solidity/libsolidity/analysis/OverrideChecker.cpp
2019-12-11 15:15:51 +01:00

873 lines
26 KiB
C++

/*
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 <http://www.gnu.org/licenses/>.
*/
/**
* Component that verifies overloads, abstract contracts, function clashes and others
* checks at contract or function level.
*/
#include <libsolidity/analysis/OverrideChecker.h>
#include <libsolidity/ast/AST.h>
#include <libsolidity/ast/TypeProvider.h>
#include <libsolidity/analysis/TypeChecker.h>
#include <liblangutil/ErrorReporter.h>
#include <libdevcore/Visitor.h>
#include <boost/range/adaptor/reversed.hpp>
#include <boost/algorithm/string/predicate.hpp>
using namespace std;
using namespace dev;
using namespace langutil;
using namespace dev::solidity;
namespace
{
// Helper struct to do a search by name
struct MatchByName
{
string const& m_name;
bool operator()(OverrideProxy const& _item)
{
return _item.name() == m_name;
}
};
vector<ContractDefinition const*> resolveDirectBaseContracts(ContractDefinition const& _contract)
{
vector<ContractDefinition const*> resolvedContracts;
for (ASTPointer<InheritanceSpecifier> const& specifier: _contract.baseContracts())
{
Declaration const* baseDecl =
specifier->name().annotation().referencedDeclaration;
auto contract = dynamic_cast<ContractDefinition const*>(baseDecl);
solAssert(contract, "contract is null");
resolvedContracts.emplace_back(contract);
}
return resolvedContracts;
}
vector<ASTPointer<UserDefinedTypeName>> sortByContract(vector<ASTPointer<UserDefinedTypeName>> const& _list)
{
auto sorted = _list;
stable_sort(sorted.begin(), sorted.end(),
[] (ASTPointer<UserDefinedTypeName> _a, ASTPointer<UserDefinedTypeName> _b) {
if (!_a || !_b)
return _a < _b;
Declaration const* aDecl = _a->annotation().referencedDeclaration;
Declaration const* bDecl = _b->annotation().referencedDeclaration;
if (!aDecl || !bDecl)
return aDecl < bDecl;
return aDecl->id() < bDecl->id();
}
);
return sorted;
}
OverrideProxy makeOverrideProxy(CallableDeclaration const& _callable)
{
if (auto const* fun = dynamic_cast<FunctionDefinition const*>(&_callable))
return OverrideProxy{fun};
else if (auto const* mod = dynamic_cast<ModifierDefinition const*>(&_callable))
return OverrideProxy{mod};
else
solAssert(false, "Invalid call to makeOverrideProxy.");
return {};
}
}
bool OverrideProxy::operator<(OverrideProxy const& _other) const
{
return id() < _other.id();
}
bool OverrideProxy::isVariable() const
{
return holds_alternative<VariableDeclaration const*>(m_item);
}
bool OverrideProxy::isFunction() const
{
return holds_alternative<FunctionDefinition const*>(m_item);
}
bool OverrideProxy::isModifier() const
{
return holds_alternative<ModifierDefinition const*>(m_item);
}
bool OverrideProxy::CompareBySignature::operator()(OverrideProxy const& _a, OverrideProxy const& _b) const
{
return _a.overrideComparator() < _b.overrideComparator();
}
size_t OverrideProxy::id() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) -> size_t { return _item->id(); }
}, m_item);
}
shared_ptr<OverrideSpecifier> OverrideProxy::overrides() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) { return _item->overrides(); }
}, m_item);
}
set<OverrideProxy> OverrideProxy::baseFunctions() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) -> set<OverrideProxy> {
set<OverrideProxy> ret;
for (auto const* f: _item->annotation().baseFunctions)
ret.insert(makeOverrideProxy(*f));
return ret;
}
}, m_item);
}
void OverrideProxy::storeBaseFunction(OverrideProxy const& _base) const
{
std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) {
_item->annotation().baseFunctions.emplace(std::get<FunctionDefinition const*>(_base.m_item));
},
[&](ModifierDefinition const* _item) {
_item->annotation().baseFunctions.emplace(std::get<ModifierDefinition const*>(_base.m_item));
},
[&](VariableDeclaration const* _item) {
_item->annotation().baseFunctions.emplace(std::get<FunctionDefinition const*>(_base.m_item));
}
}, m_item);
}
string const& OverrideProxy::name() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) -> string const& { return _item->name(); }
}, m_item);
}
