標題: | 多層次超大型模組之放置與平面規劃 Multilevel Large-scale Module Placement/Floorplanning |
作者: | 李訓政 Hsun-Cheng Lee 張耀文 Yao-Wen Chang 資訊科學與工程研究所 |
關鍵字: | 平面規劃;晶片放置;群集;反群集;B*樹;MB*樹;floorplanning;placement;clustering;declustering;B*-tree;MB*-tree |
公開日期: | 2000 |
摘要: | 在這篇論文中,我們提出一個基於B*-tree表示法之多層次架構去處理大量模組的平面規劃及晶片放置,稱作MB*-tree。MB*-tree採用兩階段的技術─先群集再反群集。在群集的階段根據面積及模組的連通性利用quadratic programming (Lagrangian relaxation)反覆將硬(軟)的模組群組起來,同時利用B*-tree建立模組之間的幾何關係。而在反群集的階段,反覆地解開被群集的模組(也就是執行樹的延展),然後再調整平面規劃及放置的結果。在反群集階段,MB*-tree保留了模組之前的幾何關係,這個特性使得MB*-tree對多層次平面規劃與放置而言成為非常理想的資料結構。在實驗中,顯示MB*-tree的結果不會隨著電路複雜度大小而有所顯著變化,而其他知名研究報告─Sequence pair,O-tree及B*-tree則不然。在處理電路大小範圍為49至9800個模組、408至81600條訊號線時,MB*-tree在時間近似線性成長的情況下,獲得高品質的平面規劃,其未使用空間不大於3.72%。而Sequence pair、O-tree及B*-tree在相同的時間下卻分別只能處理196、196及1960個模組的電路,且未使用空間高達27.33%以上。 We present in this thesis a multilevel floorplanning/placement framework based on the B*-tree representation, called MB*-tree, to handle the floorplanning and packing for large-scale building modules. The MB*-tree adopts a two-stage technique, clustering followed by declustering. The clustering stage applies quadratic programming (Lagrangian relaxation) to iteratively groups a set of hard (soft) modules based on a cost metric guided by area utilization and module connectivity, and at the same time establishes the geometric relations for the newly clustered modules by constructing a corresponding B*-tree for them. The declustering stage iteratively ungroups a set of the previously clustered modules (i.e., perform tree expansion) and then refines the placement/floorplanning solution by using a simulated annealing scheme. In particular, the MB*-tree preserves the geometric relations among modules during declustering, which makes the MB*-tree an ideal data structure for the multilevel floorplanning/placement framework. Experimental results show that the MB*-tree scales very well as the circuit size increases while the famous previous works, sequence pair, O-tree, and B*-tree, do not. For circuit sizes ranging from 49 to 9,800 modules and from 408 to 81,600 nets, the MB*-tree consistently obtains high-quality floorplans with dead spaces of less than 3.72% in empirically linear runtime, while standalone sequence pair, O-tree, and B*-tree can handle only up to 196, 196, and 1,960 modules in the same amount of runtime and result in the dead spaces of as large as 27.33%. |
URI: | http://140.113.39.130/cdrfb3/record/nctu/#NT890394106 http://hdl.handle.net/11536/67014 |
Appears in Collections: | Thesis |