Optimize your Node app by simply upgrading Node.js | In In Node.js | By By Vladimir

In January, I published an article on RisingStack’s blog. This article was an introduction to Node.js performance (and in V8 JavaScript Engine in general).

Now it is time for a follow-up article regarding the sources of performance bottlenecks in Node.js.

If a method contains a non-optimizable pattern, even if it is hot and stable, the JavaScript engine will not attempt to optimize it.

The following table states for each pattern if it can be optimized for different versions of Node.js.

item v0.12.18 v4.0.0 v6.0.0 v7.0.0 v7.7.4 Rest parameters N/A no no no no access non-existent index of `arguments` no no no no no `debugger` statement no no no no no `for...in` loop whose key exists in outer scope no no no no no leaks `arguments` via a closure no no no no no object literal containing a getter no no no no no object literal containing a setter no no no no no overwrite named function argument and read `arguments` no no no no no pass `arguments` to `call()` no no no no no Unsupported phi use of arguments no no no no no Unsupported phi use of const or let variable no no no no no return `arguments` no no no no no yield no no no no no assign to `arguments` no no no no yes calls `eval()` no no no no yes `try...catch...finally` statement no no no yes yes `try...finally` statement no no no yes yes `try...catch` statement no no no yes yes function is bound using `Function.prototype.bind()` no no yes yes yes `for...in` loop using an array no yes yes yes yes `switch` statement with over 128 cases no yes yes yes yes

As you can see, some patterns are not optimization killers in all Node.js versions.

This table has been built using a very handy repository by Colin Ihrig. I forked it to add some patterns and to change the output format. Some results (for instance, the patterns optimized by TurboFan) had to be computed using directly the --trace-opt --trace-deopt flags.

In the rest of this article, we will go through the different patterns considered in this table.

Code patterns

For each pattern present in the table, we will give:

A code example

A short description of the language feature/pattern that explains (when possible) why it prevents V8 from optimizing it.

Rest parameters

View the code on Gist.

Rest parameters were introduced in the ECMAScript 2015 norm. This pattern is mainly a helper for the arguments object. It introduces a lot of polymorphism in the signature of the function.

At the moment, V8 does not optimize methods that use this feature.

access non-existent index of `arguments`

View the code on Gist.

The arguments object was introduced in the first version of ECMAScript. Using it adds polymorphism into the function’s signature.

As far as I know, only two uses of arguments are not performance killers in V8.

`debugger` statement

View the code on Gist.

The debugger statement was introduced formally in the third version of the ECMAScript norm. Using it will potentially change the execution workflow of the script.

Optimizing a function containing such statement looks extremely complex. Anyway, there should not be any debugger statement in production code.

`for…in` loop whose key exists in outer scope

View the code on Gist.

for...in loops gave a serious headache to the V8 team. Since they wrote on this topic, I think it is best to let them expose this topic: Fast For-In in V8 (on V8 Blog)

leaks `arguments` via a closure

View the code on Gist.

The arguments object was introduced in the first version of ECMAScript. Using it introduces polymorphism into the function’s signature.

The Bluebird wiki has a very nice paragraph regarding arguments leaking.

object literal containing a getter and object literal containing a setter

View the code on Gist.

View the code on Gist.

ECMAScript offers a powerful way to execute code when (read or write) access to an object’s property is made. However, it introduces a possible polymorphism in the typing of the members of an object.

overwrite named function argument and read `arguments`

View the code on Gist.

Once again, this one is about the use of arguments . V8 does not like when you mess with arguments.

pass `arguments` to `call()`

View the code on Gist.

You might want to pass the arguments of a function from a method to another. In this case, you should never use Function.prototype.call but Function.prototype.apply . Since apply accepts an Array-like object as the second argument, you can pass the arguments object directly to it: myFunction.apply(null, arguments) .

Unsupported phi use of arguments and Unsupported phi use of const or let variable

View the code on Gist.

View the code on Gist.

Those two are still a bit obscure to me. You can find some documentation on them on the v8 bailout reasons repository.

return `arguments`

View the code on Gist.

This is what is called an arguments leak. It is impossible to make safe heuristics regarding the signature of such a function. Therefore, its optimization is extremely unlikely.

Yield

View the code on Gist.

Generators have been introduced in the ECMAScript 2016 norm. Those objects have an unusual behavior for V8 since these functions can be exited and re-entered.

At the moment, V8 does not optimize generators.

assign to `arguments`

View the code on Gist.

Historically, this pattern was not optimized and, as often, this is due to the use of the arguments object.

However, it seems that latest versions of the engine optimize it.

calls `eval()`

View the code on Gist.

Historically, this pattern was not optimized. eval is a function that uses some dark magic. I basically execute in the current context any arbitrary JavaScript code passed as a string.

Despites its unstable nature, it seems that latest versions of the engine optimize it thanks to its new architecture: TurboFan.

`try…catch…finally` statement, `try…finally` statement and `try…catch` statement

View the code on Gist.

View the code on Gist.

View the code on Gist.

This is probably the coolest everyday-life enhancement in V8. It is possible thanks to TurboFan which is the new optimizing compiler.

function is bound using `Function.prototype.bind()`

View the code on Gist.

Function.prototype.bind has been introduced in the 5.1 version of ECMAScript. It is used to create a new function from another by binding a context ( this and arguments) to another function.

Benedikt Meurer has written an article on this topic; it is a short and high-quality reading.

`for…in` loop using an array

View the code on Gist.

As stated before, for...in loops have been an issue for the V8 team. Once again, I advise reading their blog post on this topic.

`switch` statement with over 128 cases

View the code on Gist.

The real code is available in another gist.

Historically, bloated switch statements were not optimized. But the V8 team removed this constraint a while ago.

Conclusion

Knowing how optimization works in the V8 JavaScript Engine allows you to benefit from the full power of this great engine. All the principles presented in that article are valid for Google Chrome Web Browser as well.

What about other JS engines?

I am currently going through the documentation of ChakraCore Node.js version. This will probably result in another article on the topic.

Regarding other engines, I will wait to see the results of the VM Working Group and I will try to cover as many Node.js versions as possible.

A few last words

Please let me know if you have any comments or remarks regarding this article. I am easily reachable on Twitter.

Also, don’t hesitate to give Sqreen a try to detect users performing attacks in your app and block targeted attacks. 🙂