iptables-parser/wrapper.py

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#!/usr/bin/env python3
#from ctypes import *
import ctypes
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import _ctypes
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from datetime import datetime
import os
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import json
import random
import plotly.graph_objects as go
import networkx as nx
import dash
import dash_cytoscape as cyto
from dash import Dash, dcc, html
from dash.dependencies import Input, Output
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import dash_bootstrap_components as dbc
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cyto.load_extra_layouts()
external_script = ["https://tailwindcss.com/", {"src": "https://cdn.tailwindcss.com"}]
class LogData(ctypes.Structure):
_fields_ = [
("tag", ctypes.c_char_p),
("iface_in", ctypes.c_char_p),
("iface_out", ctypes.c_char_p),
("mac", ctypes.c_char_p),
("dst_ip", ctypes.c_char_p),
("src_ip", ctypes.c_char_p),
("dst_port", ctypes.c_char_p),
("src_port", ctypes.c_char_p),
("proto", ctypes.c_char_p),
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("tstamp", ctypes.c_char_p),
("len", ctypes.c_char_p)
]
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def c_parser(log_line):
so_file = "lib/parser_lib.so"
iptablesParser = CDLL(so_file)
iptablesParser.iptablesParser.argtype = c_char_p
iptablesParser.iptablesParser.restype = c_char_p
iptablesParser.lineParser.argtype = c_char_p
iptablesParser.lineParser.restype = c_char_p
parser_arg = log_line.encode('utf-8')
# c_return = iptablesParser.iptablesParser(parser_arg)
c_return = iptablesParser.lineParser(parser_arg)
_ctypes.dlclose(iptablesParser._handle)
# iptablesParser.freeme(c_return)
print()
print("[ Return on Python ]"+"-"*50+"[+]")
print(c_return.decode("utf-8"))
print(c_return)
def file_pointer():
f = open("/var/log/iptables.log", "r")
i = 0
for x in f:
print()
print("*"*100)
print("SEQUENCE : ",i)
print("*"*100)
print(str(i)+" -> "+x)
c_parser(str(x))
if i >= 3:
break
i = i + 1
def struct_process():
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path = os.getcwd()
clibrary = ctypes.CDLL(os.path.join(path, 'lib/parser_lib.so'))
#param_1=("ABC", "CDE")
clibrary.main.restype = ctypes.POINTER(LogData)
call_lib = clibrary.main()
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print(call_lib.contents.src_ip.decode('utf-8'))
print(call_lib.contents.dst_ip.decode('utf-8'))
print(call_lib.contents.src_port.decode('utf-8'))
print(call_lib.contents.dst_port.decode('utf-8'))
print(call_lib.contents.proto.decode('utf-8'))
print(call_lib.contents.iface_in.decode('utf-8'))
print(call_lib.contents.iface_out.decode('utf-8'))
print(call_lib.contents.len)
def line_process():
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path = os.getcwd()
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log_file = "wg_api/iptable_parser/example/iptables.log"
p_file = open(os.path.join(path, log_file))
p_lines = p_file.readlines()
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clibrary = ctypes.CDLL(os.path.join(path, 'wg_api/iptable_parser/lib/parser_lib.so'))
clibrary.main.restype = ctypes.POINTER(LogData)
clibrary.line_parse.restype = ctypes.POINTER(LogData)
clibrary.line_parse.argtype = ctypes.c_char_p
test_val = "HERRROOOO"
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json_dump = []
nodes = []
edges = []
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with open(os.path.join(path, log_file)) as p_lines:
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for line in p_lines:
