#pragma once #include #include #include #include #include #include #include #include #include #include #include /** * Template of the solidity test program generated by this converter is as follows: * * pragma solidity >=0.0; * pragma experimental ABIEncoderV2; * * contract C { * // State variable * string sv_0; * // Test function that is called by the VM. * // There are 2 variations of this function: one returns * // the output of test_calldata_coding() and the other * // returns the output of test_returndata_coding(). The * // proto field called Test decides which one of the two * // are chosen for creating a test case. * function test() public returns (uint) { * // The protobuf field "Contract.test" decides which of * // the two internal functions "test_calldata_coding()" * // and "test_returndata_coding()" are called. Here, * // we assume that the protobuf field equals "CALLDATA_CODER" * return this.test_calldata_coding() * } * * // The following function is generated if the protobuf field * // "Contract.test" is equal to "RETURNDATA_CODER". * function test_returndata_coding() internal returns (uint) { * string memory lv_0, bytes memory lv_1 = test_returndata_external(); * if (lv_0 != 044852b2a670ade5407e78fb2863c51de9fcb96542a07186fe3aeda6bb8a116d) * return 1; * if (lv_1 != "1") * return 2; * return 0; * } * * // The following function is generated if the protobuf field * // "Contract.test" is equal to "RETURNDATA_CODER". * function test_returndata_external() external returns (string memory, bytes memory) * { * sv_0 = "044852b2a670ade5407e78fb2863c51de9fcb96542a07186fe3aeda6bb8a116d"; * bytes memory lv_0 = "1"; * return (sv_0, lv_0); * } * * // The following function is generated if the protobuf field * // "Contract.test" is equal to "CALLDATA_CODER". * function test_calldata_coding() internal returns (uint) { * // Local variable * bytes lv_1 = "1"; * sv_0 = "044852b2a670ade5407e78fb2863c51de9fcb96542a07186fe3aeda6bb8a116d"; * uint returnVal = this.coder_public(sv_0, lv_1); * if (returnVal != 0) * return returnVal; * // Since the return codes in the public and external coder functions are identical * // we offset error code by a fixed amount (200000) for differentiation. * returnVal = this.coder_external(sv_0, lv_1); * if (returnVal != 0) * return 200000 + returnVal; * // Encode parameters * bytes memory argumentEncoding = abi.encode(); * returnVal = checkEncodedCall(this.coder_public.selector, argumentEncoding, ); * // Check if calls to coder_public meet expectations for correctly/incorrectly encoded data. * if (returnVal != 0) * return returnVal; * * returnVal = checkEncodedCall(this.coder_external.selector, argumentEncoding, ); * // Check if calls to coder_external meet expectations for correctly/incorrectly encoded data. * // Offset return value to distinguish between failures originating from coder_public and coder_external. * if (returnVal != 0) * return uint(200000) + returnVal; * // Return zero if all checks pass. * return 0; * } * * /// Accepts function selector, correct argument encoding, and an invalid encoding length as input. * /// Returns a non-zero value if either call with correct encoding fails or call with incorrect encoding * /// succeeds. Returns zero if both calls meet expectation. * function checkEncodedCall(bytes4 funcSelector, bytes memory argumentEncoding, uint invalidLengthFuzz) * public returns (uint) { * ... * } * * /// Accepts function selector, correct argument encoding, and length of invalid encoding and returns * /// the correct and incorrect abi encoding for calling the function specified by the function selector. * function createEncoding(bytes4 funcSelector, bytes memory argumentEncoding, uint invalidLengthFuzz) * internal pure returns (bytes memory, bytes memory) { * ... * } * * /// Compares two dynamically sized bytes arrays for equality. * function bytesCompare(bytes memory a, bytes memory b) internal pure returns (bool) { * ... * } * * // Public function that is called by test() function. Accepts one or more arguments and returns * // a uint value (zero if abi en/decoding