Improving Performance of QUIC in WiFi

Manzoor, Jawad; Cerdà-Alabern, Llorenç; Sadre, Ramin; Drago, Idílio

doi:10.1109/wcnc.2019.8886329

Cited by 5 publications

(5 citation statements)

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“…We reveal the factors that impact the performance of QUIC in WiFi and implement possible solutions as a proof-of-concept, showing that they significantly improve QUIC performance. We notice that the throughput of the raspberries presented in this paper are significantly higher than those shown in our previous work [9]. This is because some important links of the mesh were improved before the data gathering campaign used in this paper.…”

Section: Introductionmentioning

confidence: 56%

“…The results show that QUIC exhibits significantly lower performance than TCP in the WMN. In our prior work we identified how packet pacing in QUIC affects the frame aggregation at MAC layer [9]. In this paper we extend our prior work and perform in-depth analysis of congestion control and loss detection algorithms of QUIC protocol to find out the root causes of its performance degradation in WiFi networks.…”

Section: Introductionmentioning

confidence: 90%

“…Optimizing the protocols for wireless links can thus result in significant improvements in the application-layer performance. Our preliminary work in this direction is presented in [9]. In this paper we build upon our prior work and perform detailed analysis of congestion control and loss detection algorithms of QUIC protocol.…”

Section: State-of-the-art In Quic Performance Evaluationmentioning

confidence: 99%

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On the Performance of QUIC over Wireless Mesh Networks

et al. 2020

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The exponential growth in adoption of mobile phones and the widespread availability of wireless networks has caused a paradigm shift in the way we access the Internet. It has not only eased access to the Internet, but also increased users' appetite for responsive services. New protocols to speed up Internet applications have naturally emerged. The QUIC transport protocol is one prominent case. Initially developed by Google as an experiment, the protocol has already made phenomenal strides, thanks to its support in Google's servers and Chrome browser. Since QUIC is still a relatively new protocol, there is a lack of sufficient understanding about its behavior in real network scenarios, particularly in the case of wireless networks. In this paper we present a comprehensive study on the performance of QUIC in Wireless Mesh Networks (WMN). We perform a large scale measurement campaign on a production WMN to compare the performance of QUIC against TCP when retrieving files from the Internet. Our results show that while QUIC outperforms TCP in wired networks, it exhibits significantly lower performance than TCP in the WMN. We investigate the reasons for this behavior and identify the root causes of the performance issues. We find that some design choices of QUIC may penalize the protocol in WiFi, e.g., uncovering sub-optimal interactions of QUIC with MAC layer features, such as frame aggregation. Finally, we implement and evaluate our solution and demonstrate up to 28% increase in throughput of QUIC.

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Section: Introductionmentioning

confidence: 56%

Section: Introductionmentioning

confidence: 90%

Section: State-of-the-art In Quic Performance Evaluationmentioning

confidence: 99%

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On the Performance of QUIC over Wireless Mesh Networks

et al. 2020

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“…Biswal et al [391] found that QUIC performs better under poor network conditions such as low bandwidth, high latency, and high loss. Manzoor et al [392] showed that QUIC achieves sub-optimal throughput in WiFi networks. They tuned QUIC to produce bursty traffic called Bursty QUIC (BQUIC) .…”

Section: B Quicmentioning

confidence: 99%

Latency and Throughput Optimization in Modern Networks: A Comprehensive Survey

Mirzaeinnia¹,

Mirzaeinia²,

Rezgui³

2020

Preprint

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“…To automate the page loading we create a script that uses Chrome-HAR-capturer 4 to connect to the browser via its remote debugging API and load each page multiple times with cold cache. When the experiment ends, an HTTP Archive (HAR) file is created, containing detailed performance data.…”

