Code coverage for Solidity smart-contracts
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solidity-coverage/lib/parse.js

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/**
* Methods in this file walk the AST and call the instrumenter
* functions where appropriate, which determine where to inject events.
* (Listed in alphabetical order)
*/
const semver = require('semver');
const Registrar = require('./registrar');
const register = new Registrar();
const FILE_SCOPED_ID = "fileScopedId";
const parse = {};
// Utilities
parse.configureStatementCoverage = function(val){
register.measureStatementCoverage = val;
}
parse.configureFunctionCoverage = function(val){
register.measureFunctionCoverage = val;
}
parse.configureModifierCoverage = function(val){
register.measureModifierCoverage = val;
}
// Nodes
parse.AssignmentExpression = function(contract, expression) {
register.statement(contract, expression);
};
parse.Block = function(contract, expression) {
for (let x = 0; x < expression.statements.length; x++) {
register.line(contract, expression.statements[x]);
parse[expression.statements[x].type] &&
parse[expression.statements[x].type](contract, expression.statements[x]);
}
};
parse.BinaryOperation = function(contract, expression, skipStatementRegistry) {
// Free-floating ternary conditional
if (expression.left && expression.left.type === 'Conditional'){
parse[expression.left.type](contract, expression.left, true);
register.statement(contract, expression);
// Ternary conditional assignment
} else if (expression.right && expression.right.type === 'Conditional'){
parse[expression.right.type](contract, expression.right, true);
register.statement(contract, expression);
// Regular binary operation
} else if(!skipStatementRegistry){
register.statement(contract, expression);
// LogicalOR condition search...
} else {
parse[expression.left.type] &&
parse[expression.left.type](contract, expression.left, true);
parse[expression.right.type] &&
parse[expression.right.type](contract, expression.right, true);
if (expression.operator === '||'){
register.logicalOR(contract, expression);
}
}
}
parse.TupleExpression = function(contract, expression, skipStatementRegistry) {
expression.components.forEach(component => {
parse[component.type] &&
parse[component.type](contract, component, skipStatementRegistry);
});
}
parse.FunctionCall = function(contract, expression, skipStatementRegistry) {
// In any given chain of call expressions, only the last one will fail this check.
// This makes sure we don't instrument a chain of expressions multiple times.
if (expression.expression.type !== 'FunctionCall') {
// Don't register sub-expressions (like intermediate method calls)
if (!skipStatementRegistry){
register.statement(contract, expression);
}
if (expression.expression.name === 'require') {
register.requireBranch(contract, expression);
expression.arguments.forEach(arg => {
parse[arg.type] && parse[arg.type](contract, arg, true);
});
}
parse[expression.expression.type] &&
parse[expression.expression.type](contract, expression.expression);
} else {
parse[expression.expression.type] &&
parse[expression.expression.type](contract, expression.expression);
}
};
parse.Conditional = function(contract, expression, skipStatementRegistry) {
parse[expression.condition.type] &&
parse[expression.condition.type](contract, expression.condition, skipStatementRegistry);
register.conditional(contract, expression);
};
parse.ContractDefinition = function(contract, expression) {
parse.ContractOrLibraryStatement(contract, expression);
};
parse.ContractOrLibraryStatement = function(contract, expression) {
// We need to define a method to pass coverage hashes into at top of each contract.
// This lets us get a fresh stack for the hash and avoid stack-too-deep errors.
if (expression.kind !== 'interface'){
let start = 0;
// It's possible a base contract will have constructor string arg
// which contains an open curly brace. Skip ahead pass the bases...
if (expression.baseContracts && expression.baseContracts.length){
for (let base of expression.baseContracts ){
if (base.range[1] > start){
start = base.range[1];
}
}
} else {
start = expression.range[0];
}
const end = contract.instrumented.slice(start).indexOf('{') + 1;
const loc = start + end;;
contract.contractName = expression.name;
(contract.injectionPoints[loc])
? contract.injectionPoints[loc].push({ type: 'injectHashMethod', contractName: expression.name})
: contract.injectionPoints[loc] = [{ type: 'injectHashMethod', contractName: expression.name}];
}
if (expression.subNodes) {
// Set flag to allow alternate cov id generation of file-level fn defs
contract.isContractScoped = true;
expression.subNodes.forEach(construct => {
parse[construct.type] &&
parse[construct.type](contract, construct);
});
// Unset flag...
