mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
182 lines
6.8 KiB
C++
182 lines
6.8 KiB
C++
/*
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This file is part of solidity.
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solidity is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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solidity is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with solidity. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <libsolidity/analysis/ControlFlowAnalyzer.h>
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#include <liblangutil/SourceLocation.h>
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#include <libdevcore/Algorithms.h>
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#include <boost/range/algorithm/sort.hpp>
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using namespace std;
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using namespace langutil;
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using namespace dev::solidity;
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bool ControlFlowAnalyzer::analyze(ASTNode const& _astRoot)
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{
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_astRoot.accept(*this);
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return Error::containsOnlyWarnings(m_errorReporter.errors());
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}
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bool ControlFlowAnalyzer::visit(FunctionDefinition const& _function)
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{
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if (_function.isImplemented())
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{
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auto const& functionFlow = m_cfg.functionFlow(_function);
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checkUninitializedAccess(functionFlow.entry, functionFlow.exit);
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checkUnreachable(functionFlow.entry, functionFlow.exit, functionFlow.revert);
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}
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return false;
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}
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void ControlFlowAnalyzer::checkUninitializedAccess(CFGNode const* _entry, CFGNode const* _exit) const
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{
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struct NodeInfo
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{
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set<VariableDeclaration const*> unassignedVariablesAtEntry;
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set<VariableDeclaration const*> unassignedVariablesAtExit;
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set<VariableOccurrence const*> uninitializedVariableAccesses;
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/// Propagate the information from another node to this node.
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/// To be used to propagate information from a node to its exit nodes.
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/// Returns true, if new variables were added and thus the current node has
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/// to be traversed again.
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bool propagateFrom(NodeInfo const& _entryNode)
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{
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size_t previousUnassignedVariablesAtEntry = unassignedVariablesAtEntry.size();
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size_t previousUninitializedVariableAccessess = uninitializedVariableAccesses.size();
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unassignedVariablesAtEntry += _entryNode.unassignedVariablesAtExit;
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uninitializedVariableAccesses += _entryNode.uninitializedVariableAccesses;
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return
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unassignedVariablesAtEntry.size() > previousUnassignedVariablesAtEntry ||
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uninitializedVariableAccesses.size() > previousUninitializedVariableAccessess
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;
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}
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};
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map<CFGNode const*, NodeInfo> nodeInfos;
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set<CFGNode const*> nodesToTraverse;
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nodesToTraverse.insert(_entry);
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// Walk all paths starting from the nodes in ``nodesToTraverse`` until ``NodeInfo::propagateFrom``
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// returns false for all exits, i.e. until all paths have been walked with maximal sets of unassigned
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// variables and accesses.
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while (!nodesToTraverse.empty())
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{
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CFGNode const* currentNode = *nodesToTraverse.begin();
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nodesToTraverse.erase(nodesToTraverse.begin());
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auto& nodeInfo = nodeInfos[currentNode];
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auto unassignedVariables = nodeInfo.unassignedVariablesAtEntry;
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for (auto const& variableOccurrence: currentNode->variableOccurrences)
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{
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switch (variableOccurrence.kind())
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{
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case VariableOccurrence::Kind::Assignment:
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unassignedVariables.erase(&variableOccurrence.declaration());
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break;
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case VariableOccurrence::Kind::InlineAssembly:
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// We consider all variables referenced in inline assembly as accessed.
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// So far any reference is enough, but we might want to actually analyze
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// the control flow in the assembly at some point.
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case VariableOccurrence::Kind::Access:
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case VariableOccurrence::Kind::Return:
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if (unassignedVariables.count(&variableOccurrence.declaration()))
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{
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if (variableOccurrence.declaration().type()->dataStoredIn(DataLocation::Storage))
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// Merely store the unassigned access. We do not generate an error right away, since this
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// path might still always revert. It is only an error if this is propagated to the exit
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// node of the function (i.e. there is a path with an uninitialized access).
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nodeInfo.uninitializedVariableAccesses.insert(&variableOccurrence);
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}
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break;
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case VariableOccurrence::Kind::Declaration:
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unassignedVariables.insert(&variableOccurrence.declaration());
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break;
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}
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}
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nodeInfo.unassignedVariablesAtExit = std::move(unassignedVariables);
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// Propagate changes to all exits and queue them for traversal, if needed.
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for (auto const& exit: currentNode->exits)
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if (nodeInfos[exit].propagateFrom(nodeInfo))
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nodesToTraverse.insert(exit);
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}
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auto const& exitInfo = nodeInfos[_exit];
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if (!exitInfo.uninitializedVariableAccesses.empty())
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{
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vector<VariableOccurrence const*> uninitializedAccessesOrdered(
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exitInfo.uninitializedVariableAccesses.begin(),
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exitInfo.uninitializedVariableAccesses.end()
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);
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boost::range::sort(
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uninitializedAccessesOrdered,
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[](VariableOccurrence const* lhs, VariableOccurrence const* rhs) -> bool
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{
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return *lhs < *rhs;
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}
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);
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for (auto const* variableOccurrence: uninitializedAccessesOrdered)
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{
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SecondarySourceLocation ssl;
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if (variableOccurrence->occurrence())
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ssl.append("The variable was declared here.", variableOccurrence->declaration().location());
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m_errorReporter.typeError(
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variableOccurrence->occurrence() ?
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variableOccurrence->occurrence()->location() :
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variableOccurrence->declaration().location(),
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ssl,
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string("This variable is of storage pointer type and can be ") +
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(variableOccurrence->kind() == VariableOccurrence::Kind::Return ? "returned" : "accessed") +
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" without prior assignment."
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);
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}
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}
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}
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void ControlFlowAnalyzer::checkUnreachable(CFGNode const* _entry, CFGNode const* _exit, CFGNode const* _revert) const
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{
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// collect all nodes reachable from the entry point
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std::set<CFGNode const*> reachable = BreadthFirstSearch<CFGNode>{{_entry}}.run(
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[](CFGNode const& _node, auto&& _addChild) {
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for (CFGNode const* exit: _node.exits)
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_addChild(*exit);
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}
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).visited;
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// traverse all paths backwards from exit and revert
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// and extract (valid) source locations of unreachable nodes into sorted set
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std::set<SourceLocation> unreachable;
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BreadthFirstSearch<CFGNode>{{_exit, _revert}}.run(
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[&](CFGNode const& _node, auto&& _addChild) {
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if (!reachable.count(&_node) && !_node.location.isEmpty())
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unreachable.insert(_node.location);
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for (CFGNode const* entry: _node.entries)
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_addChild(*entry);
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}
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);
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for (auto it = unreachable.begin(); it != unreachable.end();)
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{
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SourceLocation location = *it++;
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// Extend the location, as long as the next location overlaps (unreachable is sorted).
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for (; it != unreachable.end() && it->start <= location.end; ++it)
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location.end = std::max(location.end, it->end);
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m_errorReporter.warning(location, "Unreachable code.");
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}
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}
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