solidity/test/tools/ossfuzz/protoToAbiV2.cpp

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#include <test/tools/ossfuzz/protoToAbiV2.h>
#include <boost/preprocessor.hpp>
#include <regex>
/// Convenience macros
/// Returns a valid Solidity integer width w such that 8 <= w <= 256.
#define INTWIDTH(z, n, _ununsed) BOOST_PP_MUL(BOOST_PP_ADD(n, 1), 8)
/// Using declaration that aliases long boost multiprecision types with
/// s(u)<width> where <width> is a valid Solidity integer width and "s"
/// stands for "signed" and "u" for "unsigned".
#define USINGDECL(z, n, sign) \
using BOOST_PP_CAT(BOOST_PP_IF(sign, s, u), INTWIDTH(z, n,)) = \
boost::multiprecision::number< \
boost::multiprecision::cpp_int_backend< \
INTWIDTH(z, n,), \
INTWIDTH(z, n,), \
BOOST_PP_IF( \
sign, \
boost::multiprecision::signed_magnitude, \
boost::multiprecision::unsigned_magnitude \
), \
boost::multiprecision::unchecked, \
void \
> \
>;
/// Instantiate the using declarations for signed and unsigned integer types.
BOOST_PP_REPEAT(32, USINGDECL, 1)
BOOST_PP_REPEAT(32, USINGDECL, 0)
/// Case implementation that returns an integer value of the specified type.
/// For signed integers, we divide by two because the range for boost multiprecision
/// types is double that of Solidity integer types. Example, 8-bit signed boost
/// number range is [-255, 255] but Solidity `int8` range is [-128, 127]
#define CASEIMPL(z, n, sign) \
case INTWIDTH(z, n,): \
stream << BOOST_PP_IF( \
sign, \
integerValue< \
BOOST_PP_CAT( \
BOOST_PP_IF(sign, s, u), \
INTWIDTH(z, n,) \
)>(_counter) / 2, \
integerValue< \
BOOST_PP_CAT( \
BOOST_PP_IF(sign, s, u), \
INTWIDTH(z, n,) \
)>(_counter) \
); \
break;
/// Switch implementation that instantiates case statements for (un)signed
/// Solidity integer types.
#define SWITCHIMPL(sign) \
ostringstream stream; \
switch (_intWidth) \
{ \
BOOST_PP_REPEAT(32, CASEIMPL, sign) \
} \
return stream.str();
using namespace std;
using namespace solidity::util;
using namespace solidity::test::abiv2fuzzer;
namespace
{
template <typename V>
static V integerValue(unsigned _counter)
{
V value = V(
u256(solidity::util::keccak256(solidity::util::h256(_counter))) % u256(boost::math::tools::max_value<V>())
);
if (boost::multiprecision::is_signed_number<V>::value && value % 2 == 0)
return value * (-1);
else
return value;
}
static string signedIntegerValue(unsigned _counter, unsigned _intWidth)
{
SWITCHIMPL(1)
}
static string unsignedIntegerValue(unsigned _counter, unsigned _intWidth)
{
SWITCHIMPL(0)
}
static string integerValue(unsigned _counter, unsigned _intWidth, bool _signed)
{
if (_signed)
return signedIntegerValue(_counter, _intWidth);
else
return unsignedIntegerValue(_counter, _intWidth);
}
}
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string ProtoConverter::getVarDecl(
string const& _type,
string const& _varName,
string const& _qualifier
)
{
// One level of indentation for state variable declarations
// Two levels of indentation for local variable declarations
return Whiskers(R"(
<?isLocalVar> </isLocalVar><type><?qual> <qualifier></qual> <varName>;)"
)
("isLocalVar", !m_isStateVar)
("type", _type)
("qual", !_qualifier.empty())
("qualifier", _qualifier)
("varName", _varName)
.render() +
"\n";
}
pair<string, string> ProtoConverter::visit(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 make_pair("", "");
}
}
pair<string, string> ProtoConverter::visit(ValueType const& _type)
{
switch (_type.value_type_oneof_case())
{
case ValueType::kBoolty:
return visit(_type.boolty());
case ValueType::kInty:
return visit(_type.inty());
case ValueType::kByty:
return visit(_type.byty());
case ValueType::kAdty:
return visit(_type.adty());
case ValueType::VALUE_TYPE_ONEOF_NOT_SET:
return make_pair("", "");
}
}
pair<string, string> ProtoConverter::visit(NonValueType const& _type)
{
switch (_type.nonvalue_type_oneof_case())
{
case NonValueType::kDynbytearray:
return visit(_type.dynbytearray());
case NonValueType::kArrtype:
if (ValidityVisitor().visit(_type.arrtype()))
return visit(_type.arrtype());
else
return make_pair("", "");
case NonValueType::kStype:
if (ValidityVisitor().visit(_type.stype()))
return visit(_type.stype());
else
return make_pair("", "");
case NonValueType::NONVALUE_TYPE_ONEOF_NOT_SET:
return make_pair("", "");
}
}
pair<string, string> ProtoConverter::visit(BoolType const& _type)
{
return processType(_type, true);
}
pair<string, string> ProtoConverter::visit(IntegerType const& _type)
{
return processType(_type, true);
}
pair<string, string> ProtoConverter::visit(FixedByteType const& _type)
{
return processType(_type, true);
}
pair<string, string> ProtoConverter::visit(AddressType const& _type)
{
return processType(_type, true);
}
pair<string, string> ProtoConverter::visit(DynamicByteArrayType const& _type)
{
return processType(_type, false);
}