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if line.strip():
#print(line)
parser_arg = line.encode('utf-8')
call_lib = clibrary.line_parse(parser_arg)
time_hr = datetime.fromisoformat(call_lib.contents.tstamp.decode('utf-8'))
time_hr = time_hr.strftime("%d-%m-%Y %H:%M:%S (%Z)")
# print("-"*50)
# print("TSTAMP ",time_hr)
# print("TAG ",call_lib.contents.tag.decode('utf-8'))
# print("SRC ",call_lib.contents.src_ip.decode('utf-8'))
# print("DST ",call_lib.contents.dst_ip.decode('utf-8'))
# print("LEN ",call_lib.contents.len.decode('utf-8'))
# print("IFACE_IN ",call_lib.contents.iface_in.decode('utf-8'))
# print("IFACE_OUT ",call_lib.contents.iface_out.decode('utf-8'))
# print("PROTO ",call_lib.contents.proto.decode('utf-8'))
# if (call_lib.contents.proto != b"ICMP"):
# print("SPT ",call_lib.contents.src_port.decode('utf-8'))
# print("DPT ",call_lib.contents.dst_port.decode('utf-8'))
# print()
timestamp = call_lib.contents.tstamp.decode('utf-8')
tag = call_lib.contents.tag.decode('utf-8')
src_ip = call_lib.contents.src_ip.decode('utf-8')
dst_ip = call_lib.contents.dst_ip.decode('utf-8')
iface_in = call_lib.contents.iface_in.decode('utf-8')
iface_out = call_lib.contents.iface_out.decode('utf-8')
proto = call_lib.contents.proto.decode('utf-8')
if (call_lib.contents.proto != b"ICMP"):
src_port = call_lib.contents.src_port.decode('utf-8')
dst_port = call_lib.contents.dst_port.decode('utf-8')
else:
src_port = ""
dst_port = ""
tmp_data = {
"TimeStamp": timestamp,
"Tag": tag,
"SourceIP": src_ip,
"DestinationIP": dst_ip,
"InterafceIN": iface_in,
"InterafceOUT": iface_out,
"SourcePort": src_port,
"DestinationPort": dst_port,
"Protocol": proto
}
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if (tag != "VPN-REG"):
nodes.append({'id':src_ip, 'label': src_ip})
nodes.append({'id':dst_ip, 'label': dst_ip})
edges.append({'id': src_ip+"-"+dst_ip, 'source':src_ip, 'target': dst_ip, 'label': src_port+"->"+dst_port if proto != "ICMP" else "ICMP"})
json_dump.append(tmp_data)
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nodes = get_uniq(nodes)
edges = get_uniq(edges)
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#plot_group_graph(nodes, edges)
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json_data = json.dumps(json_dump, indent=2)
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return nodes, edges
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def get_uniq(list):
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id_list = []
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uniq_list = []
for x in list:
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if (x not in uniq_list) and (x['id'] not in id_list):
id_list.append(x['id'])
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uniq_list.append(x)
print("-"*50)
for x in uniq_list:
print(x)
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print("-"*50)
return uniq_list
#_ctypes.dlclose(call_lib._handle)
# clibrary.main(param_1)
# print(clibrary.main().contents.src_ip)
# print(clibrary.main().contents.dst_ip)
# file_pointer()
# struct_process()
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def plot_group_graph():
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nodes, edges = line_process()
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# Create a graph
G = nx.Graph()
G.add_nodes_from(nodes)
G.add_edges_from(edges)
# Generate random words for node hover data
random_words = [random.choice(["Apple", "Banana", "Cherry", "Date", "Fig", "Grape", "Lemon", "Mango", "Orange", "Peach"]) for _ in nodes]
