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Quasar RAT Disguised as an npm Package for Detecting Vulnerabilities in Ethereum Smart Contracts
Socket researchers uncover a malicious npm package posing as a tool for detecting vulnerabilities in Etherium smart contracts.
JavaScript bindings for the Solidity compiler.
Uses the Emscripten compiled Solidity found in the solc-bin repository.
To use the latest stable version of the Solidity compiler via Node.js you can install it via npm:
npm install solc
If this package is installed globally (npm install -g solc
), a command-line tool called solcjs
will be available.
To see all the supported features, execute:
solcjs --help
To compile a contract that imports other contracts via relative paths:
solcjs --bin --include-path node_modules/ --base-path . MainContract.sol
Use the --base-path
and --include-path
options to describe the layout of your project.
--base-path
represents the root of your own source tree while --include-path
allows you to
specify extra locations containing external code (e.g. libraries installed with a package manager).
Note: ensure that all the files you specify on the command line are located inside the base path or one of the include paths. The compiler refers to files from outside of these directories using absolute paths. Having absolute paths in contract metadata will result in your bytecode being reproducible only when it's placed in these exact absolute locations.
Note: this commandline interface is not compatible with solc
provided by the Solidity compiler package and thus cannot be
used in combination with an Ethereum client via the eth.compile.solidity()
RPC method. Please refer to the
Solidity compiler documentation for instructions to install solc
.
Furthermore, the commandline interface to solc-js provides fewer features than the binary release.
There are two ways to use solc
:
The high-level API consists of a single method, compile
, which expects the Compiler Standard Input and Output JSON.
It also accepts an optional set of callback functions, which include the import
and the smtSolver
callbacks.
Starting 0.6.0 it only accepts an object in place of the callback to supply the callbacks.
The import
callback function is used to resolve unmet dependencies.
This callback receives a path and must synchronously return either an error or the content of the dependency
as a string. It cannot be used together with callback-based, asynchronous,
filesystem access. A workaround is to collect the names of dependencies, return
an error, and keep re-running the compiler until all of them are resolved.
Example:
var solc = require('solc');
var input = {
language: 'Solidity',
sources: {
'test.sol': {
content: 'contract C { function f() public { } }'
}
},
settings: {
outputSelection: {
'*': {
'*': ['*']
}
}
}
};
var output = JSON.parse(solc.compile(JSON.stringify(input)));
// `output` here contains the JSON output as specified in the documentation
for (var contractName in output.contracts['test.sol']) {
console.log(
contractName +
': ' +
output.contracts['test.sol'][contractName].evm.bytecode.object
);
}
var solc = require('solc');
var input = {
language: 'Solidity',
sources: {
'test.sol': {
content: 'import "lib.sol"; contract C { function f() public { L.f(); } }'
}
},
settings: {
outputSelection: {
'*': {
'*': ['*']
}
}
}
};
function findImports(path) {
if (path === 'lib.sol')
return {
contents:
'library L { function f() internal returns (uint) { return 7; } }'
};
else return { error: 'File not found' };
}
// New syntax (supported from 0.5.12, mandatory from 0.6.0)
var output = JSON.parse(
solc.compile(JSON.stringify(input), { import: findImports })
);
// `output` here contains the JSON output as specified in the documentation
for (var contractName in output.contracts['test.sol']) {
console.log(
contractName +
': ' +
output.contracts['test.sol'][contractName].evm.bytecode.object
);
}
Since version 0.5.1, the smtSolver
callback function is used to solve SMT queries generated by
Solidity's SMTChecker. If you have an SMT solver installed locally, it can
be used to solve the given queries, where the callback must synchronously
return either an error or the result from the solver. A default
smtSolver
callback is included in this package via the module
smtchecker.js
which exports the smtCallback
function that takes 1) a
function that takes queries and returns the solving result, and 2) a solver
configuration object. The module smtsolver.js
has a few predefined solver
configurations, and relies on Z3, Eldarica or cvc5 being installed locally. It
exports the list of locally found solvers and a function that invokes a given
solver.
The API of the SMT callback is experimental and can change at any time. The last change was in version 0.8.11.
var solc = require('solc');
const smtchecker = require('solc/smtchecker');
const smtsolver = require('solc/smtsolver');
// Note that this example only works via node and not in the browser.
var input = {
language: 'Solidity',
sources: {
'test.sol': {
content: 'contract C { function f(uint x) public { assert(x > 0); } }'
}
},
settings: {
modelChecker: {
engine: "chc",
solvers: [ "smtlib2" ]
}
}
};
var output = JSON.parse(
solc.compile(
JSON.stringify(input),
{ smtSolver: smtchecker.smtCallback(smtsolver.smtSolver, smtsolver.availableSolvers[0]) }
)
);
The assertion is clearly false, and an assertion failure
warning
should be returned, together with a counterexample.
The low-level API is as follows:
solc.lowlevel.compileSingle
: the original entry point, supports only a single filesolc.lowlevel.compileMulti
: this supports multiple files, introduced in 0.1.6solc.lowlevel.compileCallback
: this supports callbacks, introduced in 0.2.1solc.lowlevel.compileStandard
: this works just like compile
above, but is only present in compilers after (and including) 0.4.11For examples how to use them, please refer to the README of the above mentioned solc-js releases.
