1 / 23

I/O Efficient Directed Model Checking

I/O Efficient Directed Model Checking. Shahid Jabbar and Stefan Edelkamp, Computer Science Department University of Dortmund, Germany. Problem. In explicit-state model checking, most real-world models require enormous amount of memory. How to cope with this state space explosion problem ?.

torie
Télécharger la présentation

I/O Efficient Directed Model Checking

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. I/O Efficient Directed Model Checking Shahid Jabbar and Stefan Edelkamp, Computer Science Department University of Dortmund, Germany

  2. Problem • In explicit-state model checking, most real-world models require enormous amount of memory. • How to cope with this state space explosion problem ? I/O Efficient Directed MC

  3. Directed Model Checking (Edelkamp, Leue, Lluch-Lafuente, 2004) • A guided search in the state space. • Usually by some heuristic estimate. • Only promising states are explored. • Under-certain conditions proved to be complete. I/O Efficient Directed MC

  4. A Closer look at different strategies Depth first Breadth first Best first A* I/O Efficient Directed MC

  5. Advantages of Directed Model Checking • Partial exploration of the state space. • Shorter error trails • Better for human comprehension • Problem: • The inevitable demands of the model .. Space, space and space. I/O Efficient Directed MC

  6. Possible Solution • Use Virtual Memory. • Assume a bigger address space divided into pages. • Saved on the hard disk but are moved back to the main memory whenever they are “called” – Page Faults. • Pages are mapped to physical locations within the main memory and the desired content is returned from the main memory location. I/O Efficient Directed MC

  7. Problem with the Virtual Memory Virtual Address Space 0x000…000 Memory Page 0xFFF…FFF I/O Efficient Directed MC

  8. B Disk External Memory Model (Aggarwal and Vitter) If the input size is very large, running time depends on the I/Os rather than on the number of instructions. M Input of size N and N >> M I/O Efficient Directed MC

  9. External Memory Graph Algorithms • External breadth first search [Munagala and Ranade, 2001]: • Generated states flushed to the disk for every BFS level. • No hash table. • Duplicates are removed by sorting the nodes according to the indices and doing an scan and compaction phase. • Before expanding a layer t, the nodes in the layer t-1 and t-2 are subtracted from t. • O(|V| + sort(|V| + |E|)) I/Os. where sort(N) = O(N / B logM/B N / B) I/Os • [Korf, 2003] presented the breadth first search version for implicit graphs. I/O Efficient Directed MC

  10. A* Algorithm • A.k.a Goal-directed Dijkstra • A heuristic estimate is used to guide the search. • E.g. Straight line distance from the current node to the goal in case of a graph with a geometric layout. • Reweighing: w’(u,v) = w(u,v) – h(u) + h(v) • Problems: • A* needs to store all the states during exploration. • A* generates large amount of duplicates that can be removed using an internal hash table – only if it can fit in the main memory. • A* do not exhibit any locality of expansion. For large state spaces, standard virtual memory management can result in excessive page faults. I/O Efficient Directed MC

  11. Take a closer look h • Implicit, unweighted, undirected graphs • Consistent heuristic estimates. => ∆h ={-1,0,1} It’s a Bucket !! g I/O Efficient Directed MC

  12. Insert state Flush when full Buffer in internal memory File on disk Bucket • A Bucket is a set of states, residing on the disk, having the same (g, h) value, • Where, g = number of transitions needed to transform the initial state to the states of the bucket, • and h = Estimated distance of the bucket’s state to the goal • No state is inserted again in a bucket that is expanded. • If Active (being read or written), represented internally by a small buffer. I/O Efficient Directed MC

  13. External A* [Edelkamp, Jabbar, and Schroedl, 2004] • Buckets represent temporal locality – cache efficient order of expansion. • If we store the states in the same bucket together we can exploit the spatial locality. • Munagala and Ranade’s BFS and Korf’s delayed duplicate detection for implicit graphs. External A* I/O Efficient Directed MC

  14. Complexity Analysis • Internal A* => Each edge is looked at most once. • Duplicates Removal: • Sorting the green bucket having one state for every edge from the 3 black buckets. • Scanning and compaction. • O(sort(|E|)) • Subtraction: • Removing states of orange buckets (duplicates free) from the green one. • O(scan(|V|) + scan(|E|)) I/O Efficient Directed MC

  15. I/O Performance of External A* Theorem: The complexity of External A* in an implicit unweighted and undirected graph with a consistent estimate is bounded by O(sort(|E|) + scan(|V|)) I/Os. I/O Efficient Directed MC

  16. Directed Graphs in Model Checking • In undirected graphs, we are required to look at onlytwo layers for duplicate detection. • But in model checking, we are mainly concerned with directed graphs. • Result by [Zhou & Hansen, 2004] • Duplicate detection scope = Locality of the search • Locality = max{\delta(s,u)-\delta(s,v), 0} for all edges (u, v) • \delta denotes the shortest path. • In directed graphs, scope corresponds to the largest cycle in the graph. • Largest cycle ≤ Sum of the largest cycles in individual processes. I/O Efficient Directed MC

  17. From SPIN to HSF-SPIN to IO-HSF-SPIN • SPIN: A well-known model checker. • HSF-SPIN (Edelkamp, Leue, Lluch-Lafuente): Directed Model Checking Extension of SPIN. • IO-HSF-SPIN: External HSF-SPIN. • Incorporates External A* in HSF-SPIN. • Successfully implemented for deadlock detection. • Active process heuristic is used to guide the search. I/O Efficient Directed MC

  18. Experimental Results -1 • Deadlock Detection in Dining Philosophers I/O Efficient Directed MC

  19. Experimental Results -2 • Deadlock Detection in Optical Telegraph I/O Efficient Directed MC

  20. Experimental Results -3 • CORBA GIOP – 1 Server, N Clients I/O Efficient Directed MC

  21. Experimental Results -4 • CORBA GIOP – 2 Servers, N Clients I/O Efficient Directed MC

  22. Pause and Resume • What if even your harddisk becomes full ? • Solution: Since the states are stored on the disk, the algorithm can be stopped at any time and resumed from the last working diagonal. I/O Efficient Directed MC

  23. Summary • State space explosion problem can be circumvented by Directed Model Checking. • But even Directed Model Checking can fail for the state spaces that cannot fit into the main memory. • External A* helps in overcoming this problem. • Extended for directed graphs as appear in Model checking. • First external directed model checker IO-HSF-SPIN. • Problem having a state space size of 20.7 GB is successfully solved. I/O Efficient Directed MC

More Related