#!/usr/bin/env python
# -*- coding: utf-8 -*-
#This file is part of PLCOpenEditor, a library implementing an IEC 61131-3 editor
#based on the plcopen standard.
#
#Copyright (C) 2007: Edouard TISSERANT and Laurent BESSARD
#
#See COPYING file for copyrights details.
#
#This library is free software; you can redistribute it and/or
#modify it under the terms of the GNU General Public
#License as published by the Free Software Foundation; either
#version 2.1 of the License, or (at your option) any later version.
#
#This library is distributed in the hope that it will be useful,
#but WITHOUT ANY WARRANTY; without even the implied warranty of
#MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
#General Public License for more details.
#
#You should have received a copy of the GNU General Public
#License along with this library; if not, write to the Free Software
#Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
import os, sys
import re
import datetime
from types import *
from xml.dom import minidom
from xml.sax.saxutils import escape, unescape, quoteattr
from new import classobj
def CreateNode(name):
node = minidom.Node()
node.nodeName = name
node._attrs = {}
node.childNodes = []
return node
def NodeRenameAttr(node, old_name, new_name):
node._attrs[new_name] = node._attrs.pop(old_name)
def NodeSetAttr(node, name, value):
attr = minidom.Attr(name)
text = minidom.Text()
text.data = value
attr.childNodes[0] = text
node._attrs[name] = attr
"""
Regular expression models for checking all kind of string values defined in XML
standard
"""
Name_model = re.compile('([a-zA-Z_\:][\w\.\-\:]*)$')
Names_model = re.compile('([a-zA-Z_\:][\w\.\-\:]*(?: [a-zA-Z_\:][\w\.\-\:]*)*)$')
NMToken_model = re.compile('([\w\.\-\:]*)$')
NMTokens_model = re.compile('([\w\.\-\:]*(?: [\w\.\-\:]*)*)$')
QName_model = re.compile('((?:[a-zA-Z_][\w]*:)?[a-zA-Z_][\w]*)$')
QNames_model = re.compile('((?:[a-zA-Z_][\w]*:)?[a-zA-Z_][\w]*(?: (?:[a-zA-Z_][\w]*:)?[a-zA-Z_][\w]*)*)$')
NCName_model = re.compile('([a-zA-Z_][\w]*)$')
URI_model = re.compile('((?:http://|/)?(?:[\w.-]*/?)*)$')
LANGUAGE_model = re.compile('([a-zA-Z]{1,8}(?:-[a-zA-Z0-9]{1,8})*)$')
ONLY_ANNOTATION = re.compile("((?:annotation )?)")
"""
Regular expression models for extracting dates and times from a string
"""
time_model = re.compile('([0-9]{2}):([0-9]{2}):([0-9]{2}(?:\.[0-9]*)?)(?:Z)?$')
date_model = re.compile('([0-9]{4})-([0-9]{2})-([0-9]{2})((?:[\-\+][0-9]{2}:[0-9]{2})|Z)?$')
datetime_model = re.compile('([0-9]{4})-([0-9]{2})-([0-9]{2})[ T]([0-9]{2}):([0-9]{2}):([0-9]{2}(?:\.[0-9]*)?)((?:[\-\+][0-9]{2}:[0-9]{2})|Z)?$')
class xml_timezone(datetime.tzinfo):
def SetOffset(self, offset):
if offset == "Z":
self.__offset = timedelta(minutes = 0)
self.__name = "UTC"
else:
sign = {"-" : -1, "+" : 1}[offset[0]]
hours, minutes = [int(val) for val in offset[1:].split(":")]
self.__offset = timedelta(minutes=sign * (hours * 60 + minutes))
self.__name = ""
def utcoffset(self, dt):
return self.__offset
def tzname(self, dt):
return self.__name
def dst(self, dt):
return ZERO
[SYNTAXELEMENT, SYNTAXATTRIBUTE, SIMPLETYPE, COMPLEXTYPE, COMPILEDCOMPLEXTYPE,
ATTRIBUTESGROUP, ELEMENTSGROUP, ATTRIBUTE, ELEMENT, CHOICE, ANY, TAG, CONSTRAINT,
] = range(13)
def NotSupportedYet(type):
"""
Function that generates a function that point out to user that datatype
used is not supported by xmlclass yet
@param type: data type
@return: function generated
"""
def GetUnknownValue(attr):
raise ValueError("\"%s\" type isn't supported by \"xmlclass\" yet!" % \
type)
return GetUnknownValue
"""
This function calculates the number of whitespace for indentation
"""
def getIndent(indent, balise):
first = indent * 2
second = first + len(balise) + 1
return u'\t'.expandtabs(first), u'\t'.expandtabs(second)
def GetAttributeValue(attr, extract=True):
"""
Function that extracts data from a tree node
@param attr: tree node containing data to extract
@param extract: attr is a tree node or not
@return: data extracted as string
"""
if not extract:
return attr
if len(attr.childNodes) == 1:
return unescape(attr.childNodes[0].data.encode("utf-8"))
else:
# content is a CDATA
text = ""
for node in attr.childNodes:
if not (node.nodeName == "#text" and node.data.strip() == ""):
text += unescape(node.data.encode("utf-8"))
return text
def GetNormalizedString(attr, extract=True):
"""
Function that normalizes a string according to XML 1.0. Replace
tabulations, line feed and carriage return by white space
@param attr: tree node containing data to extract or data to normalize
@param extract: attr is a tree node or not
@return: data normalized as string
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
return value.replace("\t", " ").replace("\r", " ").replace("\n", " ")
def GetToken(attr, extract=True):
"""
Function that tokenizes a string according to XML 1.0. Remove any leading
and trailing white space and replace internal sequence of two or more
spaces by only one white space
@param attr: tree node containing data to extract or data to tokenize
@param extract: attr is a tree node or not
@return: data tokenized as string
"""
return " ".join([part for part in
GetNormalizedString(attr, extract).split(" ")
if part])
def GetHexInteger(attr, extract=True):
"""
Function that extracts an hexadecimal integer from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as an integer
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if len(value) % 2 != 0:
raise ValueError("\"%s\" isn't a valid hexadecimal integer!" % value)
try:
return int(value, 16)
except:
raise ValueError("\"%s\" isn't a valid hexadecimal integer!" % value)
def GenerateIntegerExtraction(minInclusive=None, maxInclusive=None,
minExclusive=None, maxExclusive=None):
"""
Function that generates an extraction function for integer defining min and
max of integer value
@param minInclusive: inclusive minimum
@param maxInclusive: inclusive maximum
@param minExclusive: exclusive minimum
@param maxExclusive: exclusive maximum
@return: function generated
"""
def GetInteger(attr, extract=True):
"""
Function that extracts an integer from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as an integer
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
try:
# TODO: permit to write value like 1E2
value = int(value)
except:
raise ValueError("\"%s\" isn't a valid integer!" % value)
if minInclusive is not None and value < minInclusive:
raise ValueError("\"%d\" isn't greater or equal to %d!" % \
(value, minInclusive))
if maxInclusive is not None and value > maxInclusive:
raise ValueError("\"%d\" isn't lesser or equal to %d!" % \
(value, maxInclusive))
if minExclusive is not None and value <= minExclusive:
raise ValueError("\"%d\" isn't greater than %d!" % \
(value, minExclusive))
if maxExclusive is not None and value >= maxExclusive:
raise ValueError("\"%d\" isn't lesser than %d!" % \
(value, maxExclusive))
return value
return GetInteger
def GenerateFloatExtraction(type, extra_values=[]):
"""
Function that generates an extraction function for float
@param type: name of the type of float
@return: function generated
"""
def GetFloat(attr, extract = True):
"""
Function that extracts a float from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a float
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value in extra_values:
return value
try:
return float(value)
except:
raise ValueError("\"%s\" isn't a valid %s!" % (value, type))
return GetFloat
def GetBoolean(attr, extract=True):
"""
Function that extracts a boolean from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a boolean
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value == "true" or value == "1":
return True
elif value == "false" or value == "0":
return False
else:
raise ValueError("\"%s\" isn't a valid boolean!" % value)
def GetTime(attr, extract=True):
"""
Function that extracts a time from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a time
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
result = time_model.match(value)
if result:
values = result.groups()
time_values = [int(v) for v in values[:2]]
seconds = float(values[2])
time_values.extend([int(seconds), int((seconds % 1) * 1000000)])
return datetime.time(*time_values)
else:
raise ValueError("\"%s\" isn't a valid time!" % value)