pair<string, string> ProtoConverter::visit(ArrayType const& _type)
{
return processType(_type, false);
}
pair<string, string> ProtoConverter::visit(StructType const& _type)
{
return processType(_type, false);
}
template <typename T>
pair<string, string> ProtoConverter::processType(T const& _type, bool _isValueType)
{
ostringstream local, global;
auto [varName, paramName] = newVarNames(getNextVarCounter(), m_isStateVar);
// Add variable name to the argument list of coder function call
if (m_argsCoder.str().empty())
m_argsCoder << varName;
else
m_argsCoder << ", " << varName;
string location{};
if (!m_isStateVar && !_isValueType)
location = "memory";
auto varDeclBuffers = varDecl(
varName,
paramName,
_type,
_isValueType,
location
);
global << varDeclBuffers.first;
local << varDeclBuffers.second;
auto assignCheckBuffers = assignChecker(varName, paramName, _type);
global << assignCheckBuffers.first;
local << assignCheckBuffers.second;
m_structCounter += m_numStructsAdded;
return make_pair(global.str(), local.str());
}
template <typename T>
pair<string, string> ProtoConverter::varDecl(
string const& _varName,
string const& _paramName,
T _type,
bool _isValueType,
string const& _location
)
{
ostringstream local, global;
TypeVisitor tVisitor(m_structCounter);
string typeStr = tVisitor.visit(_type);
if (typeStr.empty())
return make_pair("", "");
// Append struct defs
global << tVisitor.structDef();
m_numStructsAdded = tVisitor.numStructs();
// variable declaration
if (m_isStateVar)
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global << getVarDecl(typeStr, _varName, _location);
else
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local << getVarDecl(typeStr, _varName, _location);
// Add typed params for calling public and external functions with said type
appendTypedParams(
CalleeType::PUBLIC,
_isValueType,
typeStr,
_paramName,
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
appendTypedParams(
CalleeType::EXTERNAL,
_isValueType,
typeStr,
_paramName,
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
appendTypes(
_isValueType,
typeStr,
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
appendTypedReturn(
_isValueType,
typeStr,
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
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appendToIsabelleTypeString(
tVisitor.isabelleTypeString(),
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
// Update dyn param only if necessary
if (tVisitor.isLastDynParamRightPadded())
m_isLastDynParamRightPadded = true;
return make_pair(global.str(), local.str());
}
template <typename T>
pair<string, string> ProtoConverter::assignChecker(
string const& _varName,
string const& _paramName,
T _type
)
{
ostringstream local;
AssignCheckVisitor acVisitor(
_varName,
_paramName,
m_returnValue,
m_isStateVar,
m_counter,
m_structCounter
);
pair<string, string> assignCheckStrPair = acVisitor.visit(_type);
m_returnValue += acVisitor.errorStmts();
m_counter += acVisitor.counted();
m_checks << assignCheckStrPair.second;
appendToIsabelleValueString(
acVisitor.isabelleValueString(),
((m_varCounter == 1) ? Delimiter::SKIP : Delimiter::ADD)
);
// State variables cannot be assigned in contract-scope
// Therefore, we buffer their assignments and
// render them in function scope later.
local << assignCheckStrPair.first;
return make_pair("", local.str());
}
pair<string, string> ProtoConverter::visit(VarDecl const& _x)
{
return visit(_x.type());
}
std::string ProtoConverter::equalityChecksAsString()
{
return m_checks.str();
}
std::string ProtoConverter::delimiterToString(Delimiter _delimiter, bool _space)
{
switch (_delimiter)
{
case Delimiter::ADD:
return _space ? ", " : ",";
case Delimiter::SKIP:
return "";
}
}
/* When a new variable is declared, we can invoke this function
* to prepare the typed param list to be passed to callee functions.
* We independently prepare this list for "public" and "external"
* callee functions.
*/
void ProtoConverter::appendTypedParams(
CalleeType _calleeType,
bool _isValueType,
std::string const& _typeString,
std::string const& _varName,
Delimiter _delimiter
)
{
switch (_calleeType)
{
case CalleeType::PUBLIC:
appendTypedParamsPublic(_isValueType, _typeString, _varName, _delimiter);
break;
case CalleeType::EXTERNAL:
appendTypedParamsExternal(_isValueType, _typeString, _varName, _delimiter);
break;
}
}
void ProtoConverter::appendTypes(
bool _isValueType,
string const& _typeString,
Delimiter _delimiter
)
{
string qualifiedTypeString = (
_isValueType ?
_typeString :
_typeString + " memory"
);
m_types << Whiskers(R"(<delimiter><type>)")
("delimiter", delimiterToString(_delimiter))
("type", qualifiedTypeString)
.render();
}
void ProtoConverter::appendTypedReturn(
bool _isValueType,
string const& _typeString,
Delimiter _delimiter
)
{
string qualifiedTypeString = (
_isValueType ?
