Graph-structured stack: Difference between revisions
New images - stack grows with intuition to right; +root node |
c++ code for add and remove nodes |
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===Operations=== |
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<source lang="cpp"> |
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GSSnode* GSS::add(GSSnode* prev, int elem) |
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{ |
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int prevlevel = prev->level; |
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assert(levels.size()>= prevlevel+1); |
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int level = prevlevel + 1; |
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if (levels.size() == level) |
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{ |
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levels.resize(level + 1); |
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} |
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GSSnode* node = findElemAtLevel(level, elem); |
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if (node == nullptr) |
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{ |
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node = new GSSnode(); |
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root->elem = elem; |
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root->level = level; |
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levels[level].push_back(root); |
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} |
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node->add(prev); |
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return node; |
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} |
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</source> |
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<source lang="cpp"> |
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void GSS::remove(GSSnode* node) |
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{ |
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if (levels.size() > node->level + 1) |
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if (findPrevAtLevel(node->level + 1, node)) throw Exception("can remove only from top"); |
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for (int i = 0; i < levels[node->level].size(); i++) |
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if (levels[node->level][i] == node) |
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{ |
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levels[node->level].erase(levels[node->level].begin() + i); |
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break; |
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} |
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delete node; |
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} |
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</source> |
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== References == |
== References == |
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Revision as of 21:44, 12 March 2017
In computer science, a graph-structured stack is a directed acyclic graph where each directed path represents a stack. The graph-structured stack is an essential part of Tomita's algorithm, where it replaces the usual stack of a pushdown automaton. This allows the algorithm to encode the nondeterministic choices in parsing an ambiguous grammar, sometimes with greater efficiency.
In the following diagram, there are four stacks: {7,3,1,0}, {7,4,1,0}, {7,5,2,0}, and {8,6,2,0}.
Another way to simulate nondeterminism would be to duplicate the stack as needed. The duplication would be less efficient since vertices would not be shared. For this example, 16 vertices would be needed instead of 9.
Operations
GSSnode* GSS::add(GSSnode* prev, int elem)
{
int prevlevel = prev->level;
assert(levels.size()>= prevlevel+1);
int level = prevlevel + 1;
if (levels.size() == level)
{
levels.resize(level + 1);
}
GSSnode* node = findElemAtLevel(level, elem);
if (node == nullptr)
{
node = new GSSnode();
root->elem = elem;
root->level = level;
levels[level].push_back(root);
}
node->add(prev);
return node;
}
void GSS::remove(GSSnode* node)
{
if (levels.size() > node->level + 1)
if (findPrevAtLevel(node->level + 1, node)) throw Exception("can remove only from top");
for (int i = 0; i < levels[node->level].size(); i++)
if (levels[node->level][i] == node)
{
levels[node->level].erase(levels[node->level].begin() + i);
break;
}
delete node;
}
References
- Masaru Tomita. Graph-Structured Stack And Natural Language Parsing. Annual Meeting of the Association of Computational Linguistics, 1988. [1]
- Elizabeth Scott, Adrian Johnstone GLL Parsing [2]
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