ContractDefinition const& OverrideProxy::contract() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) -> ContractDefinition const& {
return dynamic_cast<ContractDefinition const&>(*_item->scope());
}
}, m_item);
}
string const& OverrideProxy::contractName() const
{
return contract().name();
}
Visibility OverrideProxy::visibility() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return _item->visibility(); },
[&](ModifierDefinition const* _item) { return _item->visibility(); },
[&](VariableDeclaration const*) { return Visibility::External; }
}, m_item);
}
StateMutability OverrideProxy::stateMutability() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return _item->stateMutability(); },
[&](ModifierDefinition const*) { solAssert(false, "Requested state mutability from modifier."); return StateMutability{}; },
[&](VariableDeclaration const*) { return StateMutability::View; }
}, m_item);
}
bool OverrideProxy::virtualSemantics() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return _item->virtualSemantics(); },
[&](ModifierDefinition const* _item) { return _item->virtualSemantics(); },
[&](VariableDeclaration const*) { return false; }
}, m_item);
}
Token OverrideProxy::functionKind() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return _item->kind(); },
[&](ModifierDefinition const*) { return Token::Function; },
[&](VariableDeclaration const*) { return Token::Function; }
}, m_item);
}
FunctionType const* OverrideProxy::functionType() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return FunctionType(*_item).asCallableFunction(false); },
[&](VariableDeclaration const* _item) { return FunctionType(*_item).asCallableFunction(false); },
[&](ModifierDefinition const*) -> FunctionType const* { solAssert(false, "Requested function type of modifier."); return nullptr; }
}, m_item);
}
ModifierType const* OverrideProxy::modifierType() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const*) -> ModifierType const* { solAssert(false, "Requested modifier type of function."); return nullptr; },
[&](VariableDeclaration const*) -> ModifierType const* { solAssert(false, "Requested modifier type of variable."); return nullptr; },
[&](ModifierDefinition const* _modifier) -> ModifierType const* { return TypeProvider::modifier(*_modifier); }
}, m_item);
}
SourceLocation const& OverrideProxy::location() const
{
return std::visit(GenericVisitor{
[&](auto const* _item) -> SourceLocation const& { return _item->location(); }
}, m_item);
}
string OverrideProxy::astNodeName() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const*) { return "function"; },
[&](ModifierDefinition const*) { return "modifier"; },
[&](VariableDeclaration const*) { return "public state variable"; },
}, m_item);
}
string OverrideProxy::astNodeNameCapitalized() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const*) { return "Function"; },
[&](ModifierDefinition const*) { return "Modifier"; },
[&](VariableDeclaration const*) { return "Public state variable"; },
}, m_item);
}
string OverrideProxy::distinguishingProperty() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const*) { return "name and parameter types"; },
[&](ModifierDefinition const*) { return "name"; },
[&](VariableDeclaration const*) { return "name and parameter types"; },
}, m_item);
}
bool OverrideProxy::unimplemented() const
{
return std::visit(GenericVisitor{
[&](FunctionDefinition const* _item) { return !_item->isImplemented(); },
[&](ModifierDefinition const*) { return false; },
[&](VariableDeclaration const*) { return false; }
}, m_item);
}
bool OverrideProxy::OverrideComparator::operator<(OverrideComparator const& _other) const
{
if (name != _other.name)
return name < _other.name;
if (!functionKind || !_other.functionKind)
return false;
if (functionKind != _other.functionKind)
return *functionKind < *_other.functionKind;
if (!parameterTypes || !_other.parameterTypes)
return false;
return boost::lexicographical_compare(*parameterTypes, *_other.parameterTypes);
}
OverrideProxy::OverrideComparator const& OverrideProxy::overrideComparator() const
{
if (!m_comparator)
{
m_comparator = make_shared<OverrideComparator>(std::visit(GenericVisitor{
[&](FunctionDefinition const* _function)
{
vector<string> paramTypes;