_typeString :
_typeString + " memory"
);
m_typedReturn << Whiskers(R"(<delimiter><type> <varName>)")
("delimiter", delimiterToString(_delimiter))
("type", qualifiedTypeString)
("varName", "lv_" + to_string(m_varCounter - 1))
.render();
}
// Adds the qualifier "calldata" to non-value parameter of an external function.
void ProtoConverter::appendTypedParamsExternal(
bool _isValueType,
std::string const& _typeString,
std::string const& _varName,
Delimiter _delimiter
)
{
m_externalParamsRep.push_back({_delimiter, _isValueType, _typeString, _varName});
m_untypedParamsExternal << Whiskers(R"(<delimiter><varName>)")
("delimiter", delimiterToString(_delimiter))
("varName", _varName)
.render();
}
// Adds the qualifier "memory" to non-value parameter of an external function.
void ProtoConverter::appendTypedParamsPublic(
bool _isValueType,
std::string const& _typeString,
std::string const& _varName,
Delimiter _delimiter
)
{
std::string qualifiedTypeString = (
_isValueType ?
_typeString :
_typeString + " memory"
);
m_typedParamsPublic << Whiskers(R"(<delimiter><type> <varName>)")
("delimiter", delimiterToString(_delimiter))
("type", qualifiedTypeString)
("varName", _varName)
.render();
}
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void ProtoConverter::appendToIsabelleTypeString(
std::string const& _typeString,
Delimiter _delimiter
)
{
m_isabelleTypeString << delimiterToString(_delimiter, false) << _typeString;
}
void ProtoConverter::appendToIsabelleValueString(
std::string const& _valueString,
Delimiter _delimiter
)
{
m_isabelleValueString << delimiterToString(_delimiter, false) << _valueString;
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}
std::string ProtoConverter::typedParametersAsString(CalleeType _calleeType)
{
switch (_calleeType)
{
case CalleeType::PUBLIC:
return m_typedParamsPublic.str();
case CalleeType::EXTERNAL:
{
ostringstream typedParamsExternal;
for (auto const& i: m_externalParamsRep)
{
Delimiter del = get<0>(i);
bool valueType = get<1>(i);
string typeString = get<2>(i);
string varName = get<3>(i);
bool isCalldata = randomBool(/*probability=*/0.5);
string location = (isCalldata ? "calldata" : "memory");
string qualifiedTypeString = (valueType ? typeString : typeString + " " + location);
typedParamsExternal << Whiskers(R"(<delimiter><type> <varName>)")
("delimiter", delimiterToString(del))
("type", qualifiedTypeString)
("varName", varName)
.render();
}
return typedParamsExternal.str();
}
}
}
string ProtoConverter::visit(TestFunction const& _x, string const& _storageVarDefs)
{
// TODO: Support more than one but less than N local variables
auto localVarBuffers = visit(_x.local_vars());
string structTypeDecl = localVarBuffers.first;
string localVarDefs = localVarBuffers.second;
ostringstream testBuffer;
string testFunction = Whiskers(R"(
function test() public returns (uint) {
<?calldata>return test_calldata_coding();</calldata>
<?returndata>return test_returndata_coding();</returndata>
})")
("calldata", m_test == Contract_Test::Contract_Test_CALLDATA_CODER)
("returndata", m_test == Contract_Test::Contract_Test_RETURNDATA_CODER)
.render();
string functionDeclCalldata = "function test_calldata_coding() internal returns (uint)";
string functionDeclReturndata = "function test_returndata_coding() internal returns (uint)";
testBuffer << Whiskers(R"(<structTypeDecl>
<testFunction>
<?calldata>
<functionDeclCalldata> {
<storageVarDefs>
<localVarDefs>
<calldataTestCode>
}
<calldataHelperFuncs>
</calldata>
<?returndata>
<functionDeclReturndata> {
<returndataTestCode>
}
<?varsPresent>
function coder_returndata_external() external returns (<return_types>) {
<storageVarDefs>
<localVarDefs>
return (<return_values>);
}
</varsPresent>
</returndata>)")
("testFunction", testFunction)
("calldata", m_test == Contract_Test::Contract_Test_CALLDATA_CODER)
("returndata", m_test == Contract_Test::Contract_Test_RETURNDATA_CODER)
("calldataHelperFuncs", calldataHelperFunctions())
("varsPresent", !m_types.str().empty())
("structTypeDecl", structTypeDecl)
("functionDeclCalldata", functionDeclCalldata)
("functionDeclReturndata", functionDeclReturndata)
("storageVarDefs", _storageVarDefs)
("localVarDefs", localVarDefs)
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("calldataTestCode", testCallDataFunction(static_cast<unsigned>(_x.invalid_encoding_length())))
("returndataTestCode", testReturnDataFunction())
("return_types", m_types.str())
("return_values", m_argsCoder.str())
.render();
return testBuffer.str();
}
string ProtoConverter::testCallDataFunction(unsigned _invalidLength)
{
return Whiskers(R"(
uint returnVal = this.coder_calldata_public(<argumentNames>);
if (returnVal != 0)
return returnVal;
returnVal = this.coder_calldata_external(<argumentNames>);
if (returnVal != 0)
return uint(200000) + returnVal;
<?atLeastOneVar>