was successful, non-zero otherwise) * function coder_public(string memory c_0, bytes memory c_1) public pure returns (uint) { * if (!bytesCompare(bytes(c_0), "044852b2a670ade5407e78fb2863c51de9fcb96542a07186fe3aeda6bb8a116d")) * return 1; * if (!bytesCompare(c_1, "1")) * return 2; * return 0; * } * * // External function that is called by test() function. Accepts one or more arguments and returns * // a uint value (zero if abi en/decoding was successful, non-zero otherwise) * function coder_external(string calldata c_0, bytes calldata c_1) external pure returns (uint) { * if (!bytesCompare(bytes(c_0), "044852b2a670ade5407e78fb2863c51de9fcb96542a07186fe3aeda6bb8a116d")) * return 1; * if (!bytesCompare(c_1, "1")) * return 2; * return 0; * } * } */ namespace solidity::test::abiv2fuzzer { /// Converts a protobuf input into a Solidity program that tests /// abi coding. class ProtoConverter { public: ProtoConverter(): m_isStateVar(true), m_counter(0), m_varCounter(0), m_returnValue(1), m_isLastDynParamRightPadded(false), m_structCounter(0), m_numStructsAdded(0) {} ProtoConverter(ProtoConverter const&) = delete; ProtoConverter(ProtoConverter&&) = delete; std::string contractToString(Contract const& _input); std::string isabelleTypeString() const; std::string isabelleValueString() const; bool coderFunction() const { return m_test == Contract_Test::Contract_Test_CALLDATA_CODER; } private: enum class Delimiter { ADD, SKIP }; /// Enum of possible function types that decode abi /// encoded parameters. enum class CalleeType { PUBLIC, EXTERNAL }; /// Visitors for various Protobuf types /// Visit top-level contract specification void visit(Contract const&); /// Convert test function specification into Solidity test /// function /// @param _testSpec: Protobuf test function specification /// @param _storageDefs: String containing Solidity assignment /// statements to be placed inside the scope of the test function. std::string visit(TestFunction const& _testSpec, std::string const& _storageDefs); /// Visitors for the remaining protobuf types. They convert /// the input protobuf specification type into Solidity code. /// @return A pair of strings, first of which contains Solidity /// code to be placed inside contract scope, second of which contains /// Solidity code to be placed inside test function scope. std::pair visit(VarDecl const&); std::pair visit(Type const&); std::pair visit(ValueType const&); std::pair visit(NonValueType const&); std::pair visit(BoolType const&); std::pair visit(IntegerType const&); std::pair visit(FixedByteType const&); std::pair visit(AddressType const&); std::pair visit(DynamicByteArrayType const&); std::pair visit(ArrayType const&); std::pair visit(StructType const&); /// Convert a protobuf type @a _T into Solidity code to be placed /// inside contract and test function scopes. /// @param: _type (of parameterized type protobuf type T) is the type /// of protobuf input to be converted. /// @param: _isValueType is true if _type is a Solidity value type e.g., uint /// and false otherwise e.g., string /// @return: A pair of strings, first of which contains Solidity /// code to be placed inside contract scope, second of which contains /// Solidity code to be placed inside test function scope. template std::pair processType(T const& _type, bool _isValueType); /// Convert a protobuf type @a _T into Solidity variable assignment and check /// statements to be placed inside contract and test function scopes. /// @param: _varName is the name of the Solidity variable /// @param: _paramName is the name of the Solidity parameter that is passed /// to the test function /// @param: _type (of parameterized type protobuf type T) is the type /// of protobuf input to be converted. /// @return: A pair of strings, first of which contains Solidity /// statements to be placed inside contract scope, second of which contains /// Solidity statements to be placed inside test function scope. template std::pair assignChecker( std::string const& _varName, std::string const& _paramName, T _type ); /// Convert a protobuf type @a _T into Solidity variable declaration statement. /// @param: _varName is the name of the Solidity variable /// @param: _paramName is the name of the Solidity parameter that is passed /// to the test function /// @param: _type (of parameterized type protobuf type T) is the type /// of protobuf input to be converted. /// @param: _isValueType is a boolean that is true if _type is a /// Solidity value type e.g., uint and false otherwise e.g., string /// @param: _location is the Solidity location qualifier string to /// be used inside variable declaration statements /// @return: A pair of strings, first of which contains Solidity /// variable declaration statement to be placed inside contract scope, /// second of which contains Solidity variable declaration statement /// to be placed inside test function scope. template std::pair varDecl( std::string const& _varName, std::string const& _paramName, T _type, bool _isValueType, std::string const& _location ); /// Appends a function parameter to the function parameter stream. void appendTypedParams( CalleeType _calleeType, bool _isValueType, std::string const& _typeString, std::string const& _varName, Delimiter _delimiter ); /// Appends a function parameter to the public test function's /// parameter stream. void appendTypedParamsPublic( bool _isValueType, std::string const& _typeString, std::string const& _varName, Delimiter _delimiter = Delimiter::ADD ); /// Appends a function parameter to the external test function's /// parameter stream. void appendTypedParamsExternal( bool _isValueType, std::string const& _typeString, std::string const& _varName, Delimiter _delimiter = Delimiter::ADD ); /// Append types to typed stream used by returndata coders. void appendTypes( bool _isValueType, std::string const& _typeString, Delimiter _delimiter ); /// Append typed return value. void appendTypedReturn( bool _isValueType, std::string const& _typeString, Delimiter _delimiter ); /// Append type name to type string meant to be /// passed to Isabelle coder API. void appendToIsabelleTypeString( std::string const& _typeString, Delimiter _delimiter ); /// Append @a _valueString to value string meant to be /// passed to Isabelle coder API. void appendToIsabelleValueString( std::string const& _valueString, Delimiter _delimiter ); /// Returns a Solidity variable declaration statement /// @param _type: string containing Solidity type of the /// variable to be declared. /// @param _varName: string containing Solidity variable /// name /// @param _qualifier: string containing location where /// the variable will be placed std::string getVarDecl( std::string const& _type, std::string const& _varName, std::string const& _qualifier ); /// Return checks that are encoded as Solidity if statements /// as string std::string equalityChecksAsString(); /// Return comma separated typed function parameters as string std::string typedParametersAsString(CalleeType _calleeType); /// Return commonly used Solidity helper functions as string std::string commonHelperFunctions(); /// Return helper functions used to test calldata coding std::string calldataHelperFunctions(); /// Return top-level calldata coder test function as string std::string testCallDataFunction(unsigned _invalidLength); /// Return top-level returndata coder test function as string std::string testReturnDataFunction(); /// Return the next variable count that is used for /// variable naming. unsigned getNextVarCounter() { return m_varCounter++; } /// Return a pair of names for Solidity variable and the same variable when /// passed either as a function parameter or used to store the tuple /// returned from a function. /// @param _varCounter: name suffix /// @param _stateVar: predicate that is true for state variables, false otherwise std::pair newVarNames(unsigned _varCounter, bool _stateVar) { std::string varName = _stateVar ? s_stateVarNamePrefix : s_localVarNamePrefix; return std::make_pair( varName + std::to_string(_varCounter), paramName() + std::to_string(_varCounter) ); } std::string paramName() { switch (m_test) { case