def GetDate(attr, extract=True):
"""
Function that extracts a date from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a date
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
result = date_model.match(value)
if result:
values = result.groups()
date_values = [int(v) for v in values[:3]]
if values[3] is not None:
tz = xml_timezone()
tz.SetOffset(values[3])
date_values.append(tz)
return datetime.date(*date_values)
else:
raise ValueError("\"%s\" isn't a valid date!" % value)
def GetDateTime(attr, extract=True):
"""
Function that extracts date and time from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as date and time
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
result = datetime_model.match(value)
if result:
values = result.groups()
datetime_values = [int(v) for v in values[:5]]
seconds = float(values[5])
datetime_values.extend([int(seconds), int((seconds % 1) * 1000000)])
if values[6] is not None:
tz = xml_timezone()
tz.SetOffset(values[6])
datetime_values.append(tz)
return datetime.datetime(*datetime_values)
else:
raise ValueError("\"%s\" isn't a valid datetime!" % value)
def GenerateModelNameExtraction(type, model):
"""
Function that generates an extraction function for string matching a model
@param type: name of the data type
@param model: model that data must match
@return: function generated
"""
def GetModelName(attr, extract=True):
"""
Function that extracts a string from a tree node or not and check that
string extracted or given match the model
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a string if matching
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
result = model.match(value)
if not result:
raise ValueError("\"%s\" isn't a valid %s!" % (value, type))
return value
return GetModelName
def GenerateLimitExtraction(min=None, max=None, unbounded=True):
"""
Function that generates an extraction function for integer defining min and
max of integer value
@param min: minimum limit value
@param max: maximum limit value
@param unbounded: value can be "unbounded" or not
@return: function generated
"""
def GetLimit(attr, extract=True):
"""
Function that extracts a string from a tree node or not and check that
string extracted or given is in a list of values
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a string
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value == "unbounded":
if unbounded:
return value
else:
raise ValueError("Member limit can't be defined to \"unbounded\"!")
try:
limit = int(value)
except:
raise ValueError("\"%s\" isn't a valid value for this member limit!" % value)
if limit < 0:
raise ValueError("Member limit can't be negative!")
elif min is not None and limit < min:
raise ValueError("Member limit can't be lower than \"%d\"!" % min)
elif max is not None and limit > max:
raise ValueError("Member limit can't be upper than \"%d\"!" % max)
return limit
return GetLimit
def GenerateEnumeratedExtraction(type, list):
"""
Function that generates an extraction function for enumerated values
@param type: name of the data type
@param list: list of possible values
@return: function generated
"""
def GetEnumerated(attr, extract=True):
"""
Function that extracts a string from a tree node or not and check that
string extracted or given is in a list of values
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a string
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value in list:
return value
else:
raise ValueError("\"%s\" isn't a valid value for %s!" % \
(value, type))
return GetEnumerated
def GetNamespaces(attr, extract=True):
"""
Function that extracts a list of namespaces from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: list of namespaces
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value == "":
return []
elif value == "##any" or value == "##other":
namespaces = [value]
else:
namespaces = []
for item in value.split(" "):
if item == "##targetNamespace" or item == "##local":
namespaces.append(item)
else:
result = URI_model.match(item)
if result is not None:
namespaces.append(item)
else:
raise ValueError("\"%s\" isn't a valid value for namespace!" % value)