contract.isContractScoped = false;
}
};
parse.EmitStatement = function(contract, expression){
register.statement(contract, expression);
};
parse.ExpressionStatement = function(contract, content) {
parse[content.expression.type] &&
parse[content.expression.type](contract, content.expression);
};
parse.ForStatement = function(contract, expression) {
register.statement(contract, expression);
parse[expression.body.type] &&
parse[expression.body.type](contract, expression.body);
};
parse.FunctionDefinition = function(contract, expression) {
// Use generic name component to generate the hash for cov fn ids
// if we're not inside a contract
let tempContractName = contract.contractName;
if (!contract.isContractScoped){
contract.contractName = FILE_SCOPED_ID;
}
parse.Modifiers(contract, expression.modifiers);
if (expression.body) {
// Skip fn & statement instrumentation for `receive` methods to
// minimize gas distortion
(expression.name === null && expression.isReceiveEther)
? register.trackStatements = false
: register.functionDeclaration(contract, expression);
parse[expression.body.type] &&
parse[expression.body.type](contract, expression.body);
register.trackStatements = true;
}
// Reset contractName in case it was changed for file scoped methods
contract.contractName = tempContractName;
};
parse.IfStatement = function(contract, expression) {
register.statement(contract, expression);
register.ifStatement(contract, expression);
parse[expression.condition.type] &&
parse[expression.condition.type](contract, expression.condition, true);
parse[expression.trueBody.type] &&
parse[expression.trueBody.type](contract, expression.trueBody);
if (expression.falseBody) {
parse[expression.falseBody.type] &&
parse[expression.falseBody.type](contract, expression.falseBody);
}
};
// TODO: Investigate Node structure
/*parse.MemberAccess = function(contract, expression) {
parse[expression.object.type] &&
parse[expression.object.type](contract, expression.object);
};*/
parse.Modifiers = function(contract, modifiers) {
if (modifiers) {
modifiers.forEach(modifier => {
parse[modifier.type] && parse[modifier.type](contract, modifier);
});
}
};
parse.ModifierDefinition = function(contract, expression) {
register.functionDeclaration(contract, expression);
parse[expression.body.type] &&
parse[expression.body.type](contract, expression.body);
};
parse.NewExpression = function(contract, expression) {
parse[expression.typeName.type] &&
parse[expression.typeName.type](contract, expression.typeName);
};
parse.PragmaDirective = function(contract, expression){
let minVersion;
// Some solidity pragmas crash semver (ex: ABIEncoderV2)
try {
minVersion = semver.minVersion(expression.value);
} catch(e){
return;
}
// pragma abicoder v2 passes the semver test above but needs to be ignored
if (expression.name === 'abicoder'){
return
}
// From solc >=0.7.4, every file should have instrumentation methods
// defined at the file level which file scoped fns can use...
if (semver.lt("0.7.3", minVersion)){
const start = expression.range[0];
const end = contract.instrumented.slice(start).indexOf(';') + 1;
const loc = start + end;
const injectionObject = {
type: 'injectHashMethod',
contractName: FILE_SCOPED_ID,
isFileScoped: true
};
contract.injectionPoints[loc] = [injectionObject];
}
}
parse.SourceUnit = function(contract, expression) {
expression.children.forEach(construct => {
parse[construct.type] &&
parse[construct.type](contract, construct);
});
};
parse.ReturnStatement = function(contract, expression) {
register.statement(contract, expression);
expression.expression &&
parse[expression.expression.type] &&
parse[expression.expression.type](contract, expression.expression, true);
};
// TODO:Investigate node structure
/*parse.UnaryOperation = function(contract, expression) {
parse[subExpression.argument.type] &&
parse[subExpression.argument.type](contract, expression.argument);
};*/
parse.TryStatement = function(contract, expression) {
register.statement(contract, expression);
parse[expression.body.type] &&
parse[expression.body.type](contract, expression.body);
for (let x = 0; x < expression.catchClauses.length; x++) {
parse[expression.catchClauses[x].body.type] &&
parse[expression.catchClauses[x].body.type](contract, expression.catchClauses[x].body);
}
};
parse.UncheckedStatement = function(contract, expression) {
parse[expression.block.type] &&
parse[expression.block.type](contract, expression.block);
}
parse.UsingStatement = function (contract, expression) {
parse[expression.for.type] &&
parse[expression.for.type](contract, expression.for);
};
parse.VariableDeclarationStatement = function (contract, expression) {
if (expression.initialValue && expression.initialValue.type === 'Conditional'){
parse[expression.initialValue.type](contract, expression.initialValue, true)
}
register.statement(contract, expression);
};
parse.WhileStatement = function (contract, expression) {
register.statement(contract, expression);
parse[expression.condition.type] &&
parse[expression.condition.type](contract, expression.condition, true);
parse[expression.body.type] &&
parse[expression.body.type](contract, expression.body);
};
module.exports = parse;