Section: Measuring Page Load Timementioning

confidence: 99%

Dissecting HTTP/2 and QUIC : measurement, evaluation and optimization

Manzoor

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The Internet is evolving from the perspective of both usage and connectivity. The meteoric rise of smartphones has not only facilitated connectivity for the masses, it has also increased their appetite for more responsive applications. The widespread availability of wireless networks has caused a paradigm shift in the way we access the Internet. This shift has resulted in a new trend where traditional applications are getting migrated to the cloud, e.g., Microsoft Office 365, Google Apps etc. As a result, modern web content has become extremely complex and requires efficient web delivery protocols to maintain users’ experience regardless of the technology they use to connect to the Internet and despite variations in the quality of users’ Internet connectivity. To achieve this goal, efforts have been put into optimizing existing web and transport protocols, designing new low latency transport protocols and introducing enhance- ments in the WiFi MAC layer. In recent years, several improvements have been introduced in the HTTP protocol resulting in the HTTP/2 standard which allows more efficient use of network resources and a reduced perception of latency. QUIC transport protocol is another example of these ambitious efforts. Initially developed by Google as an experiment, the protocol has already made phenomenal strides, thanks to its support in Google’s servers and Chrome browser. However there is a lack of sufficient understanding and evaluation of these new protocols across a range of environments, which opens new opportunities for research in this direction. This thesis provides a comprehensive study on the behavior, usage and performance of HTTP/2 and QUIC, and advances them by implementing several optimizations. First, in order to understand the behavior of HTTP/1 and HTTP/2 traffic we analyze datasets of passive measurements collected in various operational networks and discover that they have very different characteristics. This calls for a reappraisal of traffic models, as well as HTTP traffic simulation and benchmarking approaches that were built on the understanding of HTTP/1 traffic only and may no longer be valid for modern web traffic. We develop a machine learning-based method compatible with existing flow monitoring systems for the classification of encrypted web traffic into appropriate HTTP versions. This will enable network administrators to identify HTTP/1 and HTTP/2 flows for network managements tasks such as traffic shaping or prioritization. We also investigate the behavior of HTTP/2 stream multiplexing in the wild. We devise a methodology for analysis of large datasets of network traffic comprising over 200 million flows to quantify the usage of H2 multiplexing in the wild and to understand its implications for network infrastructure. Next, we show with the help of emulations that HTTP/2 exhibits poor performance in adverse scenarios such as under high packet losses or network congestion. We confirm that the use of a single connection sometimes impairs application performance of HTTP/2 and implement an optimization in Chromium browser to make it more robust in such scenarios. Finally, we collect and analyze QUIC and TCP traffic in a production wireless mesh network. Our results show that while QUIC outperforms TCP in fixed networks, it exhibits significantly lower performance than TCP when there are wireless links in the end-to-end path. To see why this is the case, we carefully examine how delay variations which are common in wireless networks impact the congestion control and loss detection algorithms of QUIC. We also explore the interaction of QUIC transport with the advanced link layer features of WiFi such as frame aggregation. We fine-tune QUIC based on our findings and show notable increase in performance. Internet está evolucionando desde la perspectiva del uso y la conectividad. El ascenso meteórico de los teléfonos inteligentes no solo ha facilitado la conectividad para las masas, sino que también ha aumentado su apetito por aplicaciones más exigentes. La disponibilidad generalizada de las redes inalámbricas ha provocado un cambio de paradigma en la forma en que accedemos a Internet. Este cambio ha dado lugar a una nueva tendencia en la que las aplicaciones tradicionales se están migrando a la nube. Como resultado, el contenido web moderno se ha vuelto extremadamente complejo y requiere protocolos de entrega web eficientes para mantener la calidad de experiencia de los usuarios. Para lograr este objetivo, se han realizado esfuerzos para optimizar los protocolos web y de transporte existentes, diseñar nuevos protocolos de transporte de baja latencia e introducir mejo-ras en la capa MAC de WiFi. En los últimos años, se han introducido varias mejoras en el proto-colo HTTP que dan como resultado el estándar HTTP/2 que permite un uso más eficiente de los recursos de la red y una menor percepción de la latencia. El protocolo de transporte QUIC es otro ejemplo de estos esfuerzos ambiciosos. Inicialmente desarrollado por Google como un experi-mento, el protocolo ya ha hecho grandes avances, gracias a su soporte en los servidores de Google y el navegador Chrome. Esta tesis proporciona un estudio exhaustivo sobre el comportamiento, uso y rendimiento de HTTP/2 y QUIC, y los mejora mediante la implementación de varias optimizaciones. Primero, para comprender el comportamiento del tráfico HTTP/1 y HTTP/2, analizamos los conjuntos de datos de mediciones pasivas recopiladas en varias redes operativas y descubrimos que tienen carac-terísticas muy diferentes. Esto requiere una reevaluación de los modelos de tráfico, así como los métodos de simulación y evaluación comparativa del tráfico HTTP que se desarrollaron en el es-tudio hecho anteriormente sólo considerando el tráfico HTTP/1, y que ya no sean válidos para el tráfico web moderno. Desarrollamos un método basado en aprendizaje automático compatible con los sistemas de monitoreo de flujo existentes para la clasificación del tráfico web encriptado en las versiones HTTP. Esto permitirá a los administradores de red identificar los flujos de HTTP/1 y HTTP/2 para las tareas de administración de red, como la configuración del tráfico o la prior-ización. También investigamos el comportamiento de la multiplexación de flujos HTTP/2. Dise-ñamos una metodología para el análisis de grandes conjuntos de datos de tráfico de red que comprende más de 200 millones de flujos para cuantificar el uso de la multiplexación HTTP/2 y para comprender sus implicaciones para la infraestructura de red. A continuación, mostramos con la ayuda de las emulaciones que HTTP/2 muestra un rendimiento deficiente en escenarios adversos, como por ejemplo, una gran pérdida de paquetes o la conges-tión de la red. Confirmamos que el uso de una sola conexión a veces perjudica el rendimiento de la aplicación de HTTP/2 e implementamos una optimización en el navegador Chromium para ha-cerlo más robusto en tales escenarios. Finalmente, recopilamos y analizamos el tráfico de QUIC y TCP en una red de malla inalámbrica en producción. Nuestros resultados muestran que, si bien QUIC supera a TCP en redes fijas, puede presentar un rendimiento significativamente menor que TCP cuando hay enlaces inalám-bricos en la ruta de extremo a extremo. Para ver por qué ocurre, examinamos cuidadosamente cómo las variaciones de retardo, que son comunes en las redes inalámbricas, afectan el control de congestión y los algoritmos de detección de pérdida de QUIC. También exploramos la interacción de QUIC con las características avanzadas de la capa de enlace de WiFi, como la agregación de tramas. Ajustando QUIC en función de nuestros hallazgos mostramos que puede conseguirse un notable aumento en el rendimiento

show abstract

Improving Performance of QUIC in WiFi

Cited by 5 publications

References 16 publications

On the Performance of QUIC over Wireless Mesh Networks

On the Performance of QUIC over Wireless Mesh Networks

Latency and Throughput Optimization in Modern Networks: A Comprehensive Survey

Dissecting HTTP/2 and QUIC : measurement, evaluation and optimization

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