bytes memory argumentEncoding = abi.encode(<argumentNames>);
returnVal = checkEncodedCall(
this.coder_calldata_public.selector,
argumentEncoding,
<invalidLengthFuzz>,
<isRightPadded>
);
if (returnVal != 0)
return returnVal;
returnVal = checkEncodedCall(
this.coder_calldata_external.selector,
argumentEncoding,
<invalidLengthFuzz>,
<isRightPadded>
);
if (returnVal != 0)
return uint(200000) + returnVal;
</atLeastOneVar>
return 0;
)")
("argumentNames", m_argsCoder.str())
("invalidLengthFuzz", std::to_string(_invalidLength))
("isRightPadded", isLastDynParamRightPadded() ? "true" : "false")
("atLeastOneVar", m_varCounter > 0)
.render();
}
string ProtoConverter::testReturnDataFunction()
{
return Whiskers(R"(
<?varsPresent>
(<varDecl>) = this.coder_returndata_external();
<equality_checks>
</varsPresent>
return 0;
)")
("varsPresent", !m_typedReturn.str().empty())
("varDecl", m_typedReturn.str())
("equality_checks", m_checks.str())
.render();
}
string ProtoConverter::calldataHelperFunctions()
{
stringstream calldataHelperFuncs;
calldataHelperFuncs << R"(
/// 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,
bool isRightPadded
) internal pure returns (bytes memory, bytes memory)
{
bytes memory validEncoding = new bytes(4 + argumentEncoding.length);
// Ensure that invalidEncoding crops at least 32 bytes (padding length
// is at most 31 bytes) if `isRightPadded` is true.
// This is because shorter bytes/string values (whose encoding is right
// padded) can lead to successful decoding when fewer than 32 bytes have
// been cropped in the worst case. In other words, if `isRightPadded` is
// true, then
// 0 <= invalidLength <= argumentEncoding.length - 32
// otherwise
// 0 <= invalidLength <= argumentEncoding.length - 1
uint invalidLength;
if (isRightPadded)
invalidLength = invalidLengthFuzz % (argumentEncoding.length - 31);
else
invalidLength = invalidLengthFuzz % argumentEncoding.length;
bytes memory invalidEncoding = new bytes(4 + invalidLength);
for (uint i = 0; i < 4; i++)
validEncoding[i] = invalidEncoding[i] = funcSelector[i];
for (uint i = 0; i < argumentEncoding.length; i++)
validEncoding[i+4] = argumentEncoding[i];
for (uint i = 0; i < invalidLength; i++)
invalidEncoding[i+4] = argumentEncoding[i];
return (validEncoding, invalidEncoding);
}
/// 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,
bool isRightPadded
) public returns (uint)
{
(bytes memory validEncoding, bytes memory invalidEncoding) = createEncoding(
funcSelector,
argumentEncoding,
invalidLengthFuzz,
isRightPadded
);
(bool success, bytes memory returnVal) = address(this).call(validEncoding);
uint returnCode = abi.decode(returnVal, (uint));
// Return non-zero value if call fails for correct encoding
if (success == false || returnCode != 0)
return 400000;
(success, ) = address(this).call(invalidEncoding);
// Return non-zero value if call succeeds for incorrect encoding
if (success == true)
return 400001;
return 0;
})";
/// These are indirections to test memory-calldata codings more robustly.
stringstream indirections;
unsigned numIndirections = randomNumberOneToN(s_maxIndirections);
for (unsigned i = 1; i <= numIndirections; i++)
{
bool finalIndirection = i == numIndirections;
string mutability = (finalIndirection ? "pure" : "view");
indirections << Whiskers(R"(
function coder_calldata_external_i<N>(<parameters>) external <mutability> returns (uint) {
<?finalIndirection>
<equality_checks>
return 0;
<!finalIndirection>
return this.coder_calldata_external_i<NPlusOne>(<untyped_parameters>);
</finalIndirection>
}
)")
("N", to_string(i))
("parameters", typedParametersAsString(CalleeType::EXTERNAL))
("mutability", mutability)
("finalIndirection", finalIndirection)
("equality_checks", equalityChecksAsString())
("NPlusOne", to_string(i + 1))
("untyped_parameters", m_untypedParamsExternal.str())
.render();
}
// These are callee functions that encode from storage, decode to
// memory/calldata and check if decoded value matches storage value
// return true on successful match, false otherwise
calldataHelperFuncs << Whiskers(R"(
function coder_calldata_public(<parameters_memory>) public pure returns (uint) {
<equality_checks>
return 0;
}
function coder_calldata_external(<parameters_calldata>) external view returns (uint) {
return this.coder_calldata_external_i1(<untyped_parameters>);
}
<indirections>
)")
("parameters_memory", typedParametersAsString(CalleeType::PUBLIC))
("equality_checks", equalityChecksAsString())
("parameters_calldata", typedParametersAsString(CalleeType::EXTERNAL))
("untyped_parameters", m_untypedParamsExternal.str())
("indirections", indirections.str())
.render();
return calldataHelperFuncs.str();
}
string ProtoConverter::commonHelperFunctions()
{
stringstream helperFuncs;
helperFuncs << R"(
/// Compares bytes, returning true if they are equal and false otherwise.