return namespaces
def GenerateGetList(type, list):
"""
Function that generates an extraction function for a list of values
@param type: name of the data type
@param list: list of possible values
@return: function generated
"""
def GetLists(attr, extract=True):
"""
Function that extracts a list of values from a tree node or a string
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: list of values
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
if value == "":
return []
elif value == "#all":
return [value]
else:
values = []
for item in value.split(" "):
if item in list:
values.append(item)
else:
raise ValueError("\"%s\" isn't a valid value for %s!" % \
(value, type))
return values
return GetLists
def GenerateModelNameListExtraction(type, model):
"""
Function that generates an extraction function for list of string matching
a model
@param type: name of the data type
@param model: model that list elements must match
@return: function generated
"""
def GetModelNameList(attr, extract=True):
"""
Function that extracts a list of string from a tree node or not and
check that all extracted items match the model
@param attr: tree node containing data to extract or data as a string
@param extract: attr is a tree node or not
@return: data as a list of string if matching
"""
if extract:
value = GetAttributeValue(attr)
else:
value = attr
values = []
for item in value.split(" "):
result = model.match(item)
if result is not None:
values.append(item)
else:
raise ValueError("\"%s\" isn't a valid value for %s!" % \
(value, type))
return values
return GetModelNameList
def GenerateAnyInfos(infos):
def ExtractAny(tree):
if tree.nodeName in ["#text", "#cdata-section"]:
return unescape(tree.data.encode("utf-8"))
else:
return tree
def GenerateAny(value, name=None, indent=0):
if isinstance(value, (StringType, UnicodeType)):
try:
value = value.decode("utf-8")
except:
pass
return u'<![CDATA[%s]]>\n' % value
else:
return value.toprettyxml(indent=" "*indent, encoding="utf-8")
return {
"type": COMPLEXTYPE,
"extract": ExtractAny,
"generate": GenerateAny,
"initial": lambda: "",
"check": lambda x: isinstance(x, (StringType, UnicodeType, minidom.Node))
}
def GenerateTagInfos(infos):
def ExtractTag(tree):
if len(tree._attrs) > 0:
raise ValueError("\"%s\" musn't have attributes!" % infos["name"])
if len(tree.childNodes) > 0:
raise ValueError("\"%s\" musn't have children!" % infos["name"])
if infos["minOccurs"] == 0:
return True
else:
return None
def GenerateTag(value, name=None, indent=0):
if name is not None and not (infos["minOccurs"] == 0 and value is None):
ind1, ind2 = getIndent(indent, name)
return ind1 + "<%s/>\n" % name
else:
return ""
return {
"type": TAG,
"extract": ExtractTag,
"generate": GenerateTag,
"initial": lambda: None,
"check": lambda x: x == None or infos["minOccurs"] == 0 and value == True
}
def FindTypeInfos(factory, infos):
if isinstance(infos, (UnicodeType, StringType)):
namespace, name = DecomposeQualifiedName(infos)
return factory.GetQualifiedNameInfos(name, namespace)
return infos
def GetElementInitialValue(factory, infos):
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
if infos["minOccurs"] == 0 and infos["maxOccurs"] == 1:
if infos.has_key("default"):
return infos["elmt_type"]["extract"](infos["default"], False)
else:
return None
elif infos["minOccurs"] == 1 and infos["maxOccurs"] == 1:
return infos["elmt_type"]["initial"]()
else:
return [infos["elmt_type"]["initial"]() for i in xrange(infos["minOccurs"])]
def HandleError(message, raise_exception):
if raise_exception:
raise ValueError(message)
return False
def CheckElementValue(factory, name, infos, value, raise_exception=True):
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
if value is None and raise_exception:
if not (infos["minOccurs"] == 0 and infos["maxOccurs"] == 1):
return HandleError("Attribute '%s' isn't optional." % name, raise_exception)
elif infos["maxOccurs"] == "unbounded" or infos["maxOccurs"] > 1:
if not isinstance(value, ListType):
return HandleError("Attribute '%s' must be a list." % name, raise_exception)