# Define node colors based on conditions
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node_name = {node: "Johan:"+" "+node if node == "192.168.101.113" else node for node in nodes }
node_colors = {node: 'turqoise' if node == '192.168.20.2' else ('teal' if node.startswith('192.168') else ('orange' if node.startswith('10.30.') else 'beige')) for node in nodes}
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# Create a Dash app
#app = dash.Dash(__name__)
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#app = DjangoDash(name='dash_app', external_stylesheets=[dbc.themes.LUX])
#layout={'name': 'cose', 'avoidOverlap': True, 'nodeDimensionsIncludeLabels': True},
layout={
"name": "cose",
"idealEdgeLength": 20,
"nodeOverlap": 20,
"refresh": 30,
"fit": True,
"padding": 3,
"randomize": False,
"componentSpacing": 100,
"nodeRepulsion": 400000,
"edgeElasticity": 100,
"nestingFactor": 5,
"gravity": 80,
"numIter": 1000,
"initialTemp": 200,
"coolingFactor": 0.95,
"minTemp": 1.0,
},
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app = dash.Dash(
__name__,
external_scripts=external_script,
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external_stylesheets=[dbc.themes.FLATLY]
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)
app.scripts.config.serve_locally = True
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#positions = [ {"x":random.randint(1000,5000), "y":random.randint(1,100)} for _ in nodes ]
elements=[
{'data': {'id': node, 'label': node_name[node], 'random_word': random_word, 'color': node_colors[node]}} for node, random_word in zip(nodes, random_words)
] + [{'data': {'source': source, 'target': target, 'color':'crimson'}} for source, target in edges], # Include the edges
stylesheet=[
{
'selector': 'node',
'style': {
'background-color': 'data(color)',
"width": "mapData(weight, 40, 80, 20, 60)",
'label': 'data(label)',
'font-size': '12px',
'text-halign': 'center',
'text-valign': 'top', # Adjust the text position to 'top'
'border-width': '2px',
'border-color': 'seagreen',
'shadow-box': '2px',
'content': 'data(label)',
}
},
{
'selector': 'edge',
'style': {
'width': 2,
'background-opacity': 0.2, # Set the opacity for the parent node
'line-color': 'teal',
}
},
{
'selector': 'edge:selected',
'style': {
'border': 'crimson',
'border-opacity': 0.2,
'width': 4,
'background-opacity': 0.2, # Set the opacity for the parent node
'line-color': 'crimson',
}
},
{
'selector': ':parent',
'style': {
'background-opacity': 0.2, # Set the opacity for the parent node
}
},
{
'selector': 'node:parent',
'style': {
'border-width': 1, # Set the border width for the parent node
}
},
{
'selector': ':selected',
'style': {
'border-width': 4, # Set the border width for selected nodes
'border-color': 'crimson', # Set the border color for selected nodes
}
},
],
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# Define the app layout
app.layout = html.Div([
html.Div(children=[
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html.Div(children=[
dcc.Tabs([
dcc.Tab(label='Tab 1',children=[
html.Div(children=[
html.Div(f'Node Details: ', className='p-2'),
dcc.Slider(id='slider', min=1, max=500, step=20),
html.Button('Reset', id='bt-reset', className='btn bg-teal-500 p-2 text-white hover:bg-teal-600'),
dcc.Dropdown(['cose', 'cola', 'random', 'circle'], 'cose', id='graph-mode-dropdown'),
dcc.Input(
id="input_{}".format("text"),
type="text",
placeholder="input type {}"
),
html.Div(id='out-all-types', className=''),
], className='p-2 space-y-2'),
]),
dcc.Tab(label='Tab 2', children=[
html.Div(children=[
html.Div(f'Edge Details: '),
html.Div(id='hover-data', className=''),
], className='space-y-2 p-2'),
]),
]),
], className="w-96 flex-none"),