function bytesCompare(bytes memory a, bytes memory b) internal pure returns (bool) {
if(a.length != b.length)
return false;
for (uint i = 0; i < a.length; i++)
if (a[i] != b[i])
return false;
return true;
}
)";
return helperFuncs.str();
}
void ProtoConverter::visit(Contract const& _x)
{
string pragmas = R"(pragma solidity >=0.0;
pragma experimental ABIEncoderV2;)";
// Record test spec
m_test = _x.test();
// TODO: Support more than one but less than N state variables
auto storageBuffers = visit(_x.state_vars());
string storageVarDecls = storageBuffers.first;
string storageVarDefs = storageBuffers.second;
m_isStateVar = false;
string testFunction = visit(_x.testfunction(), storageVarDefs);
/* Structure of contract body
* - Storage variable declarations
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* - Struct definitions
* - Test function
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* - Storage variable assignments
* - Local variable definitions and assignments
* - Test code proper (calls public and external functions)
* - Helper functions
*/
ostringstream contractBody;
contractBody << storageVarDecls
<< testFunction
<< commonHelperFunctions();
m_output << Whiskers(R"(<pragmas>
<contractStart>
<contractBody>
<contractEnd>)")
("pragmas", pragmas)
("contractStart", "contract C {")
("contractBody", contractBody.str())
("contractEnd", "}")
.render();
}
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string ProtoConverter::isabelleTypeString() const
{
string typeString = m_isabelleTypeString.str();
if (!typeString.empty())
return "(" + typeString + ")";
else
return typeString;
}
string ProtoConverter::isabelleValueString() const
{
string valueString = m_isabelleValueString.str();
if (!valueString.empty())
return "(" + valueString + ")";
else
return valueString;
}
string ProtoConverter::contractToString(Contract const& _input)
{
visit(_input);
return m_output.str();
}
/// Type visitor
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void TypeVisitor::StructTupleString::addTypeStringToTuple(string& _typeString)
{
index++;
if (index > 1)
stream << ",";
stream << _typeString;
}
void TypeVisitor::StructTupleString::addArrayBracketToType(string& _arrayBracket)
{
stream << _arrayBracket;
}
string TypeVisitor::visit(BoolType const&)
{
m_baseType = "bool";
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m_structTupleString.addTypeStringToTuple(m_baseType);
return m_baseType;
}
string TypeVisitor::visit(IntegerType const& _type)
{
m_baseType = getIntTypeAsString(_type);
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m_structTupleString.addTypeStringToTuple(m_baseType);
return m_baseType;
}
string TypeVisitor::visit(FixedByteType const& _type)
{
m_baseType = getFixedByteTypeAsString(_type);
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m_structTupleString.addTypeStringToTuple(m_baseType);
return m_baseType;
}
string TypeVisitor::visit(AddressType const&)
{
m_baseType = "address";
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m_structTupleString.addTypeStringToTuple(m_baseType);
return m_baseType;
}
string TypeVisitor::visit(ArrayType const& _type)
{
if (!ValidityVisitor().visit(_type))
return "";
string baseType = visit(_type.t());
solAssert(!baseType.empty(), "");
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string arrayBracket = _type.is_static() ?
string("[") +
to_string(getStaticArrayLengthFromFuzz(_type.length())) +
string("]") :
string("[]");
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m_baseType += arrayBracket;
m_structTupleString.addArrayBracketToType(arrayBracket);
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// If we don't know yet if the array will be dynamically encoded,
// check again. If we already know that it will be, there's no
// need to do anything.
if (!m_isLastDynParamRightPadded)
m_isLastDynParamRightPadded = DynParamVisitor().visit(_type);
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return baseType + arrayBracket;
}
string TypeVisitor::visit(DynamicByteArrayType const&)
{
m_isLastDynParamRightPadded = true;
m_baseType = "bytes";
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m_structTupleString.addTypeStringToTuple(m_baseType);
return m_baseType;
}
void TypeVisitor::structDefinition(StructType const& _type)
{
// Return an empty string if struct is empty
solAssert(ValidityVisitor().visit(_type), "");
// Reset field counter and indentation
unsigned wasFieldCounter = m_structFieldCounter;
unsigned wasIndentation = m_indentation;
m_indentation = 1;
m_structFieldCounter = 0;
// Commence struct declaration
string structDef = lineString(
"struct " +
string(s_structNamePrefix) +
to_string(m_structCounter) +
" {"
);
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// Start tuple of types with parenthesis
m_structTupleString.start();
// Increase indentation for struct fields
m_indentation++;
for (auto const& t: _type.t())
{
string type{};
if (!ValidityVisitor().visit(t))
continue;
TypeVisitor tVisitor(m_structCounter + 1);
type = tVisitor.visit(t);
m_structCounter += tVisitor.numStructs();
m_structDef << tVisitor.structDef();
solAssert(!type.empty(), "");
structDef += lineString(
Whiskers(R"(<type> <member>;)")
("type", type)
("member", "m" + to_string(m_structFieldCounter++))
.render()
);
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string isabelleTypeStr = tVisitor.isabelleTypeString();
m_structTupleString.addTypeStringToTuple(isabelleTypeStr);
}
m_indentation--;
structDef += lineString("}");
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// End tuple of types with parenthesis
m_structTupleString.end();
m_structCounter++;
m_structDef << structDef;
m_indentation = wasIndentation;
m_structFieldCounter = wasFieldCounter;
}
string TypeVisitor::visit(StructType const& _type)
{
if (ValidityVisitor().visit(_type))
{
// Add struct definition
structDefinition(_type);
// Set last dyn param if struct contains a dyn param e.g., bytes, array etc.