for (Type const* t: functionType()->parameterTypes())
paramTypes.emplace_back(t->richIdentifier());
return OverrideComparator{
_function->name(),
_function->kind(),
std::move(paramTypes)
};
},
[&](VariableDeclaration const* _var)
{
vector<string> paramTypes;
for (Type const* t: functionType()->parameterTypes())
paramTypes.emplace_back(t->richIdentifier());
return OverrideComparator{
_var->name(),
Token::Function,
std::move(paramTypes)
};
},
[&](ModifierDefinition const* _mod)
{
return OverrideComparator{
_mod->name(),
{},
{}
};
}
}, m_item));
}
return *m_comparator;
}
bool OverrideChecker::LessFunction::operator()(ModifierDefinition const* _a, ModifierDefinition const* _b) const
{
return _a->name() < _b->name();
}
bool OverrideChecker::LessFunction::operator()(FunctionDefinition const* _a, FunctionDefinition const* _b) const
{
if (_a->name() != _b->name())
return _a->name() < _b->name();
if (_a->kind() != _b->kind())
return _a->kind() < _b->kind();
return boost::lexicographical_compare(
TypeProvider::function(*_a)->asCallableFunction(false)->parameterTypes(),
TypeProvider::function(*_b)->asCallableFunction(false)->parameterTypes(),
[](auto const& _paramTypeA, auto const& _paramTypeB)
{
return _paramTypeA->richIdentifier() < _paramTypeB->richIdentifier();
}
);
}
bool OverrideChecker::LessFunction::operator()(ContractDefinition const* _a, ContractDefinition const* _b) const
{
if (!_a || !_b)
return _a < _b;
return _a->id() < _b->id();
}
void OverrideChecker::check(ContractDefinition const& _contract)
{
checkIllegalOverrides(_contract);
checkAmbiguousOverrides(_contract);
}
void OverrideChecker::checkIllegalOverrides(ContractDefinition const& _contract)
{
OverrideProxyBySignatureMultiSet const& inheritedFuncs = inheritedFunctions(_contract);
OverrideProxyBySignatureMultiSet const& inheritedMods = inheritedModifiers(_contract);
for (ModifierDefinition const* modifier: _contract.functionModifiers())
{
if (contains_if(inheritedFuncs, MatchByName{modifier->name()}))
m_errorReporter.typeError(
modifier->location(),
"Override changes function or public state variable to modifier."
);
checkOverrideList(OverrideProxy{modifier}, inheritedMods);
}
for (FunctionDefinition const* function: _contract.definedFunctions())
{
if (function->isConstructor())
continue;
if (contains_if(inheritedMods, MatchByName{function->name()}))
m_errorReporter.typeError(function->location(), "Override changes modifier to function.");
checkOverrideList(OverrideProxy{function}, inheritedFuncs);
}
for (auto const* stateVar: _contract.stateVariables())
{
if (!stateVar->isPublic())
continue;
if (contains_if(inheritedMods, MatchByName{stateVar->name()}))
m_errorReporter.typeError(stateVar->location(), "Override changes modifier to public state variable.");
checkOverrideList(OverrideProxy{stateVar}, inheritedFuncs);
}
}
void OverrideChecker::checkOverride(OverrideProxy const& _overriding, OverrideProxy const& _super)
{
solAssert(_super.isModifier() == _overriding.isModifier(), "");
if (_super.isFunction() || _super.isModifier())
_overriding.storeBaseFunction(_super);
if (_overriding.isModifier() && *_overriding.modifierType() != *_super.modifierType())
m_errorReporter.typeError(
_overriding.location(),
"Override changes modifier signature."
);
if (!_overriding.overrides())
overrideError(_overriding, _super, "Overriding " + _overriding.astNodeName() + " is missing 'override' specifier.");
if (_super.isVariable())
overrideError(
_super,
_overriding,
"Cannot override public state variable.",
"Overriding " + _overriding.astNodeName() + " is here:"
);
else if (!_super.virtualSemantics())
overrideError(
_super,
_overriding,
"Trying to override non-virtual " + _super.astNodeName() + ". Did you forget to add \"virtual\"?",
"Overriding " + _overriding.astNodeName() + " is here:"
);
if (_overriding.isVariable())
{
if (_super.visibility() != Visibility::External)
overrideError(_overriding, _super, "Public state variables can only override functions with external visibility.");
solAssert(_overriding.visibility() == Visibility::External, "");
}
else if (_overriding.visibility() != _super.visibility())
{
// Visibility change from external to public is fine.