html.Div(children=[
dcc.Tabs([
dcc.Tab(label='OAM',children=[
html.Div(children=[
cyto.Cytoscape(
id='network-graph',
layout=layout[0],
zoomingEnabled=True,
zoom=0.9,
responsive=True,
elements=elements[0],
style={'width': '100%', 'height': '88vh', 'background':'#dfdfdf'},
stylesheet=stylesheet[0],
)
], className="bg-amber-50 p-4 flex"),
]),
dcc.Tab(label='VPN Registration',children=[
html.Div(children=[
cyto.Cytoscape(
id='network-graph',
layout=layout[0],
zoomingEnabled=True,
zoom=0.9,
responsive=True,
elements=elements[0],
style={'width': '100%', 'height': '88vh', 'background':'#efefef'},
stylesheet=stylesheet[0],
)
], className="bg-amber-50 p-4"),
]),
]),
], className="w-[calc(100%-24rem)] h-[calc(100%-16rem)]"), ],
className="flex w-full h-full"),
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])
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@app.callback(
[Output('network-graph', 'zoom'),
Output('network-graph', 'elements')],
[Input('bt-reset', 'n_clicks')]
)
def reset_layout(n_clicks):
print(n_clicks, 'click')
return [0.5, elements[0]]
@app.callback(
Output('network-graph', 'layout'),
[Input('graph-mode-dropdown', 'value')]
)
def graph_mode(value):
print(value)
tmp_layout = layout[0]
tmp_layout['name'] = value
return tmp_layout
# @app.callback(
# Output('network-graph', 'layout'),
# [Input('slider', 'value')]
# )
# def update_zoom(value):
# print(value)
# tmp_layout = layout[0]
# tmp_layout['idealEdgeLength'] = value
# return tmp_layout
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@app.callback(
Output('hover-data', 'children'),
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Input('network-graph', 'tapNodeData')
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)
def display_hover_data(data):
if data:
return html.Div([
html.Div(f'Node: {data["id"]}', style={'font-weight': 'bold', 'background':'#dfdfdf'}),
html.Div(f'Random Word: {data["random_word"]}')
])
else:
return ''
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@app.callback(
Output("out-all-types", "children"),
Input("input_{}".format('text'), "value"),
)
def cb_render(*vals):
return html.Div([
html.Div(f'Input: {vals}', style={'font-weight': 'bold', 'background':'#dfdfdf'}),
])
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if __name__ == '__main__':
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app.run_server(debug=True, use_reloader=True)
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def plot_net_graph(nodes, edges):
# Create a graph
G = nx.Graph()
G.add_nodes_from(nodes)
G.add_edges_from(edges)
# Generate random words for node hover data
random_words = [random.choice(["Apple", "Banana", "Cherry", "Date", "Fig", "Grape", "Lemon", "Mango", "Orange", "Peach"]) for _ in nodes]
# Create positions for the nodes using a circular layout
pos = nx.circular_layout(G, scale=2)
# Create a Plotly figure
fig = go.Figure()
# Add edges to the figure
for edge in edges:
x0, y0 = pos[edge[0]]
x1, y1 = pos[edge[1]]
edge_trace = go.Scatter(
x=[x0, x1, None],
y=[y0, y1, None],
mode='lines',
line=dict(width=2, color='gray'), # Set edge color to 'gray' and adjust width
hoverinfo='none', # Disable edge hover
)
fig.add_trace(edge_trace)
# Define node colors based on conditions
node_colors = []
for node in nodes:
if node == '192.168.20.2':
node_colors.append('#22C55E') # Green color
elif node.startswith('10.30.1'):
node_colors.append('seagreen') # Blue color
elif node.startswith('192.168.100') or node.startswith('192.168.101'):
node_colors.append('#3B82F6') # Blue color
else:
node_colors.append('#EF4444') # Red color
node_size = []
for node in nodes:
if node == '192.168.20.2':