m_isLastDynParamRightPadded = DynParamVisitor().visit(_type);
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// If top-level struct is a non-empty struct, assign the name S<suffix>
m_baseType = s_structTypeName + to_string(m_structStartCounter);
}
else
m_baseType = {};
return m_baseType;
}
/// AssignCheckVisitor implementation
void AssignCheckVisitor::ValueStream::appendValue(string& _value)
{
solAssert(!_value.empty(), "Abiv2 fuzzer: Empty value");
index++;
if (index > 1)
stream << ",";
stream << _value;
}
pair<string, string> AssignCheckVisitor::visit(BoolType const& _type)
{
string value = ValueGetterVisitor(counter()).visit(_type);
if (!m_forcedVisit)
m_valueStream.appendValue(value);
return assignAndCheckStringPair(m_varName, m_paramName, value, value, DataType::VALUE);
}
pair<string, string> AssignCheckVisitor::visit(IntegerType const& _type)
{
string value = ValueGetterVisitor(counter()).visit(_type);
if (!m_forcedVisit)
m_valueStream.appendValue(value);
return assignAndCheckStringPair(m_varName, m_paramName, value, value, DataType::VALUE);
}
pair<string, string> AssignCheckVisitor::visit(FixedByteType const& _type)
{
string value = ValueGetterVisitor(counter()).visit(_type);
if (!m_forcedVisit)
{
string isabelleValue = ValueGetterVisitor{}.isabelleBytesValueAsString(value);
m_valueStream.appendValue(isabelleValue);
}
return assignAndCheckStringPair(m_varName, m_paramName, value, value, DataType::VALUE);
}
pair<string, string> AssignCheckVisitor::visit(AddressType const& _type)
{
string value = ValueGetterVisitor(counter()).visit(_type);
if (!m_forcedVisit)
{
string isabelleValue = ValueGetterVisitor{}.isabelleAddressValueAsString(value);
m_valueStream.appendValue(isabelleValue);
}
return assignAndCheckStringPair(m_varName, m_paramName, value, value, DataType::VALUE);
}
pair<string, string> AssignCheckVisitor::visit(DynamicByteArrayType const& _type)
{
string value = ValueGetterVisitor(counter()).visit(_type);
if (!m_forcedVisit)
{
string isabelleValue = ValueGetterVisitor{}.isabelleBytesValueAsString(value);
m_valueStream.appendValue(isabelleValue);
}
DataType dataType = DataType::BYTES;
return assignAndCheckStringPair(m_varName, m_paramName, value, value, dataType);
}
pair<string, string> AssignCheckVisitor::visit(ArrayType const& _type)
{
if (!ValidityVisitor().visit(_type))
return make_pair("", "");
// Obtain type of array to be resized and initialized
string typeStr{};
unsigned wasStructCounter = m_structCounter;
TypeVisitor tVisitor(m_structCounter);
typeStr = tVisitor.visit(_type);
pair<string, string> resizeBuffer;
string lengthStr;
unsigned length;
// Resize dynamic arrays
if (!_type.is_static())
{
length = getDynArrayLengthFromFuzz(_type.length(), counter());
lengthStr = to_string(length);
if (m_stateVar)
{
// Dynamic storage arrays are resized via the empty push() operation
resizeBuffer.first = Whiskers(R"(<indentation>for (uint i = 0; i < <length>; i++) <arrayRef>.push();)")
("indentation", indentation())
("length", lengthStr)
("arrayRef", m_varName)
.render() + "\n";
// Add a dynamic check on the resized length
resizeBuffer.second = checkString(m_paramName + ".length", lengthStr, DataType::VALUE);
}
else
{
// Resizing memory arrays via the new operator
string resizeOp = Whiskers(R"(new <fullTypeStr>(<length>))")
("fullTypeStr", typeStr)
("length", lengthStr)
.render();
resizeBuffer = assignAndCheckStringPair(
m_varName,
m_paramName + ".length",
resizeOp,
lengthStr,
DataType::VALUE
);
}
}
else
{
length = getStaticArrayLengthFromFuzz(_type.length());
lengthStr = to_string(length);
// Add check on length
resizeBuffer.second = checkString(m_paramName + ".length", lengthStr, DataType::VALUE);
}
// Add assignCheckBuffer and check statements
pair<string, string> assignCheckBuffer;
string wasVarName = m_varName;
string wasParamName = m_paramName;
if (!m_forcedVisit)
m_valueStream.startArray();
for (unsigned i = 0; i < length; i++)
{
m_varName = wasVarName + "[" + to_string(i) + "]";
m_paramName = wasParamName + "[" + to_string(i) + "]";
pair<string, string> assign = visit(_type.t());
assignCheckBuffer.first += assign.first;
assignCheckBuffer.second += assign.second;
if (i < length - 1)
m_structCounter = wasStructCounter;
}
// Since struct visitor won't be called for zero-length
// arrays, struct counter will not get incremented. Therefore,
// we need to manually force a recursive struct visit.