// Any other change is disallowed.
if (!(
_super.visibility() == Visibility::External &&
_overriding.visibility() == Visibility::Public
))
overrideError(_overriding, _super, "Overriding " + _overriding.astNodeName() + " visibility differs.");
}
if (_super.isFunction())
{
FunctionType const* functionType = _overriding.functionType();
FunctionType const* superType = _super.functionType();
solAssert(functionType->hasEqualParameterTypes(*superType), "Override doesn't have equal parameters!");
if (!functionType->hasEqualReturnTypes(*superType))
overrideError(_overriding, _super, "Overriding " + _overriding.astNodeName() + " return types differ.");
// This is only relevant for a function overriding a function.
if (_overriding.isFunction())
{
if (_overriding.stateMutability() != _super.stateMutability())
overrideError(
_overriding,
_super,
"Overriding function changes state mutability from \"" +
stateMutabilityToString(_super.stateMutability()) +
"\" to \"" +
stateMutabilityToString(_overriding.stateMutability()) +
"\"."
);
if (_overriding.unimplemented() && !_super.unimplemented())
overrideError(
_overriding,
_super,
"Overriding an implemented function with an unimplemented function is not allowed."
);
}
}
}
void OverrideChecker::overrideListError(
OverrideProxy const& _item,
set<ContractDefinition const*, LessFunction> _secondary,
string const& _message1,
string const& _message2
)
{
// Using a set rather than a vector so the order is always the same
set<string> names;
SecondarySourceLocation ssl;
for (Declaration const* c: _secondary)
{
ssl.append("This contract: ", c->location());
names.insert(c->name());
}
string contractSingularPlural = "contract ";
if (_secondary.size() > 1)
contractSingularPlural = "contracts ";
m_errorReporter.typeError(
_item.overrides() ? _item.overrides()->location() : _item.location(),
ssl,
_message1 +
contractSingularPlural +
_message2 +
joinHumanReadable(names, ", ", " and ") +
"."
);
}
void OverrideChecker::overrideError(Declaration const& _overriding, Declaration const& _super, string const& _message, string const& _secondaryMsg)
{
m_errorReporter.typeError(
_overriding.location(),
SecondarySourceLocation().append(_secondaryMsg, _super.location()),
_message
);
}
void OverrideChecker::overrideError(OverrideProxy const& _overriding, OverrideProxy const& _super, string const& _message, string const& _secondaryMsg)
{
m_errorReporter.typeError(
_overriding.location(),
SecondarySourceLocation().append(_secondaryMsg, _super.location()),
_message
);
}
void OverrideChecker::checkAmbiguousOverrides(ContractDefinition const& _contract) const
{
{
// Fetch inherited functions and sort them by signature.
// We get at least one function per signature and direct base contract, which is
// enough because we re-construct the inheritance graph later.
OverrideProxyBySignatureMultiSet nonOverriddenFunctions = inheritedFunctions(_contract);
// Remove all functions that match the signature of a function in the current contract.
for (FunctionDefinition const* f: _contract.definedFunctions())
nonOverriddenFunctions.erase(OverrideProxy{f});
for (VariableDeclaration const* v: _contract.stateVariables())
if (v->isPublic())
nonOverriddenFunctions.erase(OverrideProxy{v});
// Walk through the set of functions signature by signature.
for (auto it = nonOverriddenFunctions.cbegin(); it != nonOverriddenFunctions.cend();)
{
std::set<OverrideProxy> baseFunctions;
for (auto nextSignature = nonOverriddenFunctions.upper_bound(*it); it != nextSignature; ++it)
baseFunctions.insert(*it);
checkAmbiguousOverridesInternal(std::move(baseFunctions), _contract.location());
}
}
{
OverrideProxyBySignatureMultiSet modifiers = inheritedModifiers(_contract);
for (ModifierDefinition const* mod: _contract.functionModifiers())
modifiers.erase(OverrideProxy{mod});
for (auto it = modifiers.cbegin(); it != modifiers.cend();)
{
std::set<OverrideProxy> baseModifiers;
for (auto next = modifiers.upper_bound(*it); it != next; ++it)
baseModifiers.insert(*it);
checkAmbiguousOverridesInternal(std::move(baseModifiers), _contract.location());
}
}
}
void OverrideChecker::checkAmbiguousOverridesInternal(set<OverrideProxy> _baseCallables, SourceLocation const& _location) const
{
if (_baseCallables.size() <= 1)
return;
// Construct the override graph for this signature.
