llvm/utils/DSAextract.py
Serge Guelton 60ccceba74 Python compat - print statement
Make sure all print statements are compatible with Python 2 and Python3 using
the `from __future__ import print_function` statement.

Differential Revision: https://reviews.llvm.org/D56249

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@350307 91177308-0d34-0410-b5e6-96231b3b80d8
2019-01-03 14:11:33 +00:00

114 lines
3.3 KiB
Python

#! /usr/bin/python
#this is a script to extract given named nodes from a dot file, with
#the associated edges. An edge is kept iff for edge x -> y
# x and y are both nodes specified to be kept.
#known issues: if a line contains '->' and is not an edge line
#problems will occur. If node labels do not begin with
#Node this also will not work. Since this is designed to work
#on DSA dot output and not general dot files this is ok.
#If you want to use this on other files rename the node labels
#to Node[.*] with a script or something. This also relies on
#the length of a node name being 13 characters (as it is in all
#DSA dot output files)
#Note that the name of the node can be any substring of the actual
#name in the dot file. Thus if you say specify COLLAPSED
#as a parameter this script will pull out all COLLAPSED
#nodes in the file
#Specifying escape characters in the name like \n also will not work,
#as Python
#will make it \\n, I'm not really sure how to fix this
#currently the script prints the names it is searching for
#to STDOUT, so you can check to see if they are what you intend
from __future__ import print_function
import re
import string
import sys
if len(sys.argv) < 3:
print('usage is ./DSAextract <dot_file_to_modify> \
<output_file> [list of nodes to extract]')
#open the input file
input = open(sys.argv[1], 'r')
#construct a set of node names
node_name_set = set()
for name in sys.argv[3:]:
node_name_set |= set([name])
#construct a list of compiled regular expressions from the
#node_name_set
regexp_list = []
for name in node_name_set:
regexp_list.append(re.compile(name))
#used to see what kind of line we are on
nodeexp = re.compile('Node')
#used to check to see if the current line is an edge line
arrowexp = re.compile('->')
node_set = set()
#read the file one line at a time
buffer = input.readline()
while buffer != '':
#filter out the unnecessary checks on all the edge lines
if not arrowexp.search(buffer):
#check to see if this is a node we are looking for
for regexp in regexp_list:
#if this name is for the current node, add the dot variable name
#for the node (it will be Node(hex number)) to our set of nodes
if regexp.search(buffer):
node_set |= set([re.split('\s+',buffer,2)[1]])
break
buffer = input.readline()
#test code
#print '\n'
print(node_name_set)
#print node_set
#open the output file
output = open(sys.argv[2], 'w')
#start the second pass over the file
input = open(sys.argv[1], 'r')
buffer = input.readline()
while buffer != '':
#there are three types of lines we are looking for
#1) node lines, 2) edge lines 3) support lines (like page size, etc)
#is this an edge line?
#note that this is no completely robust, if a none edge line
#for some reason contains -> it will be missidentified
#hand edit the file if this happens
if arrowexp.search(buffer):
#check to make sure that both nodes are in the node list
#if they are print this to output
nodes = arrowexp.split(buffer)
nodes[0] = string.strip(nodes[0])
nodes[1] = string.strip(nodes[1])
if nodes[0][:13] in node_set and \
nodes[1][:13] in node_set:
output.write(buffer)
elif nodeexp.search(buffer): #this is a node line
node = re.split('\s+', buffer,2)[1]
if node in node_set:
output.write(buffer)
else: #this is a support line
output.write(buffer)
buffer = input.readline()