kicad/scripting/extract-docstrings.py

406 lines
13 KiB
Python
Executable File

#!/usr/bin/env python
"""Doxygen XML to SWIG docstring converter.
Converts Doxygen generated XML files into a file containing docstrings
that can be used by SWIG >1.3.23
Usage:
extract-docstrings.py input_py_wrapper.py input_xml_dir output_directory
input_py_wrapper.py is a swig generated file, with/without docstrings,
so we can get to know which classes are inspected by swig
input_xml_dir is your doxygen generated XML directory
output_directory is the directory where output will be written
"""
# This code is implemented using Mark Pilgrim's code as a guideline:
# http://www.faqs.org/docs/diveintopython/kgp_divein.html
# Based in doxy2swig.py
# Author: Prabhu Ramachandran
# License: BSD style
from xml.dom import minidom
import re
import textwrap
import sys
import types
import os.path
def my_open_read(source):
if hasattr(source, "read"):
return source
else:
return open(source)
def my_open_write(dest):
if hasattr(dest, "write"):
return dest
else:
return open(dest, 'w')
class Doxy2SWIG:
"""Converts Doxygen generated XML files into a file containing
docstrings that can be used by SWIG-1.3.x that have support for
feature("docstring"). Once the data is parsed it is stored in
self.pieces.
"""
def __init__(self, src):
"""Initialize the instance given a source object (file or
filename).
"""
f = my_open_read(src)
self.my_dir = os.path.dirname(f.name)
self.xmldoc = minidom.parse(f).documentElement
f.close()
self.pieces = []
self.pieces.append('\n// File: %s\n'%\
os.path.basename(f.name))
self.space_re = re.compile(r'\s+')
self.lead_spc = re.compile(r'^(%feature\S+\s+\S+\s*?)"\s+(\S)')
self.multi = 0
self.ignores = ('inheritancegraph', 'param', 'listofallmembers',
'innerclass', 'name', 'declname', 'incdepgraph',
'invincdepgraph', 'programlisting', 'type',
'references', 'referencedby', 'location',
'collaborationgraph', 'reimplements',
'reimplementedby', 'derivedcompoundref',
'basecompoundref')
#self.generics = []
def generate(self):
"""Parses the file set in the initialization. The resulting
data is stored in `self.pieces`.
"""
self.parse(self.xmldoc)
def parse(self, node):
"""Parse a given node. This function in turn calls the
`parse_<nodeType>` functions which handle the respective
nodes.
"""
pm = getattr(self, "parse_%s"%node.__class__.__name__)
pm(node)
def parse_Document(self, node):
self.parse(node.documentElement)
def parse_Text(self, node):
txt = node.data
txt = txt.replace('\\', r'\\\\')
txt = txt.replace('"', r'\"')
# ignore pure whitespace
m = self.space_re.match(txt)
if m and len(m.group()) == len(txt):
pass
else:
self.add_text(textwrap.fill(txt))
def parse_Element(self, node):
"""Parse an `ELEMENT_NODE`. This calls specific
`do_<tagName>` handers for different elements. If no handler
is available the `generic_parse` method is called. All
tagNames specified in `self.ignores` are simply ignored.
"""
name = node.tagName
ignores = self.ignores
if name in ignores:
return
attr = "do_%s" % name
if hasattr(self, attr):
handlerMethod = getattr(self, attr)
handlerMethod(node)
else:
self.generic_parse(node)
#if name not in self.generics: self.generics.append(name)
def add_text(self, value):
"""Adds text corresponding to `value` into `self.pieces`."""
if type(value) in (types.ListType, types.TupleType):
self.pieces.extend(value)
else:
self.pieces.append(value)
def get_specific_nodes(self, node, names):
"""Given a node and a sequence of strings in `names`, return a
dictionary containing the names as keys and child
`ELEMENT_NODEs`, that have a `tagName` equal to the name.
"""
nodes = [(x.tagName, x) for x in node.childNodes \
if x.nodeType == x.ELEMENT_NODE and \
x.tagName in names]
return dict(nodes)
def generic_parse(self, node, pad=0):
"""A Generic parser for arbitrary tags in a node.
Parameters:
- node: A node in the DOM.
- pad: `int` (default: 0)
If 0 the node data is not padded with newlines. If 1 it
appends a newline after parsing the childNodes. If 2 it
pads before and after the nodes are processed. Defaults to
0.
"""
npiece = 0
if pad:
npiece = len(self.pieces)
if pad == 2:
self.add_text('\n')
for n in node.childNodes:
self.parse(n)
if pad:
if len(self.pieces) > npiece:
self.add_text('\n')
def space_parse(self, node):
self.add_text(' ')
self.generic_parse(node)
do_ref = space_parse
do_emphasis = space_parse
do_bold = space_parse
do_computeroutput = space_parse
do_formula = space_parse
def do_compoundname(self, node):
self.add_text('\n\n')
data = node.firstChild.data
self.add_text('%%feature("docstring") %s "\n'%data)
def do_compounddef(self, node):
kind = node.attributes['kind'].value
if kind in ('class', 'struct'):
prot = node.attributes['prot'].value
if prot <> 'public':
return
names = ('compoundname', 'briefdescription',
'detaileddescription', 'includes')
first = self.get_specific_nodes(node, names)
for n in names:
if first.has_key(n):
self.parse(first[n])
self.add_text(['";','\n'])
for n in node.childNodes:
if n not in first.values():
self.parse(n)
elif kind in ('file', 'namespace'):
nodes = node.getElementsByTagName('sectiondef')
for n in nodes:
self.parse(n)
def do_includes(self, node):
self.add_text('C++ includes: ')
self.generic_parse(node, pad=1)
def do_parameterlist(self, node):
self.add_text(['\n', '\n', 'Parameters:', '\n'])
self.generic_parse(node, pad=1)
def do_para(self, node):
self.add_text('\n')
self.generic_parse(node, pad=1)
def do_parametername(self, node):
self.add_text('\n')
try:
self.add_text("%s: "%node.firstChild.data)
except AttributeError:
self.add_text("???: ")
def do_parameterdefinition(self, node):
self.generic_parse(node, pad=1)
def do_detaileddescription(self, node):
self.generic_parse(node, pad=1)
def do_briefdescription(self, node):
self.generic_parse(node, pad=1)
def do_memberdef(self, node):
prot = node.attributes['prot'].value
id = node.attributes['id'].value
kind = node.attributes['kind'].value
tmp = node.parentNode.parentNode.parentNode
compdef = tmp.getElementsByTagName('compounddef')[0]
cdef_kind = compdef.attributes['kind'].value
if prot == 'public':
first = self.get_specific_nodes(node, ('definition', 'name'))
name = first['name'].firstChild.data
if name[:8] == 'operator': # Don't handle operators yet.
