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I am trying to solve a so-called "pebble game" problem to determine whether my large computation can fit into 4 TB of RAM. The original description of the pebble game is given in http://www.sciencedirect.com/science/article/pii/0304397582900159, but I will give it here for completeness.

Consider a computation described by a directed acyclic graph G = (V,E), together with a function f : V -> Z that gives the memory required to store each node. In my case, |V| = 210201, and a few of the nodes are fairly large (e.g., f(n) = 100 GB). Each node can be computed once its children are available. The question is: given a total memory bound of M, is it possible to order the computation to visit every node using at most M memory at any given time?

This problem is NP-complete for DAGs, so heuristic solutions are all that can be hoped for. Does anyone know of any good ones?

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When processing one node, why would you need to keep the other nodes in memory? Can you generate an internal id for every node and keep a list of those id's to figure out which nodes you haven't visited before? –  Geoffrey De Smet Jun 13 '12 at 10:07
    
Each node represents a certain computation, which can only be performed if the data for all nodes it depends on is currently in memory. I.e., instead of storing an id, some nodes require storing 100 GB from when they are computed until the last node that depends on them is computed. –  Geoffrey Irving Jun 13 '12 at 17:29
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