Contract_Test::Contract_Test_CALLDATA_CODER: return s_paramNamePrefix; case Contract_Test::Contract_Test_RETURNDATA_CODER: return s_localVarNamePrefix; } } /// Checks if the last dynamically encoded Solidity type is right /// padded, returning true if it is and false otherwise. bool isLastDynParamRightPadded() { return m_isLastDynParamRightPadded; } /// Convert delimter to a comma or null string. static std::string delimiterToString(Delimiter _delimiter, bool _space = true); /// Contains the test program std::ostringstream m_output; /// Contains a subset of the test program. This subset contains /// checks to be encoded in the test program std::ostringstream m_checks; /// Contains typed parameter list to be passed to callee functions std::ostringstream m_typedParamsExternal; std::ostringstream m_typedParamsPublic; /// Contains type string to be passed to Isabelle API std::ostringstream m_isabelleTypeString; /// Contains values to be encoded in the format accepted /// by the Isabelle API. std::ostringstream m_isabelleValueString; /// Contains type stream to be used in returndata coder function /// signature std::ostringstream m_types; std::ostringstream m_typedReturn; /// Argument names to be passed to coder functions std::ostringstream m_argsCoder; /// Predicate that is true if we are in contract scope bool m_isStateVar; unsigned m_counter; unsigned m_varCounter; /// Monotonically increasing return value for error reporting unsigned m_returnValue; /// Flag that indicates if last dynamically encoded parameter /// passed to a function call is of a type that is going to be /// right padded by the ABI encoder. bool m_isLastDynParamRightPadded; /// Struct counter unsigned m_structCounter; unsigned m_numStructsAdded; /// Enum stating abiv2 coder to be tested Contract_Test m_test; /// Prefixes for declared and parameterized variable names static auto constexpr s_localVarNamePrefix = "lv_"; static auto constexpr s_stateVarNamePrefix = "sv_"; static auto constexpr s_paramNamePrefix = "p_"; }; /// Visitor interface for Solidity protobuf types. template class AbiV2ProtoVisitor { public: static unsigned constexpr s_maxArrayDimensions = 3; virtual ~AbiV2ProtoVisitor() = default; virtual T visit(BoolType const& _node) = 0; virtual T visit(IntegerType const& _node) = 0; virtual T visit(FixedByteType const& _node) = 0; virtual T visit(AddressType const& _node) = 0; virtual T visit(DynamicByteArrayType const& _node) = 0; virtual T visit(ArrayType const& _node) = 0; virtual T visit(StructType const& _node) = 0; virtual T visit(ValueType const& _node) { return visitValueType(_node); } virtual T visit(NonValueType const& _node) { return visitNonValueType(_node); } virtual T visit(Type const& _node) { return visitType(_node); } enum class DataType { BYTES, VALUE, ARRAY }; /// Prefixes for declared and parameterized variable names static auto constexpr s_structNamePrefix = "S"; // Static function definitions static bool isValueType(DataType _dataType) { return _dataType == DataType::VALUE; } static unsigned getIntWidth(IntegerType const& _x) { return 8 * ((_x.width() % 32) + 1); } static bool isIntSigned(IntegerType const& _x) { return _x.is_signed(); } static std::string getIntTypeAsString(IntegerType const& _x) { return ((isIntSigned(_x) ? "int" : "uint") + std::to_string(getIntWidth(_x))); } static unsigned getFixedByteWidth(FixedByteType const& _x) { return (_x.width() % 32) + 1; } static std::string getFixedByteTypeAsString(FixedByteType const& _x) { return "bytes" + std::to_string(getFixedByteWidth(_x)); } // Convert _counter to string and return its keccak256 hash static u256 hashUnsignedInt(unsigned _counter) { return util::keccak256(util::h256(_counter)); } static u256 maskUnsignedInt(unsigned _counter, unsigned _numMaskNibbles) { return hashUnsignedInt(_counter) & u256("0x" + std::string(_numMaskNibbles, 'f')); } // Requires caller to pass number of nibbles (twice the number of bytes) as second argument. // Note: Don't change HexPrefix::Add. See comment in fixedByteValueAsString(). static std::string maskUnsignedIntToHex(unsigned _counter, unsigned _numMaskNibbles) { return toHex(maskUnsignedInt(_counter, _numMaskNibbles), util::HexPrefix::Add); } /// Dynamically sized arrays can have a length of at least zero /// and at most s_maxArrayLength. static unsigned getDynArrayLengthFromFuzz(unsigned _fuzz, unsigned _counter) { // Increment modulo value by one in order to meet upper bound return (_fuzz + _counter) % (s_maxArrayLength + 1); } /// Statically sized arrays must have a length of at least one /// and at most s_maxArrayLength. static unsigned getStaticArrayLengthFromFuzz(unsigned _fuzz) { return _fuzz % s_maxArrayLength + 1; } /// Returns a pseudo-random value for the size of a string/hex /// literal. Used for creating variable length hex/string literals. /// @param _counter Monotonically increasing counter value static unsigned getVarLength(unsigned _counter) { // Since _counter values are usually small, we use // this linear equation to make the number derived from // _counter approach a uniform distribution over // [0, s_maxDynArrayLength] auto v = (_counter + 879) * 32 % (s_maxDynArrayLength + 1); /// Always return an even number because Isabelle string /// values are formatted as hex literals if (v % 2 == 1) return v + 1; else return v; } protected: T visitValueType(ValueType const& _type) { switch (_type.value_type_oneof_case()) { case ValueType::kInty: return visit(_type.inty()); case ValueType::kByty: return visit(_type.byty()); case ValueType::kAdty: return visit(_type.adty()); case ValueType::kBoolty: return visit(_type.boolty()); case ValueType::VALUE_TYPE_ONEOF_NOT_SET: return T(); } } T visitNonValueType(NonValueType const& _type) { switch (_type.nonvalue_type_oneof_case()) { case NonValueType::kDynbytearray: return visit(_type.dynbytearray()); case NonValueType::kArrtype: return visit(_type.arrtype()); case NonValueType::kStype: return visit(_type.stype()); case NonValueType::NONVALUE_TYPE_ONEOF_NOT_SET: return T(); } } T visitType(Type const& _type) { switch (_type.type_oneof_case()) { case Type::kVtype: return visit(_type.vtype()); case Type::kNvtype: return visit(_type.nvtype()); case Type::TYPE_ONEOF_NOT_SET: return T(); } } private: static unsigned constexpr s_maxArrayLength = 4; static unsigned constexpr s_maxDynArrayLength = 256; }; /// Converts a protobuf type into a Solidity type string. class TypeVisitor: public AbiV2ProtoVisitor { public: TypeVisitor(unsigned _structSuffix = 0): m_indentation(1), m_structCounter(_structSuffix), m_structStartCounter(_structSuffix), m_structFieldCounter(0), m_isLastDynParamRightPadded(false) {} std::string visit(BoolType const&) override; std::string visit(IntegerType const&) override; std::string visit(FixedByteType const&) override; std::string visit(AddressType const&) override; std::string visit(ArrayType const&) override; std::string visit(DynamicByteArrayType const&) override; std::string visit(StructType const&) override; using AbiV2ProtoVisitor::visit; std::string baseType() { return m_baseType; } bool isLastDynParamRightPadded() { return m_isLastDynParamRightPadded; } std::string structDef() { return m_structDef.str(); } unsigned numStructs() { return m_structCounter - m_structStartCounter; } static bool arrayOfStruct(ArrayType const& _type) { Type const& baseType = _type.t(); if (baseType.has_nvtype() && baseType.nvtype().has_stype()) return true; else if (baseType.has_nvtype() && baseType.nvtype().has_arrtype()) return arrayOfStruct(baseType.nvtype().arrtype()); else return false; } std::string isabelleTypeString() { return m_structTupleString.stream.str(); } private: struct StructTupleString { StructTupleString() = default; unsigned index = 0; std::ostringstream stream; void start() { stream << "("; } void end() { stream << ")"; } void addTypeStringToTuple(std::string& _typeString); void addArrayBracketToType(std::string& _arrayBracket); }; void structDefinition(StructType const&); std::string indentation() { return std::string(m_indentation * 1, '\t'); } std::string lineString(std::string const& _line) { return indentation() + _line + "\n"; } std::string