return
defn = first['definition'].firstChild.data
self.add_text('\n')
self.add_text('%feature("docstring") ')
anc = node.parentNode.parentNode
if cdef_kind in ('file', 'namespace'):
ns_node = anc.getElementsByTagName('innernamespace')
if not ns_node and cdef_kind == 'namespace':
ns_node = anc.getElementsByTagName('compoundname')
if ns_node:
ns = ns_node[0].firstChild.data
self.add_text(' %s::%s "\n%s'%(ns, name, defn))
else:
self.add_text(' %s "\n%s'%(name, defn))
elif cdef_kind in ('class', 'struct'):
# Get the full function name.
anc_node = anc.getElementsByTagName('compoundname')
cname = anc_node[0].firstChild.data
self.add_text(' %s::%s "\n%s'%(cname, name, defn))
for n in node.childNodes:
if n not in first.values():
self.parse(n)
self.add_text(['";', '\n'])
def do_definition(self, node):
data = node.firstChild.data
self.add_text('%s "\n%s'%(data, data))
def do_sectiondef(self, node):
kind = node.attributes['kind'].value
if kind in ('public-func', 'func'):
self.generic_parse(node)
def do_simplesect(self, node):
kind = node.attributes['kind'].value
if kind in ('date', 'rcs', 'version'):
pass
elif kind == 'warning':
self.add_text(['\n', 'WARNING: '])
self.generic_parse(node)
elif kind == 'see':
self.add_text('\n')
self.add_text('See: ')
self.generic_parse(node)
else:
self.generic_parse(node)
def do_argsstring(self, node):
self.generic_parse(node, pad=1)
def do_member(self, node):
kind = node.attributes['kind'].value
refid = node.attributes['refid'].value
if kind == 'function' and refid[:9] == 'namespace':
self.generic_parse(node)
def do_doxygenindex(self, node):
self.multi = 1
comps = node.getElementsByTagName('compound')
for c in comps:
refid = c.attributes['refid'].value
fname = refid + '.xml'
if not os.path.exists(fname):
fname = os.path.join(self.my_dir, fname)
print "parsing file: %s"%fname
p = Doxy2SWIG(fname)
p.generate()
self.pieces.extend(self.clean_pieces(p.pieces))
def write(self, fname):
o = my_open_write(fname)
if self.multi:
o.write("".join(self.pieces))
else:
o.write("".join(self.clean_pieces(self.pieces)))
o.close()
def clean_pieces(self, pieces):
"""Cleans the list of strings given as `pieces`. It replaces
multiple newlines by a maximum of 2 and returns a new list.
It also wraps the paragraphs nicely.
"""
ret = []
count = 0
for i in pieces:
if i == '\n':
count = count + 1
else:
if i == '";':
if count:
ret.append('\n')
elif count > 2:
ret.append('\n\n')
elif count:
ret.append('\n'*count)
count = 0
ret.append(i)
_data = "".join(ret)
ret = []
for i in _data.split('\n\n'):
if i == 'Parameters:':
ret.extend(['Parameters:\n-----------', '\n\n'])
elif i.find('// File:') > -1: # leave comments alone.
ret.extend([i, '\n'])
else:
_tmp = textwrap.fill(i.strip())
_tmp = self.lead_spc.sub(r'\1"\2', _tmp)
ret.extend([_tmp, '\n\n'])
return ret
def get_python_classes(input_py):
with open(input_py) as f:
data = f.read()
classes_supers = re.findall(r'class[ ]+([\w_]+)(\([\w_, ]+\))?:',data)
classes = (classname for classname,superclass in classes_supers)
return classes
return []
def main(input_py, input_xml, output_dir):
classes = get_python_classes(input_py)
with file("%s/docstrings.i"%output_dir,'w') as f_index:
for classname in classes:
class_file = "%s/class%s.xml"%(input_xml,classname.replace("_","__"))
swig_file = "%s/%s.i"%(output_dir,classname.lower())
if os.path.isfile(class_file):
print "processing:",class_file," ->",swig_file
p = Doxy2SWIG(class_file)
p.generate()
p.write(swig_file)
f_index.write('%%include "%s.i"\n'% classname.lower())
#else:
# print "ignoring class %s, as %s does not exist" %(classname,class_file)
if __name__ == '__main__':
print sys.argv
if len(sys.argv) != 4:
print __doc__
sys.exit(1)
main(sys.argv[1], sys.argv[2],sys.argv[3])