Links' Seminars and Public Events |
2020 | |
---|---|
Wed 8th Jan 1:30 pm 3:30 pm | Introduction to argumentation theory Salle Agora 1, Bâtiment ESPRIT |
2019 | |
Thu 19th Dec 11:00 am 1:30 pm | Thèse L. Gallois amphi Bâtiment B Inria |
Fri 13th Dec 11:45 am 1:00 pm | 1. On Parsing Gpath (Jérémy and Antonio) 2. On Nested Regular Expression (Joachim) |
Fri 13th Dec 10:30 am 11:45 am | Repet Lily pour l'équipe "Lille-Salle B31 " |
Tue 24th Sep 10:00 am 11:00 am | Stijn Vansummeren Title: General Dynamic Yannakakis: Conjunctive Queries with Theta Joins Under Updates Abstract: The ability to efficiently analyze changing data is a key requirement of many real-time analytics applications like Stream Processing, Complex Event Recognition, Business Intelligence, and Machine Learning. Traditional approaches to this problem are based either on the materialization of subresults (to avoid their recomputation) or on the recomputation of subresults (to avoid the space overhead of materialization). Both techniques have recently been shown suboptimal: instead of fully materializing results and subresults, one can maintain a data structure that supports efficient maintenance under updates and can quickly enumerate the full query output, as well as the changes produced under single updates. In our work we are concerned with designing a practical family of algorithms for dynamic query evaluation based on this idea, and for queries featuring both equi-joins and inequality joins, as well as certain forms of aggregation. Our main insight is that, for acyclic conjunctive queries, such algorithms can naturally be obtained by modifying Yannakakis' seminal algorithm for processing acyclic joins in the static setting. In this talk I present the main ideas behind this modfication, offset it against the traditional ways of doing incremental view maintenance, and discuss recent extensions such as dealing with general theta-joins. Amphitheater of INRIA Building B. |
Tue 25th Jun 11:30 am 5:30 pm | Happy Hours Inria Lille |
Tue 25th Jun 10:30 am 11:30 am | Seminar Véronique Benzaken and Évelyne Contejean Elles présenteront un outil qui prend en entrée une requête SQL et sa compilation par Postrgres sous forme de plan d'exécution, et démontre (avec Coq) que la requête initiale est équivalente au plan d'exécution. Lille-Salle B21 |
Fri 21st Jun 11:00 am 12:00 pm | Charles |
Fri 24th May 11:00 am 12:00 pm | Seminaire Sławek |
Fri 10th May 11:00 am 12:00 pm | Seminaire Iovka |
Fri 12th Apr 11:00 am 12:30 pm | Alexandre Vigny in Links Seminar |
Fri 5th Apr 11:00 am 12:30 pm | Talk of Semyon Grigorev Title: Parsing techniques for context-free path querying Abstract: Context-free path querying (CFPQ) is a case of language constrained path querying: the way to specify constraints on paths in a graph in terms of formal languages. In CFPQ language is restricted to be a context-free. Classical parsing techniques and algorithms, such as generalized LR and LL parsing, or parser combinators, can be used for CFPQ. Results of adaptation of different parsing techniques for CFPQ will be presented. B31 |
Fri 5th Apr 11:00 am 12:00 pm | Semyon Grigorev in Links' seminar |
Fri 22nd Mar 10:00 am 11:30 am | Seminar LINKS by Aurelien Lemay "Tutorial: Grammatical Inference" |
Fri 8th Mar 11:00 am 12:00 pm | Seminar Momar Title: Regular Matching and Inclusion on Compressed Tree Patterns with Context Variables
Abstract: We study the complexity of regular matching and inclusion for compressed tree patterns extended by context variables. The addition of context variables to tree patterns permits us to properly capture compressed string patterns but also compressed patterns for unranked trees with tree and hedge variables. Regular inclusion for the latter is relevant to certain query answering on Xml streams with references. |
Fri 15th Feb 11:00 am 12:00 pm | Seminar [Florent] |
Wed 13th Feb 1:30 pm 2:30 pm | 30mn de science : Florent Capelli on Knowledge Compilation Inria salle Plénière (Bâtiment A) |
Fri 1st Feb 11:00 am 12:30 pm | Bruno Guillon in Links' seminar Title: Finding paths in large graphs Abstract: When dealing with large graphs, classical algorithms for finding paths such as Dijkstra's Algorithm are unsuitable, because they require to perform too many disk accesses. To avoid this while keeping a data structure of size quasi-linear in the size of the graph, we propose to guide the path search with a distance oracle, obtained from a topological embedding of the graph. I will present fresh experimental research on this topic, in which we obtain graph embeddings using learning algorithms from natural language processing. On some graphs, such as the graph of publications from DBLP, our topologically-guided path search allows us to visit a small portion of the graph only, in average. This is joint work with Charles Paperman. B21 Room |