m_baseType; std::ostringstream m_structDef; /// Utility type for conveniently composing a tuple /// string for struct types. StructTupleString m_structTupleString; unsigned m_indentation; unsigned m_structCounter; unsigned m_structStartCounter; unsigned m_structFieldCounter; bool m_isLastDynParamRightPadded; static auto constexpr s_structTypeName = "S"; }; /// Returns a pair of strings, first of which contains assignment statements /// to initialize a given type, and second of which contains checks to be /// placed inside the coder function to test abi en/decoding. class AssignCheckVisitor: public AbiV2ProtoVisitor> { public: AssignCheckVisitor( std::string _varName, std::string _paramName, unsigned _errorStart, bool _stateVar, unsigned _counter, unsigned _structCounter ) { m_counter = m_counterStart = _counter; m_varName = _varName; m_paramName = _paramName; m_errorCode = m_errorStart = _errorStart; m_indentation = 2; m_stateVar = _stateVar; m_structCounter = m_structStart = _structCounter; } std::pair visit(BoolType const&) override; std::pair visit(IntegerType const&) override; std::pair visit(FixedByteType const&) override; std::pair visit(AddressType const&) override; std::pair visit(ArrayType const&) override; std::pair visit(DynamicByteArrayType const&) override; std::pair visit(StructType const&) override; using AbiV2ProtoVisitor>::visit; unsigned errorStmts() { return m_errorCode - m_errorStart; } unsigned counted() { return m_counter - m_counterStart; } unsigned structs() { return m_structCounter - m_structStart; } std::string isabelleValueString() { return m_valueStream.stream.str(); } private: struct ValueStream { ValueStream() = default; unsigned index = 0; std::ostringstream stream; void startStruct() { if (index >= 1) stream << ","; index = 0; stream << "("; } void endStruct() { stream << ")"; } void startArray() { if (index >= 1) stream << ","; index = 0; stream << "["; } void endArray() { stream << "]"; index++; } void appendValue(std::string& _value); }; std::string indentation() { return std::string(m_indentation * 1, '\t'); } unsigned counter() { return m_counter++; } std::pair assignAndCheckStringPair( std::string const& _varRef, std::string const& _checkRef, std::string const& _assignValue, std::string const& _checkValue, DataType _type ); std::string assignString(std::string const&, std::string const&); std::string checkString(std::string const&, std::string const&, DataType); unsigned m_counter; unsigned m_counterStart; std::string m_varName; std::string m_paramName; unsigned m_errorCode; unsigned m_errorStart; unsigned m_indentation; bool m_stateVar; unsigned m_structCounter; unsigned m_structStart; ValueStream m_valueStream; bool m_forcedVisit = false; }; /// Returns a valid value (as a string) for a given type. class ValueGetterVisitor: AbiV2ProtoVisitor { public: ValueGetterVisitor(unsigned _counter = 0): m_counter(_counter) {} std::string visit(BoolType const&) override; std::string visit(IntegerType const&) override; std::string visit(FixedByteType const&) override; std::string visit(AddressType const&) override; std::string visit(DynamicByteArrayType const&) override; std::string visit(ArrayType const&) override { solAssert(false, "ABIv2 proto fuzzer: Cannot call valuegettervisitor on complex type"); } std::string visit(StructType const&) override { solAssert(false, "ABIv2 proto fuzzer: Cannot call valuegettervisitor on complex type"); } using AbiV2ProtoVisitor::visit; static std::string isabelleAddressValueAsString(std::string& _solAddressString); static std::string isabelleBytesValueAsString(std::string& _solFixedBytesString); private: unsigned counter() { return m_counter++; } static std::string addressValueAsString(unsigned _counter); static std::string fixedByteValueAsString(unsigned _width, unsigned _counter); /// Returns a hex literal if _isHexLiteral is true, a string literal otherwise. /// The size of the returned literal is _numBytes bytes. /// @param _decorate If true, the returned string is enclosed within double quotes /// if _isHexLiteral is false. /// @param _isHexLiteral If