if (length == 0 && TypeVisitor().arrayOfStruct(_type))
{
bool previousState = m_forcedVisit;
m_forcedVisit = true;
visit(_type.t());
m_forcedVisit = previousState;
}
if (!m_forcedVisit)
m_valueStream.endArray();
m_varName = wasVarName;
m_paramName = wasParamName;
// Compose resize and initialization assignment and check
return make_pair(
resizeBuffer.first + assignCheckBuffer.first,
resizeBuffer.second + assignCheckBuffer.second
);
}
pair<string, string> AssignCheckVisitor::visit(StructType const& _type)
{
if (!ValidityVisitor().visit(_type))
return make_pair("", "");
pair<string, string> assignCheckBuffer;
unsigned i = 0;
// Increment struct counter
m_structCounter++;
string wasVarName = m_varName;
string wasParamName = m_paramName;
if (!m_forcedVisit)
m_valueStream.startStruct();
for (auto const& t: _type.t())
{
m_varName = wasVarName + ".m" + to_string(i);
m_paramName = wasParamName + ".m" + to_string(i);
pair<string, string> assign = visit(t);
// If type is not well formed continue without
// updating state.
if (assign.first.empty() && assign.second.empty())
continue;
assignCheckBuffer.first += assign.first;
assignCheckBuffer.second += assign.second;
i++;
}
if (!m_forcedVisit)
m_valueStream.endStruct();
m_varName = wasVarName;
m_paramName = wasParamName;
return assignCheckBuffer;
}
pair<string, string> AssignCheckVisitor::assignAndCheckStringPair(
string const& _varRef,
string const& _checkRef,
string const& _assignValue,
string const& _checkValue,
DataType _type
)
{
return make_pair(assignString(_varRef, _assignValue), checkString(_checkRef, _checkValue, _type));
}
string AssignCheckVisitor::assignString(string const& _ref, string const& _value)
{
string assignStmt = Whiskers(R"(<ref> = <value>;)")
("ref", _ref)
("value", _value)
.render();
return indentation() + assignStmt + "\n";
}
string AssignCheckVisitor::checkString(string const& _ref, string const& _value, DataType _type)
{
string checkPred;
switch (_type)
{
case DataType::BYTES:
checkPred = Whiskers(R"(!bytesCompare(<varName>, <value>))")
("varName", _ref)
("value", _value)
.render();
break;
case DataType::VALUE:
checkPred = Whiskers(R"(<varName> != <value>)")
("varName", _ref)
("value", _value)
.render();
break;
case DataType::ARRAY:
solUnimplemented("Proto ABIv2 fuzzer: Invalid data type.");
}
string checkStmt = Whiskers(R"(if (<checkPred>) return <errCode>;)")
("checkPred", checkPred)
("errCode", to_string(m_errorCode++))
.render();
return indentation() + checkStmt + "\n";
}
/// ValueGetterVisitor
string ValueGetterVisitor::visit(BoolType const&)
{
return counter() % 2 ? "true" : "false";
}
string ValueGetterVisitor::visit(IntegerType const& _type)
{
return integerValue(counter(), getIntWidth(_type), _type.is_signed());
}
string ValueGetterVisitor::visit(FixedByteType const& _type)
{
return fixedByteValueAsString(
getFixedByteWidth(_type),
counter()
);
}
string ValueGetterVisitor::visit(AddressType const&)
{
return addressValueAsString(counter());
}
string ValueGetterVisitor::visit(DynamicByteArrayType const&)
{
return bytesArrayValueAsString(
counter(),
true
);
}
std::string ValueGetterVisitor::croppedString(
unsigned _numBytes,
unsigned _counter,
bool _isHexLiteral
)
{
solAssert(
_numBytes > 0 && _numBytes <= 32,
"Proto ABIv2 fuzzer: Too short or too long a cropped string"
);
// Number of masked nibbles is twice the number of bytes for a
// hex literal of _numBytes bytes. For a string literal, each nibble
// is treated as a character.
unsigned numMaskNibbles = _isHexLiteral ? _numBytes * 2 : _numBytes;
// Start position of substring equals totalHexStringLength - numMaskNibbles
// totalHexStringLength = 64 + 2 = 66
// e.g., 0x12345678901234567890123456789012 is a total of 66 characters
// |---------------------^-----------|
// <--- start position---><--numMask->
// <-----------total length --------->
// Note: This assumes that maskUnsignedIntToHex() invokes toHex(..., HexPrefix::Add)
unsigned startPos = 66 - numMaskNibbles;
// Extracts the least significant numMaskNibbles from the result
// of maskUnsignedIntToHex().
