%0 Journal Article %1 Alimadadi:2018:FBP %A Alimadadi, Saba %A Zhong, Di %A Madsen, Magnus %A Tip, Frank %D 2018 %I ACM %J Proc. ACM Program. Lang. %K Bugs JavaScript OOPSLA Promises %N OOPSLA %P 162:1--162:26 %R 10.1145/3276532 %T Finding Broken Promises in Asynchronous JavaScript Programs %V 2 %X Recently, promises were added to ECMAScript 6, the JavaScript standard, in order to provide better support for the asynchrony that arises in user interfaces, network communication, and non-blocking I/O. Using promises, programmers can avoid common pitfalls of event-driven programming such as event races and the deeply nested counterintuitive control ow referred to as “callback hell”. Unfortunately, promises have complex semantics and the intricate control– and data- ow present in promise-based code hinders program comprehension and can easily lead to bugs. The promise graph was proposed as a graphical aid for understanding and debugging promise-based code. However, it did not cover all promise-related features in ECMAScript 6, and did not present or evaluate any technique for constructing the promise graphs. In this paper, we extend the notion of promise graphs to include all promise-related features in ECMAScript 6, including default reactions, exceptions, and the synchronization operations race and all. Furthermore, we report on the construction and evaluation of PromiseKeeper, which performs a dynamic analysis to create promise graphs and infer common promise anti-patterns. We evaluate PromiseKeeper by applying it to 12 open source promise-based Node.js applications. Our results suggest that the promise graphs constructed by PromiseKeeper can provide developers with valuable information about occurrences of common anti-patterns in their promise-based code, and that promise graphs can be constructed with acceptable run-time overhead.

@article{Alimadadi:2018:FBP, abstract = {Recently, promises were added to ECMAScript 6, the JavaScript standard, in order to provide better support for the asynchrony that arises in user interfaces, network communication, and non-blocking I/O. Using promises, programmers can avoid common pitfalls of event-driven programming such as event races and the deeply nested counterintuitive control ow referred to as “callback hell”. Unfortunately, promises have complex semantics and the intricate control– and data- ow present in promise-based code hinders program comprehension and can easily lead to bugs. The promise graph was proposed as a graphical aid for understanding and debugging promise-based code. However, it did not cover all promise-related features in ECMAScript 6, and did not present or evaluate any technique for constructing the promise graphs. In this paper, we extend the notion of promise graphs to include all promise-related features in ECMAScript 6, including default reactions, exceptions, and the synchronization operations race and all. Furthermore, we report on the construction and evaluation of PromiseKeeper, which performs a dynamic analysis to create promise graphs and infer common promise anti-patterns. We evaluate PromiseKeeper by applying it to 12 open source promise-based Node.js applications. Our results suggest that the promise graphs constructed by PromiseKeeper can provide developers with valuable information about occurrences of common anti-patterns in their promise-based code, and that promise graphs can be constructed with acceptable run-time overhead.}, acmid = {3276532}, added-at = {2019-03-31T23:29:07.000+0200}, articleno = {162}, author = {Alimadadi, Saba and Zhong, Di and Madsen, Magnus and Tip, Frank}, biburl = {https://www.bibsonomy.org/bibtex/2702e5df47ec66f5e53487801acbb2752/gron}, description = {Finding broken promises in asynchronous JavaScript programs}, doi = {10.1145/3276532}, interhash = {c9d9dea252376594eca237ef3e042f43}, intrahash = {702e5df47ec66f5e53487801acbb2752}, issn = {2475-1421}, issue_date = {November 2018}, journal = {Proc. ACM Program. Lang.}, keywords = {Bugs JavaScript OOPSLA Promises}, month = oct, number = {OOPSLA}, numpages = {26}, pages = {162:1--162:26}, publisher = {ACM}, timestamp = {2019-03-31T23:29:07.000+0200}, title = {{Finding Broken Promises in Asynchronous JavaScript Programs}}, volume = 2, year = 2018 }