// Reserve node 0 for the current contract and node
// 1 for an artificial top node to which all override paths
// connect at the end.
struct OverrideGraph
{
OverrideGraph(decltype(_baseCallables) const& _baseCallables)
{
for (auto const& baseFunction: _baseCallables)
addEdge(0, visit(baseFunction));
}
std::map<OverrideProxy, int> nodes;
std::map<int, OverrideProxy> nodeInv;
std::map<int, std::set<int>> edges;
int numNodes = 2;
void addEdge(int _a, int _b)
{
edges[_a].insert(_b);
edges[_b].insert(_a);
}
private:
/// Completes the graph starting from @a _function and
/// @returns the node ID.
int visit(OverrideProxy const& _function)
{
auto it = nodes.find(_function);
if (it != nodes.end())
return it->second;
int currentNode = numNodes++;
nodes[_function] = currentNode;
nodeInv[currentNode] = _function;
if (_function.overrides())
for (auto const& baseFunction: _function.baseFunctions())
addEdge(currentNode, visit(baseFunction));
else
addEdge(currentNode, 1);
return currentNode;
}
} overrideGraph(_baseCallables);
// Detect cut vertices following https://en.wikipedia.org/wiki/Biconnected_component#Pseudocode
// Can ignore the root node, since it is never a cut vertex in our case.
struct CutVertexFinder
{
CutVertexFinder(OverrideGraph const& _graph): m_graph(_graph)
{
run();
}
std::set<OverrideProxy> const& cutVertices() const { return m_cutVertices; }
private:
OverrideGraph const& m_graph;
std::vector<bool> m_visited = std::vector<bool>(m_graph.numNodes, false);
std::vector<int> m_depths = std::vector<int>(m_graph.numNodes, -1);
std::vector<int> m_low = std::vector<int>(m_graph.numNodes, -1);
std::vector<int> m_parent = std::vector<int>(m_graph.numNodes, -1);
std::set<OverrideProxy> m_cutVertices{};
void run(int _u = 0, int _depth = 0)
{
m_visited.at(_u) = true;
m_depths.at(_u) = m_low.at(_u) = _depth;
for (int v: m_graph.edges.at(_u))
if (!m_visited.at(v))
{
m_parent[v] = _u;
run(v, _depth + 1);
if (m_low[v] >= m_depths[_u] && m_parent[_u] != -1)
m_cutVertices.insert(m_graph.nodeInv.at(_u));
m_low[_u] = min(m_low[_u], m_low[v]);
}
else if (v != m_parent[_u])
m_low[_u] = min(m_low[_u], m_depths[v]);
}
} cutVertexFinder{overrideGraph};
// Remove all base functions overridden by cut vertices (they don't need to be overridden).
for (OverrideProxy const& function: cutVertexFinder.cutVertices())
{
std::set<OverrideProxy> toTraverse = function.baseFunctions();
while (!toTraverse.empty())
{
OverrideProxy base = *toTraverse.begin();
toTraverse.erase(toTraverse.begin());
_baseCallables.erase(base);
for (OverrideProxy const& f: base.baseFunctions())
toTraverse.insert(f);
}
// Remove unimplemented base functions at the cut vertices itself as well.
if (function.unimplemented())
_baseCallables.erase(function);
}
// If more than one function is left, they have to be overridden.
if (_baseCallables.size() <= 1)
return;
SecondarySourceLocation ssl;
for (OverrideProxy const& baseFunction: _baseCallables)
ssl.append("Definition in \"" + baseFunction.contractName() + "\": ", baseFunction.location());
string callableName = _baseCallables.begin()->astNodeName();
if (_baseCallables.begin()->isVariable())
callableName = "function";
string distinguishigProperty = _baseCallables.begin()->distinguishingProperty();
bool foundVariable = false;
for (auto const& base: _baseCallables)
if (base.isVariable())
foundVariable = true;
string message =
"Derived contract must override " + callableName + " \"" +
_baseCallables.begin()->name() +
"\". Two or more base classes define " + callableName + " with same " + distinguishigProperty + ".";
if (foundVariable)
message +=
" Since one of the bases defines a public state variable which cannot be overridden, "
"you have to change the inheritance layout or the names of the functions.";
m_errorReporter.typeError(_location, ssl, message);
}
set<ContractDefinition const*, OverrideChecker::LessFunction> OverrideChecker::resolveOverrideList(OverrideSpecifier const& _overrides) const
{
set<ContractDefinition const*, LessFunction> resolved;
for (ASTPointer<UserDefinedTypeName> const& override: _overrides.overrides())
{
Declaration const* decl = override->annotation().referencedDeclaration;
solAssert(decl, "Expected declaration to be resolved.");
// If it's not a contract it will be caught
// in the reference resolver
if (ContractDefinition const* contract = dynamic_cast<decltype(contract)>(decl))
resolved.insert(contract);
}
return resolved;
}
void OverrideChecker::checkOverrideList(OverrideProxy _item, OverrideProxyBySignatureMultiSet const& _inherited)
{
set<ContractDefinition const*, LessFunction> specifiedContracts =
_item.overrides() ?