return maskUnsignedIntToHex(
_counter,
numMaskNibbles
).substr(startPos, numMaskNibbles);
}
std::string ValueGetterVisitor::hexValueAsString(
unsigned _numBytes,
unsigned _counter,
bool _isHexLiteral,
bool _decorate
)
{
solAssert(_numBytes > 0 && _numBytes <= 32,
"Proto ABIv2 fuzzer: Invalid hex length"
);
// If _decorate is set, then we return a hex"" or a "" string.
if (_numBytes == 0)
return Whiskers(R"(<?decorate><?isHex>hex</isHex>""</decorate>)")
("decorate", _decorate)
("isHex", _isHexLiteral)
.render();
// This is needed because solidity interprets a 20-byte 0x prefixed hex literal as an address
// payable type.
return Whiskers(R"(<?decorate><?isHex>hex</isHex>"</decorate><value><?decorate>"</decorate>)")
("decorate", _decorate)
("isHex", _isHexLiteral)
("value", croppedString(_numBytes, _counter, _isHexLiteral))
.render();
}
std::string ValueGetterVisitor::fixedByteValueAsString(unsigned _width, unsigned _counter)
{
solAssert(
(_width >= 1 && _width <= 32),
"Proto ABIv2 Fuzzer: Fixed byte width is not between 1--32"
);
return hexValueAsString(_width, _counter, /*isHexLiteral=*/true);
}
std::string ValueGetterVisitor::addressValueAsString(unsigned _counter)
{
return "address(" + maskUnsignedIntToHex(_counter, 40) + ")";
}
std::string ValueGetterVisitor::isabelleAddressValueAsString(std::string& _solAddressString)
{
// Isabelle encoder expects address literal to be exactly
// 20 bytes and a hex string.
// Example: 0x0102030405060708090a0102030405060708090a
std::regex const addressPattern("address\\((.*)\\)");
std::smatch match;
solAssert(std::regex_match(_solAddressString, match, addressPattern), "Abiv2 fuzzer: Invalid address string");
std::string addressHex = match[1].str();
addressHex.erase(2, 24);
return addressHex;
}
std::string ValueGetterVisitor::isabelleBytesValueAsString(std::string& _solBytesString)
{
std::regex const bytesPattern("hex\"(.*)\"");
std::smatch match;
solAssert(std::regex_match(_solBytesString, match, bytesPattern), "Abiv2 fuzzer: Invalid bytes string");
std::string bytesHex = match[1].str();
return "0x" + bytesHex;
}
std::string ValueGetterVisitor::variableLengthValueAsString(
unsigned _numBytes,
unsigned _counter,
bool _isHexLiteral
)
{
if (_numBytes == 0)
return Whiskers(R"(<?isHex>hex</isHex>"")")
("isHex", _isHexLiteral)
.render();
unsigned numBytesRemaining = _numBytes;
// Stores the literal
string output{};
// If requested value is shorter than or exactly 32 bytes,
// the literal is the return value of hexValueAsString.
if (numBytesRemaining <= 32)
output = hexValueAsString(
numBytesRemaining,
_counter,
_isHexLiteral,
/*decorate=*/false
);
// If requested value is longer than 32 bytes, the literal
// is obtained by duplicating the return value of hexValueAsString
// until we reach a value of the requested size.
else
{
// Create a 32-byte value to be duplicated and
// update number of bytes to be appended.
// Stores the cached literal that saves us
// (expensive) calls to keccak256.
string cachedString = hexValueAsString(
/*numBytes=*/32,
_counter,
_isHexLiteral,
/*decorate=*/false
);
output = cachedString;
numBytesRemaining -= 32;
// Append bytes from cachedString until
// we create a value of desired length.
unsigned numAppendedBytes;
while (numBytesRemaining > 0)
{
// We append at most 32 bytes at a time
numAppendedBytes = numBytesRemaining >= 32 ? 32 : numBytesRemaining;
output += cachedString.substr(
0,
// Double the substring length for hex literals since each
// character is actually half a byte (or a nibble).
_isHexLiteral ? numAppendedBytes * 2 : numAppendedBytes
);
numBytesRemaining -= numAppendedBytes;
}
solAssert(
numBytesRemaining == 0,
"Proto ABIv2 fuzzer: Logic flaw in variable literal creation"
);
}
if (_isHexLiteral)
solAssert(
output.size() == 2 * _numBytes,
"Proto ABIv2 fuzzer: Generated hex literal is of incorrect length"
);
else
solAssert(
output.size() == _numBytes,
"Proto ABIv2 fuzzer: Generated string literal is of incorrect length"
);
// Decorate output
return Whiskers(R"(<?isHexLiteral>hex</isHexLiteral>"<value>")")
("isHexLiteral", _isHexLiteral)
("value", output)
.render();
}
string ValueGetterVisitor::bytesArrayValueAsString(unsigned _counter, bool _isHexLiteral)
{
return variableLengthValueAsString(
getVarLength(_counter),
_counter,
_isHexLiteral
);
}