A graph library
Project description
graph-theory
A simple graph library...
... A bit like networkx, just without the overhead...
... similar to graph-tool, without the Python 2.7 legacy...
... with code that you can explain to your boss..."
Install:
pip install graph-theory
Import:
import Graph
g = Graph()
Modules:
| module | description |
|---|---|
from graph import Graph, Graph3D |
Elementary methods (see basic methods below) for Graph and Graph3D. |
from graph.assignment_problem import ... |
solvers for assignment problem, the Weapons-Target Assignment Problem, ... |
from graph.flow_problem import ... |
maximum flow |
from graph.hash import ... |
graph hash functions: graph hash, merkle tree, flow graph hash |
from graph.random import ... |
graph generators for random, 2D and 3D graphs. |
from graph.scheduling import sp_solver |
Scheduling problem solver. |
from graph.search import ... |
shortest path, breadth-first, depth-first |
from graph.topology import ... |
Topological comparisons and operators: make/assert subgraph, detect partitions, path comparisons, cycle detection, path verification, network range |
from graph.transform import ... |
Isomorphic transformation methods like adjacency matrix, all-pairs-shortest path, etc. |
All module functions are available from Graph, Graph2D and Graph3D (where applicable).
| methods | description |
|---|---|
a in g |
assert if g contains node a |
g.add_node(n, [obj]) |
adds a node (with a pointer to object obj if given) |
g.node(node1) |
returns object attached to node 1. |
g.del_node(node1) |
deletes node1 and all it's edges. |
g.nodes() |
returns a list of nodes |
len(g.nodes()) |
returns the number of nodes |
g.nodes(from_node=1) |
returns nodes with edges from node 1 |
g.nodes(to_node=2) |
returns nodes with edges to node 2 |
g.nodes(in_degree=2) |
returns nodes with 2 incoming edges |
g.nodes(out_degree=2) |
returns nodes with 2 outgoing edges |
g.add_edge(1,2,3) |
adds edge to g for vector (1,2) with value 3 |
g.edge(1,2) |
returns value of edge between nodes 1 and 2 |
g.edge(1,2,default=3) |
returns default=3 if edge(1,2) doesn't exist. similar to d.get(key, 3) |
g.del_edge(1,2) |
removes edge between nodes 1 and 2 |
g.edges(path=[path]) |
returns a list of edges (along a path if given). |
g.edges(from_node=1) |
returns edges outgoing from node 1 |
g.edges(to_node=2) |
returns edges incoming to node 2 |
len(g.edges()) |
returns the number of edges |
g.from_dict(d) |
updates the graph from a dictionary |
g.to_dict() |
dumps the graph as a dictionary |
g.from_list(L) |
updates the graph from a list |
g.to_list() |
dumps the graph as a list of edges |
g.shortest_path(start,end) |
finds the path with smallest edge sum |
g.breadth_first_search(start,end) |
finds the with least number of hops |
g.depth_first_search(start,end) |
finds a path between 2 nodes (start, end) using DFS and backtracking. |
g.distance_from_path(path) |
finds the distance following a given path. |
g.maximum_flow(source,sink) |
finds the maximum flow between a source and a sink |
g.solve_tsp() |
solves the traveling salesman problem for the graph |
g.is_subgraph(g2) |
determines if graph g2 is a subgraph in g. |
g.is_partite(n) |
determines if graph is n-partite |
g.has_cycles() |
determines if there are cycles in the graph |
g.same_path(p1,p2) |
compares two paths, returns True if they're the same. |
g.adjacency_matrix() |
returns the adjacency matrix for the graph. |
g.all_pairs_shortest_paths() |
finds the shortest path between all nodes. |
g.shortest_tree_all_pairs() |
finds the shortest tree for all pairs. |
g.has_path(p) |
asserts whether a path p exists in g. |
g.all_paths(start,end) |
finds all combinations of paths between 2 nodes. |
FAQ
| want to | doesn't work | do instead | but why? |
|---|---|---|---|
| have multiple edges between two nodes | Graph(from_list=[(1,2,3), (1,2,4)] |
Add dummy nodes[(1,a,3), (a,2,0), (1,b,4),(b,2,0)] |
Explicit is better than implicit. |
| multiple values on an edge | g.add_edge(1,2,{'a':3, 'b':4}) |
Have two graphsg_a.add_edge(1,2,3)g_b.add_edge(1,2,4) |
Most graph algorithms don't work with multiple values |
Specialised modules:
from graph import Graph
from graph import Graph3D
from graph.hashing import merkle_tree
from graph.assignment_problem import ap_solver
from graph.assignment_problem import wtap_solver
from graph.scheduling_problem import sp_solver
Examples contains a number of tutorial/solutions to common operations research and computer science problems, which are made simple when treated as a graph.
| module | function | description |
|---|---|---|
| assignment_problem.py | assignment_problem | solves the assignment problem |
| hashgraph.py | merkle_tree | datablocks |
| hashgraph.py | graph_hash | computes the sha256 of a graphs nodes and edges |
| hashgraph.py | flow_graph_hash | computes the sha256 of a graph with multiple sources and sinks |
| knapsack_problem.py | knapsack problem | solves the knapsack problem |
| wtap.py | weapons-target assignment problem | solves the WTAP problem. |
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
Close
Hashes for graph-theory-2020.2.3.48877.tar.gz
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 | 643b8c10716c6a6a27c2e0a5507aa45bda87a1863f4cbed7dcd7377eb1ab66c2 |
|
| MD5 | 94c476422ecd0c3a9b79df28fcac172f |
|
| BLAKE2b-256 | 85e2621f5b8937e55d828058a1a6f1bdd6e491de7263599a814865b3dd54a6cf |