resolveOverrideList(*_item.overrides()) :
decltype(specifiedContracts){};
// Check for duplicates in override list
if (_item.overrides() && specifiedContracts.size() != _item.overrides()->overrides().size())
{
// Sort by contract id to find duplicate for error reporting
vector<ASTPointer<UserDefinedTypeName>> list =
sortByContract(_item.overrides()->overrides());
// Find duplicates and output error
for (size_t i = 1; i < list.size(); i++)
{
Declaration const* aDecl = list[i]->annotation().referencedDeclaration;
Declaration const* bDecl = list[i-1]->annotation().referencedDeclaration;
if (!aDecl || !bDecl)
continue;
if (aDecl->id() == bDecl->id())
{
SecondarySourceLocation ssl;
ssl.append("First occurrence here: ", list[i-1]->location());
m_errorReporter.typeError(
list[i]->location(),
ssl,
"Duplicate contract \"" +
joinHumanReadable(list[i]->namePath(), ".") +
"\" found in override list of \"" +
_item.name() +
"\"."
);
}
}
}
set<ContractDefinition const*, LessFunction> expectedContracts;
// Build list of expected contracts
for (auto [begin, end] = _inherited.equal_range(_item); begin != end; begin++)
{
// Validate the override
checkOverride(_item, *begin);
expectedContracts.insert(&begin->contract());
}
if (_item.overrides() && expectedContracts.empty())
m_errorReporter.typeError(
_item.overrides()->location(),
_item.astNodeNameCapitalized() + " has override specified but does not override anything."
);
decltype(specifiedContracts) missingContracts;
// If we expect only one contract, no contract needs to be specified
if (expectedContracts.size() > 1)
missingContracts = expectedContracts - specifiedContracts;
if (!missingContracts.empty())
overrideListError(
_item,
missingContracts,
_item.astNodeNameCapitalized() + " needs to specify overridden ",
""
);
auto surplusContracts = specifiedContracts - expectedContracts;
if (!surplusContracts.empty())
overrideListError(
_item,
surplusContracts,
"Invalid ",
"specified in override list: "
);
}
OverrideChecker::OverrideProxyBySignatureMultiSet const& OverrideChecker::inheritedFunctions(ContractDefinition const& _contract) const
{
if (!m_inheritedFunctions.count(&_contract))
{
OverrideProxyBySignatureMultiSet result;
for (auto const* base: resolveDirectBaseContracts(_contract))
{
set<OverrideProxy, OverrideProxy::CompareBySignature> functionsInBase;
for (FunctionDefinition const* fun: base->definedFunctions())
if (!fun->isConstructor())
functionsInBase.emplace(OverrideProxy{fun});
for (VariableDeclaration const* var: base->stateVariables())
if (var->isPublic())
functionsInBase.emplace(OverrideProxy{var});
for (OverrideProxy const& func: inheritedFunctions(*base))
functionsInBase.insert(func);
result += functionsInBase;
}
m_inheritedFunctions[&_contract] = result;
}
return m_inheritedFunctions[&_contract];
}
OverrideChecker::OverrideProxyBySignatureMultiSet const& OverrideChecker::inheritedModifiers(ContractDefinition const& _contract) const
{
if (!m_inheritedModifiers.count(&_contract))
{
OverrideProxyBySignatureMultiSet result;
for (auto const* base: resolveDirectBaseContracts(_contract))
{
set<OverrideProxy, OverrideProxy::CompareBySignature> modifiersInBase;
for (ModifierDefinition const* mod: base->functionModifiers())
modifiersInBase.emplace(OverrideProxy{mod});
for (OverrideProxy const& mod: inheritedModifiers(*base))
modifiersInBase.insert(mod);
result += modifiersInBase;
}
m_inheritedModifiers[&_contract] = result;
}
return m_inheritedModifiers[&_contract];
}