if len(value) < infos["minOccurs"] or infos["maxOccurs"] != "unbounded" and len(value) > infos["maxOccurs"]:
return HandleError("List out of bounds for attribute '%s'." % name, raise_exception)
if not reduce(lambda x, y: x and y, map(infos["elmt_type"]["check"], value), True):
return HandleError("Attribute '%s' must be a list of valid elements." % name, raise_exception)
elif infos.has_key("fixed") and value != infos["fixed"]:
return HandleError("Value of attribute '%s' can only be '%s'." % (name, str(infos["fixed"])), raise_exception)
else:
return infos["elmt_type"]["check"](value)
return True
def GetContentInfos(name, choices):
for choice_infos in choices:
if choices_infos["type"] == "sequence":
for element_infos in choices_infos["elements"]:
if element_infos["type"] == CHOICE:
if GetContentInfos(name, element_infos["choices"]):
return choices_infos
elif element_infos["name"] == name:
return choices_infos
elif choice_infos["name"] == name:
return choices_infos
return None
def ComputeContentChoices(factory, name, infos):
choices = []
for choice in infos["choices"]:
if choice["type"] == "sequence":
choice["name"] = "sequence"
for sequence_element in choice["elements"]:
if sequence_element["type"] != CHOICE:
element_infos = factory.ExtractTypeInfos(sequence_element["name"], name, sequence_element["elmt_type"])
if element_infos is not None:
sequence_element["elmt_type"] = element_infos
elif choice["elmt_type"] == "tag":
choice["elmt_type"] = GenerateTagInfos(choice)
else:
choice_infos = factory.ExtractTypeInfos(choice["name"], name, choice["elmt_type"])
if choice_infos is not None:
choice["elmt_type"] = choice_infos
choices.append((choice["name"], choice))
return choices
def ExtractContentElement(factory, tree, infos, content):
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
if infos["maxOccurs"] == "unbounded" or infos["maxOccurs"] > 1:
if isinstance(content, ListType) and len(content) > 0 and \
content[-1]["name"] == tree.nodeName:
content_item = content.pop(-1)
content_item["value"].append(infos["elmt_type"]["extract"](tree))
return content_item
elif not isinstance(content, ListType) and \
content is not None and \
content["name"] == tree.nodeName:
return {"name": tree.nodeName,
"value": content["value"] + [infos["elmt_type"]["extract"](tree)]}
else:
return {"name": tree.nodeName,
"value": [infos["elmt_type"]["extract"](tree)]}
else:
return {"name": tree.nodeName,
"value": infos["elmt_type"]["extract"](tree)}
def GenerateContentInfos(factory, name, choices):
choices_dict = {}
for choice_name, infos in choices:
if choice_name == "sequence":
for element in infos["elements"]:
if element["type"] == CHOICE:
element["elmt_type"] = GenerateContentInfos(factory, name, ComputeContentChoices(factory, name, element))
elif choices_dict.has_key(element["name"]):
raise ValueError("'%s' element defined two times in choice" % choice_name)
else:
choices_dict[element["name"]] = infos
else:
if choices_dict.has_key(choice_name):
raise ValueError("'%s' element defined two times in choice" % choice_name)
choices_dict[choice_name] = infos
def GetContentInitial():
content_name, infos = choices[0]
if content_name == "sequence":
content_value = []
for i in xrange(infos["minOccurs"]):
for element_infos in infos["elements"]:
value = GetElementInitialValue(factory, element_infos)
if value is not None:
if element_infos["type"] == CHOICE:
content_value.append(value)
else:
content_value.append({"name": element_infos["name"], "value": value})
else:
content_value = GetElementInitialValue(factory, infos)
return {"name": content_name, "value": content_value}
def CheckContent(value):
if value["name"] != "sequence":
infos = choices_dict.get(value["name"], None)
if infos is not None:
return CheckElementValue(factory, value["name"], infos, value["value"], False)
elif len(value["value"]) > 0:
infos = choices_dict.get(value["value"][0]["name"], None)
if infos is None:
for choice_name, infos in choices:
if infos["type"] == "sequence":
for element_infos in infos["elements"]:
if element_infos["type"] == CHOICE:
infos = GetContentInfos(value["value"][0]["name"], element_infos["choices"])