true, the returned string is enclosed within /// double quotes prefixed by the string "hex" if _decorate is true. If /// _decorate is false, the returned string is returned as-is. /// @return hex value as string static std::string hexValueAsString( unsigned _numBytes, unsigned _counter, bool _isHexLiteral, bool _decorate = true ); /// Returns a hex/string literal of variable length whose value and /// size are pseudo-randomly determined from the counter value. /// @param _counter A monotonically increasing counter value /// @param _isHexLiteral Flag that indicates whether hex (if true) or /// string literal (false) is desired /// @return A variable length hex/string value static std::string bytesArrayValueAsString(unsigned _counter, bool _isHexLiteral); /// Concatenates the hash value obtained from monotonically increasing counter /// until the desired number of bytes determined by _numBytes. /// @param _width Desired number of bytes for hex value /// @param _counter A counter value used for creating a keccak256 hash /// @param _isHexLiteral Since this routine may be used to construct /// string or hex literals, this flag is used to construct a valid output. /// @return Valid hex or string literal of size _width bytes static std::string variableLengthValueAsString( unsigned _width, unsigned _counter, bool _isHexLiteral ); /// Returns a value that is @a _numBytes bytes long. /// @param _numBytes: Number of bytes of desired value /// @param _counter: A counter value /// @param _isHexLiteral: True if desired value is a hex literal, false otherwise static std::string croppedString(unsigned _numBytes, unsigned _counter, bool _isHexLiteral); unsigned m_counter; }; /// Returns true if protobuf array specification is well-formed, false otherwise class ValidityVisitor: AbiV2ProtoVisitor { public: ValidityVisitor(): m_arrayDimensions(0) {} bool visit(BoolType const&) override { return true; } bool visit(IntegerType const&) override { return true; } bool visit(FixedByteType const&) override { return true; } bool visit(AddressType const&) override { return true; } bool visit(DynamicByteArrayType const&) override { return true; } bool visit(ArrayType const& _type) override { // Mark array type as invalid in one of the following is true // - contains more than s_maxArrayDimensions dimensions // - contains an invalid base type, which happens in the // following cases // - array base type is invalid // - array base type is empty m_arrayDimensions++; if (m_arrayDimensions > s_maxArrayDimensions) return false; return visit(_type.t()); } bool visit(StructType const& _type) override { // A struct is marked invalid only if all of its fields // are invalid. This is done to prevent an empty struct // being defined (which is a Solidity error). for (auto const& t: _type.t()) if (visit(t)) return true; return false; } unsigned m_arrayDimensions; using AbiV2ProtoVisitor::visit; }; /// Returns true if visited type is dynamically encoded by the abi coder, /// false otherwise. class DynParamVisitor: AbiV2ProtoVisitor { public: DynParamVisitor() = default; bool visit(BoolType const&) override { return false; } bool visit(IntegerType const&) override { return false; } bool visit(FixedByteType const&) override { return false; } bool visit(AddressType const&) override { return false; } bool visit(DynamicByteArrayType const&) override { return true; } bool visit(ArrayType const& _type) override { // Return early if array spec is not well-formed if (!ValidityVisitor().visit(_type)) return false; // Array is dynamically encoded if it at least one of the following is true // - at least one dimension is dynamically sized // - base type is dynamically encoded if (!_type.is_static()) return true; else return visit(_type.t()); } bool visit(StructType const& _type) override { // Return early if empty struct if (!ValidityVisitor().visit(_type)) return false; // Struct is dynamically encoded if at least one of its fields // is dynamically encoded. for (auto const& t: _type.t()) if (visit(t)) return true; return false; } using AbiV2ProtoVisitor::visit; }; }