node_size.append(30) # Green color
elif node.startswith('10.30.1'):
node_size.append(25) # Blue color
elif node.startswith('192.168.100') or node.startswith('192.168.101'):
node_size.append(25) # Blue color
else:
node_size.append(20) # Red color
# Add nodes to the figure with defined colors
for node, word, color, size in zip(nodes, random_words, node_colors, node_size):
x, y = pos[node]
is_192_168 = node.startswith('192.168')
node_trace = go.Scatter(
x=[x],
y=[y],
mode='markers',
marker=dict(
size=size,
color=color, # Set color based on the conditions
line=dict(
width=2,
color='black' # Set border color
)
),
text=f"Node: {node}<br>Random Word: {word}",
hoverinfo='text' # Display node and random word on hover
)
fig.add_trace(node_trace)
# Customize the layout
fig.update_layout(
showlegend=False,
title='Denser Network Graph with Larger Circled Nodes',
hovermode='closest', # Set hover mode to the nodes only
xaxis=dict(showgrid=False, zeroline=False, showticklabels=False), # Remove x-axis values
yaxis=dict(showgrid=False, zeroline=False, showticklabels=False), # Remove y-axis values
paper_bgcolor='lightgray', # Set a milder background color
)
# Set the aspect ratio to make the graph denser
fig.update_xaxes(scaleanchor="y", scaleratio=1)
# Display the plot
app = Dash()
app.layout = html.Div([
dcc.Graph(
id='my-graph',
figure=fig,
style = {'display': 'inline-block', 'height': '90vh', 'width': '100%'}
)
])
app.run_server(debug=True, use_reloader=True) # Turn off reloader if inside Jupyter
#fig.show()
def plot_graph(in_nodes, in_edges):
#G = nx.random_geometric_graph(10, 0.25)
G = nx.Graph()
G.add_nodes_from(in_nodes)
G.add_edges_from(in_edges)
print("*"*50)
print(G.edges())
print(G.nodes())
print("*"*50)
edge_x = []
edge_y = []
for edge in G.edges():
print(G.nodes[edge[0]]['pos'])
print(G.nodes[edge[1]]['pos'])
x0, y0 = G.nodes[edge[0]]['pos']
x1, y1 = G.nodes[edge[1]]['pos']
edge_x.append(x0)
edge_x.append(x1)
edge_x.append(None)
edge_y.append(y0)
edge_y.append(y1)
edge_y.append(None)
edge_trace = go.Scatter(
x=edge_x, y=edge_y,
line=dict(width=0.5, color='#888'),
hoverinfo='none',
mode='lines')
node_x = []
node_y = []
for node in G.nodes():
x, y = G.nodes[node]['pos']
node_x.append(x)
node_y.append(y)
node_trace = go.Scatter(
x=node_x, y=node_y,
mode='markers',
hoverinfo='text',
marker=dict(
showscale=True,
# colorscale options
#'Greys' | 'YlGnBu' | 'Greens' | 'YlOrRd' | 'Bluered' | 'RdBu' |
#'Reds' | 'Blues' | 'Picnic' | 'Rainbow' | 'Portland' | 'Jet' |
#'Hot' | 'Blackbody' | 'Earth' | 'Electric' | 'Viridis' |
colorscale='YlGnBu',
reversescale=True,
color=[],
size=10,
colorbar=dict(
thickness=15,
title='Node Connections',
xanchor='left',
titleside='right'
),
line_width=2))
node_adjacencies = []
node_text = []
for node, adjacencies in enumerate(G.adjacency()):
node_adjacencies.append(len(adjacencies[1]))
node_text.append('# of connections: '+str(len(adjacencies[1])))
node_trace.marker.color = node_adjacencies
node_trace.text = node_text
fig = go.Figure(data=[edge_trace, node_trace],
layout=go.Layout(
title='Network graph made with Python',
titlefont_size=16,
showlegend=False,
hovermode='closest',
margin=dict(b=20,l=5,r=5,t=40),
annotations=[ dict(
text="Python code: <a href='https://plotly.com/ipython-notebooks/network-graphs/'> https://plotly.com/ipython-notebooks/network-graphs/</a>",
showarrow=False,
xref="paper", yref="paper",
x=0.005, y=-0.002 ) ],
xaxis=dict(showgrid=False, zeroline=False, showticklabels=False),
yaxis=dict(showgrid=False, zeroline=False, showticklabels=False))
)
fig.show()
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#plot_group_graph()