if infos is not None:
sequence_number = 0
element_idx = 0
while element_idx < len(value["value"]):
for element_infos in infos["elements"]:
if element_infos["name"] == value["value"][element_idx]["name"]:
element_value = value["value"][element_idx]["value"]
element_idx += 1
else:
element_value = None
if not CheckElementValue(factory, element_infos["name"], element_infos, element_value, False):
raise ValueError("Invalid sequence value in attribute 'content'")
sequence_number += 1
if sequence_number < infos["minOccurs"] or infos["maxOccurs"] != "unbounded" and sequence_number > infos["maxOccurs"]:
raise ValueError("Invalid sequence value in attribute 'content'")
return True
else:
for element_name, infos in choices:
if element_name == "sequence":
required = 0
for element in infos["elements"]:
if element["minOccurs"] > 0:
required += 1
if required == 0:
return True
return False
def ExtractContent(tree, content):
infos = choices_dict.get(tree.nodeName, None)
if infos is not None:
if infos["name"] == "sequence":
sequence_dict = dict([(element_infos["name"], element_infos) for element_infos in infos["elements"] if element_infos["type"] != CHOICE])
element_infos = sequence_dict.get(tree.nodeName)
if content is not None and \
content["name"] == "sequence" and \
len(content["value"]) > 0 and \
choices_dict.get(content["value"][-1]["name"]) == infos:
return {"name": "sequence",
"value": content["value"] + [ExtractContentElement(factory, tree, element_infos, content["value"][-1])]}
else:
return {"name": "sequence",
"value": [ExtractContentElement(factory, tree, element_infos, None)]}
else:
return ExtractContentElement(factory, tree, infos, content)
else:
for choice_name, infos in choices:
if infos["type"] == "sequence":
for element_infos in infos["elements"]:
if element_infos["type"] == CHOICE:
try:
if content is not None and \
content["name"] == "sequence" and \
len(content["value"]) > 0:
return {"name": "sequence",
"value": content["value"] + [element_infos["elmt_type"]["extract"](tree, content["value"][-1])]}
else:
return {"name": "sequence",
"value": [element_infos["elmt_type"]["extract"](tree, None)]}
except:
pass
raise ValueError("Invalid element \"%s\" for content!" % tree.nodeName)
def GenerateContent(value, name=None, indent=0):
text = ""
if value["name"] != "sequence":
infos = choices_dict.get(value["name"], None)
if infos is not None:
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
if infos["maxOccurs"] == "unbounded" or infos["maxOccurs"] > 1:
for item in value["value"]:
text += infos["elmt_type"]["generate"](item, value["name"], indent)
else:
text += infos["elmt_type"]["generate"](value["value"], value["name"], indent)
elif len(value["value"]) > 0:
infos = choices_dict.get(value["value"][0]["name"], None)
if infos is None:
for choice_name, infos in choices:
if infos["type"] == "sequence":
for element_infos in infos["elements"]:
if element_infos["type"] == CHOICE:
infos = GetContentInfos(value["value"][0]["name"], element_infos["choices"])
if infos is not None:
sequence_dict = dict([(element_infos["name"], element_infos) for element_infos in infos["elements"]])
for element_value in value["value"]:
element_infos = sequence_dict.get(element_value["name"])
if element_infos["maxOccurs"] == "unbounded" or element_infos["maxOccurs"] > 1:
for item in element_value["value"]:
text += element_infos["elmt_type"]["generate"](item, element_value["name"], indent)
else:
text += element_infos["elmt_type"]["generate"](element_value["value"], element_infos["name"], indent)
return text
return {
"type": COMPLEXTYPE,
"initial": GetContentInitial,
"check": CheckContent,
"extract": ExtractContent,
"generate": GenerateContent
}
#-------------------------------------------------------------------------------
# Structure extraction functions
#-------------------------------------------------------------------------------
def DecomposeQualifiedName(name):
result = QName_model.match(name)
if not result:
raise ValueError("\"%s\" isn't a valid QName value!" % name)
parts = result.groups()[0].split(':')
if len(parts) == 1:
return None, parts[0]
return parts