Note: These low-level functions remain available for compatibility reasons.
However, they were superseded by the compile()
function and are no longer required.
Starting from version 0.5.0+commit.1d4f565a
, the functions compileSingle
, compileMulti
, and compileCallback
are always null
when using newer solc binary versions.
It is recommended to use the latest release of solc-js, but it should also handle all the older solc binaries down to 0.1.x
.
Note:
If you are using Electron, nodeIntegration
is on for BrowserWindow
by default. If it is on, Electron will provide a require
method which will not behave as expected and this may cause calls, such as require('solc')
, to fail.
To turn off nodeIntegration
, use the following:
new BrowserWindow({
webPreferences: {
nodeIntegration: false
}
});
In order to compile contracts using a specific version of Solidity, the solc.loadRemoteVersion(version, callback)
method is available. This returns a new solc
object that uses a version of the compiler specified.
You can also load the "binary" manually and use setupMethods
to create the familiar wrapper functions described above:
var solc = solc.setupMethods(require("/my/local/soljson.js"))
.
By default, the npm version is only created for releases. This prevents people from deploying contracts with non-release versions because they are less stable and harder to verify. If you would like to use the latest development snapshot (at your own risk!), you may use the following example code.
var solc = require('solc');
// getting the development snapshot
solc.loadRemoteVersion('latest', function(err, solcSnapshot) {
if (err) {
// An error was encountered, display and quit
} else {
// NOTE: Use `solcSnapshot` here with the same interface `solc` has
// For example:
const output = solcSnapshot.compile(/* ... */)
}
});
The version must be in the long format.
Thus, if you would like to use version v0.8.17
you need to include the commit hash of the release.
You can extract the long version string for each version from the publicly available release list.
solc.loadRemoteVersion('v0.8.17+commit.8df45f5f', function(err, solcSnapshot) { /* ... */ });
When using libraries, the resulting bytecode will contain placeholders for the real addresses of the referenced libraries. These have to be updated, via a process called linking, before deploying the contract.
The linker
module (require('solc/linker')
) offers helpers to accomplish this.
The linkBytecode
method provides a simple helper for linking:
var linker = require('solc/linker');
bytecode = linker.linkBytecode(bytecode, { MyLibrary: '0x123456...' });
As of Solidity 0.4.11 the compiler supports standard JSON input and output which outputs a link references map. This gives a map of library names to offsets in the bytecode to replace the addresses at. It also doesn't have the limitation on library file and contract name lengths.
There is a method available in the linker
module called findLinkReferences
which can find such link references in bytecode produced by an older compiler:
var linker = require('solc/linker');
var linkReferences = linker.findLinkReferences(bytecode);
The ABI generated by Solidity versions can differ slightly, due to new features introduced. There is a tool included which aims to translate the ABI generated by an older Solidity version to conform to the latest standard.
It can be used as:
var abi = require('solc/abi');
var inputABI = [
{
constant: false,
inputs: [],
name: 'hello',
outputs: [{ name: '', type: 'string' }],
payable: false,
type: 'function'
}
];
var outputABI = abi.update('0.3.6', inputABI);
// Output contains: [{"constant":false,"inputs":[],"name":"hello","outputs":[{"name":"","type":"string"}],"payable":true,"type":"function"},{"type":"fallback","payable":true}]
There is a helper available to format old JSON assembly output into a text familiar to earlier users of Remix IDE.
var translate = require('solc/translate')
// assemblyJSON refers to the JSON of the given assembly and sourceCode is the source of which the assembly was generated from
var output = translate.prettyPrintLegacyAssemblyJSON(assemblyJSON, sourceCode)
Compilation is generally a long-running and resource intensive task that cannot reasonably be performed in the main thread of the browser.
Some browsers even disallow synchronous compilation on the main thread if the module is larger than 4KB.
Thus, the only supported way to use solc
in a web browser is through a web worker.
Web Workers allow you to run javascript in the background in the browser, letting the browser's main thread free to do whatever it needs to do.
Please, see the minimal example of how to use solc
with web workers below or check out this repository for a full demo.
<!DOCTYPE html>
<html>
<head>
<meta charset="utf-8" />
</head>
<body>
<script>
var worker = new Worker('./dist/bundle.js');
worker.addEventListener('message', function (e) {
console.log(e.data.version)
}, false);
worker.postMessage({})
</script>
</body>
</html>
importScripts('https://binaries.soliditylang.org/bin/soljson-v0.8.19+commit.7dd6d404.js')
import wrapper from 'solc/wrapper';
self.addEventListener('message', () => {
const compiler = wrapper(self.Module)
self.postMessage({
version: compiler.version()
})
}, false)
FAQs
Solidity compiler
The npm package scol receives a total of 0 weekly downloads. As such, scol popularity was classified as not popular.
We found that scol demonstrated a healthy version release cadence and project activity because the last version was released less than a year ago. It has 0 open source maintainers collaborating on the project.
Did you know?
Socket for GitHub automatically highlights issues in each pull request and monitors the health of all your open source dependencies. Discover the contents of your packages and block harmful activity before you install or update your dependencies.
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