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Jython is an implementation of the high-level, dynamic, object-oriented
language Python written in 100% Pure Java, and seamlessly integrated with
the Java platform. It thus allows you to run Python on any Java platform.
# Copyright 2004-2005 Elemental Security, Inc. All Rights Reserved.
# Licensed to PSF under a Contributor Agreement.
"""Convert graminit.[ch] spit out by pgen to Python code.
Pgen is the Python parser generator. It is useful to quickly create a
parser from a grammar file in Python's grammar notation. But I don't
want my parsers to be written in C (yet), so I'm translating the
parsing tables to Python data structures and writing a Python parse
engine.
Note that the token numbers are constants determined by the standard
Python tokenizer. The standard token module defines these numbers and
their names (the names are not used much). The token numbers are
hardcoded into the Python tokenizer and into pgen. A Python
implementation of the Python tokenizer is also available, in the
standard tokenize module.
On the other hand, symbol numbers (representing the grammar's
non-terminals) are assigned by pgen based on the actual grammar
input.
Note: this module is pretty much obsolete; the pgen module generates
equivalent grammar tables directly from the Grammar.txt input file
without having to invoke the Python pgen C program.
"""
# Python imports
import re
# Local imports
from pgen2 import grammar, token
class Converter(grammar.Grammar):
"""Grammar subclass that reads classic pgen output files.
The run() method reads the tables as produced by the pgen parser
generator, typically contained in two C files, graminit.h and
graminit.c. The other methods are for internal use only.
See the base class for more documentation.
"""
def run(self, graminit_h, graminit_c):
"""Load the grammar tables from the text files written by pgen."""
self.parse_graminit_h(graminit_h)
self.parse_graminit_c(graminit_c)
self.finish_off()
def parse_graminit_h(self, filename):
"""Parse the .h file written by pgen. (Internal)
This file is a sequence of #define statements defining the
nonterminals of the grammar as numbers. We build two tables
mapping the numbers to names and back.
"""
try:
f = open(filename)
except IOError, err:
print "Can't open %s: %s" % (filename, err)
return False
self.symbol2number = {}
self.number2symbol = {}
lineno = 0
for line in f:
lineno += 1
mo = re.match(r"^#define\s+(\w+)\s+(\d+)$", line)
if not mo and line.strip():
print "%s(%s): can't parse %s" % (filename, lineno,
line.strip())
else:
symbol, number = mo.groups()
number = int(number)
assert symbol not in self.symbol2number
assert number not in self.number2symbol
self.symbol2number[symbol] = number
self.number2symbol[number] = symbol
return True
def parse_graminit_c(self, filename):
"""Parse the .c file written by pgen. (Internal)
The file looks as follows. The first two lines are always this:
#include "pgenheaders.h"
#include "grammar.h"
After that come four blocks:
1) one or more state definitions
2) a table defining dfas
3) a table defining labels
4) a struct defining the grammar
A state definition has the following form:
- one or more arc arrays, each of the form:
static arc arcs__[] = {
{, },
...
};
- followed by a state array, of the form:
static state states_[] = {
{, arcs__},
...
};
"""
try:
f = open(filename)
except IOError, err:
print "Can't open %s: %s" % (filename, err)
return False
# The code below essentially uses f's iterator-ness!
lineno = 0
# Expect the two #include lines
lineno, line = lineno+1, f.next()
assert line == '#include "pgenheaders.h"\n', (lineno, line)
lineno, line = lineno+1, f.next()
assert line == '#include "grammar.h"\n', (lineno, line)
# Parse the state definitions
lineno, line = lineno+1, f.next()
allarcs = {}
states = []
while line.startswith("static arc "):
while line.startswith("static arc "):
mo = re.match(r"static arc arcs_(\d+)_(\d+)\[(\d+)\] = {$",
line)
assert mo, (lineno, line)
n, m, k = map(int, mo.groups())
arcs = []
for _ in range(k):
lineno, line = lineno+1, f.next()
mo = re.match(r"\s+{(\d+), (\d+)},$", line)
assert mo, (lineno, line)
i, j = map(int, mo.groups())
arcs.append((i, j))
lineno, line = lineno+1, f.next()
assert line == "};\n", (lineno, line)
allarcs[(n, m)] = arcs
lineno, line = lineno+1, f.next()
mo = re.match(r"static state states_(\d+)\[(\d+)\] = {$", line)
assert mo, (lineno, line)
s, t = map(int, mo.groups())
assert s == len(states), (lineno, line)
state = []
for _ in range(t):
lineno, line = lineno+1, f.next()
mo = re.match(r"\s+{(\d+), arcs_(\d+)_(\d+)},$", line)
assert mo, (lineno, line)
k, n, m = map(int, mo.groups())
arcs = allarcs[n, m]
assert k == len(arcs), (lineno, line)
state.append(arcs)
states.append(state)
lineno, line = lineno+1, f.next()
assert line == "};\n", (lineno, line)
lineno, line = lineno+1, f.next()
self.states = states
# Parse the dfas
dfas = {}
mo = re.match(r"static dfa dfas\[(\d+)\] = {$", line)
assert mo, (lineno, line)
ndfas = int(mo.group(1))
for i in range(ndfas):
lineno, line = lineno+1, f.next()
mo = re.match(r'\s+{(\d+), "(\w+)", (\d+), (\d+), states_(\d+),$',
line)
assert mo, (lineno, line)
symbol = mo.group(2)
number, x, y, z = map(int, mo.group(1, 3, 4, 5))
assert self.symbol2number[symbol] == number, (lineno, line)
assert self.number2symbol[number] == symbol, (lineno, line)
assert x == 0, (lineno, line)
state = states[z]
assert y == len(state), (lineno, line)
lineno, line = lineno+1, f.next()
mo = re.match(r'\s+("(?:\\\d\d\d)*")},$', line)
assert mo, (lineno, line)
first = {}
rawbitset = eval(mo.group(1))
for i, c in enumerate(rawbitset):
byte = ord(c)
for j in range(8):
if byte & (1<