def GenerateElement(element_name, attributes, elements_model,
accept_text=False):
def ExtractElement(factory, node):
attrs = factory.ExtractNodeAttrs(element_name, node, attributes)
children_structure = ""
children_infos = []
children = []
for child in node.childNodes:
if child.nodeName not in ["#comment", "#text"]:
namespace, childname = DecomposeQualifiedName(child.nodeName)
children_structure += "%s "%childname
result = elements_model.match(children_structure)
if not result:
raise ValueError("Invalid structure for \"%s\" children!. First element invalid." % node.nodeName)
valid = result.groups()[0]
if len(valid) < len(children_structure):
raise ValueError("Invalid structure for \"%s\" children!. Element number %d invalid." % (node.nodeName, len(valid.split(" ")) - 1))
for child in node.childNodes:
if child.nodeName != "#comment" and \
(accept_text or child.nodeName != "#text"):
if child.nodeName == "#text":
children.append(GetAttributeValue(node))
else:
namespace, childname = DecomposeQualifiedName(child.nodeName)
infos = factory.GetQualifiedNameInfos(childname, namespace)
if infos["type"] != SYNTAXELEMENT:
raise ValueError("\"%s\" can't be a member child!" % name)
if infos["extract"].has_key(element_name):
children.append(infos["extract"][element_name](factory, child))
else:
children.append(infos["extract"]["default"](factory, child))
return node.nodeName, attrs, children
return ExtractElement
"""
Class that generate class from an XML Tree
"""
class ClassFactory:
def __init__(self, document, filepath=None, debug=False):
self.Document = document
if filepath is not None:
self.BaseFolder, self.FileName = os.path.split(filepath)
else:
self.BaseFolder = self.FileName = None
self.Debug = debug
# Dictionary for stocking Classes and Types definitions created from
# the XML tree
self.XMLClassDefinitions = {}
self.DefinedNamespaces = {}
self.Namespaces = {}
self.SchemaNamespace = None
self.TargetNamespace = None
self.CurrentCompilations = []
# Dictionaries for stocking Classes and Types generated
self.ComputeAfter = []
if self.FileName is not None:
self.ComputedClasses = {self.FileName: {}}
else:
self.ComputedClasses = {}
self.ComputedClassesInfos = {}
self.AlreadyComputed = {}
def GetQualifiedNameInfos(self, name, namespace=None, canbenone=False):
if namespace is None:
if self.Namespaces[self.SchemaNamespace].has_key(name):
return self.Namespaces[self.SchemaNamespace][name]
for space, elements in self.Namespaces.iteritems():
if space != self.SchemaNamespace and elements.has_key(name):
return elements[name]
parts = name.split("_", 1)
if len(parts) > 1:
group = self.GetQualifiedNameInfos(parts[0], namespace)
if group is not None and group["type"] == ELEMENTSGROUP:
elements = []
if group.has_key("elements"):
elements = group["elements"]
elif group.has_key("choices"):
elements = group["choices"]
for element in elements:
if element["name"] == parts[1]:
return element
if not canbenone:
raise ValueError("Unknown element \"%s\" for any defined namespaces!" % name)
elif self.Namespaces.has_key(namespace):
if self.Namespaces[namespace].has_key(name):
return self.Namespaces[namespace][name]
parts = name.split("_", 1)
if len(parts) > 1:
group = self.GetQualifiedNameInfos(parts[0], namespace)
if group is not None and group["type"] == ELEMENTSGROUP:
elements = []
if group.has_key("elements"):
elements = group["elements"]
elif group.has_key("choices"):
elements = group["choices"]
for element in elements:
if element["name"] == parts[1]:
return element
if not canbenone:
raise ValueError("Unknown element \"%s\" for namespace \"%s\"!" % (name, namespace))
elif not canbenone:
raise ValueError("Unknown namespace \"%s\"!" % namespace)
return None
def SplitQualifiedName(self, name, namespace=None, canbenone=False):
if namespace is None:
if self.Namespaces[self.SchemaNamespace].has_key(name):
return name, None
for space, elements in self.Namespaces.items():
if space != self.SchemaNamespace and elements.has_key(name):
return name, None
parts = name.split("_", 1)
if len(parts) > 1:
group = self.GetQualifiedNameInfos(parts[0], namespace)
if group is not None and group["type"] == ELEMENTSGROUP:
elements = []
if group.has_key("elements"):
elements = group["elements"]
elif group.has_key("choices"):
elements = group["choices"]
for element in elements:
if element["name"] == parts[1]:
return part[1], part[0]
if not canbenone:
raise ValueError("Unknown element \"%s\" for any defined namespaces!" % name)
elif self.Namespaces.has_key(namespace):
if self.Namespaces[namespace].has_key(name):
return name, None
parts = name.split("_", 1)
if len(parts) > 1:
group = self.GetQualifiedNameInfos(parts[0], namespace)
if group is not None and group["type"] == ELEMENTSGROUP:
elements = []
if group.has_key("elements"):
elements = group["elements"]
elif group.has_key("choices"):
elements = group["choices"]
for element in elements:
if element["name"] == parts[1]:
return parts[1], parts[0]
if not canbenone:
raise ValueError("Unknown element \"%s\" for namespace \"%s\"!" % (name, namespace))
elif not canbenone:
raise ValueError("Unknown namespace \"%s\"!" % namespace)
return None, None
def ExtractNodeAttrs(self, element_name, node, valid_attrs):
attrs = {}
for qualified_name, attr in node._attrs.items():
namespace, name = DecomposeQualifiedName(qualified_name)
if name in valid_attrs:
infos = self.GetQualifiedNameInfos(name, namespace)
if infos["type"] != SYNTAXATTRIBUTE:
raise ValueError("\"%s\" can't be a member attribute!" % name)
elif name in attrs:
raise ValueError("\"%s\" attribute has been twice!" % name)
elif element_name in infos["extract"]:
attrs[name] = infos["extract"][element_name](attr)
else:
attrs[name] = infos["extract"]["default"](attr)
elif namespace == "xmlns":
infos = self.GetQualifiedNameInfos("anyURI", self.SchemaNamespace)
self.DefinedNamespaces[infos["extract"](attr)] = name
else:
raise ValueError("Invalid attribute \"%s\" for member \"%s\"!" % (qualified_name, node.nodeName))
for attr in valid_attrs:
if attr not in attrs and \
self.Namespaces[self.SchemaNamespace].has_key(attr) and \
self.Namespaces[self.SchemaNamespace][attr].has_key("default"):
if self.Namespaces[self.SchemaNamespace][attr]["default"].has_key(element_name):
default = self.Namespaces[self.SchemaNamespace][attr]["default"][element_name]
else:
default = self.Namespaces[self.SchemaNamespace][attr]["default"]["default"]
if default is not None:
attrs[attr] = default
return attrs
def ReduceElements(self, elements, schema=False):
result = []
for child_infos in elements:
if child_infos is not None:
if child_infos[1].has_key("name") and schema:
self.CurrentCompilations.append(child_infos[1]["name"])
namespace, name = DecomposeQualifiedName(child_infos[0])
infos = self.GetQualifiedNameInfos(name, namespace)
if infos["type"] != SYNTAXELEMENT:
raise ValueError("\"%s\" can't be a member child!" % name)
element = infos["reduce"](self, child_infos[1], child_infos[2])
if element is not None:
result.append(element)
if child_infos[1].has_key("name") and schema:
self.CurrentCompilations.pop(-1)
annotations = []
children = []
for element in result:
if element["type"] == "annotation":
annotations.append(element)
else:
children.append(element)
return annotations, children
def AddComplexType(self, typename, infos):
if not self.XMLClassDefinitions.has_key(typename):
self.XMLClassDefinitions[typename] = infos
else:
raise ValueError("\"%s\" class already defined. Choose another name!" % typename)
def ParseSchema(self):
pass
def ExtractTypeInfos(self, name, parent, typeinfos):
if isinstance(typeinfos, (StringType, UnicodeType)):
namespace, name = DecomposeQualifiedName(typeinfos)
infos = self.GetQualifiedNameInfos(name, namespace)
if infos["type"] == COMPLEXTYPE:
name, parent = self.SplitQualifiedName(name, namespace)
result = self.CreateClass(name, parent, infos)
if result is not None and not isinstance(result, (UnicodeType, StringType)):
self.Namespaces[self.TargetNamespace][result["name"]] = result
return result
elif infos["type"] == ELEMENT and infos["elmt_type"]["type"] == COMPLEXTYPE:
name, parent = self.SplitQualifiedName(name, namespace)
result = self.CreateClass(name, parent, infos["elmt_type"])
if result is not None and not isinstance(result, (UnicodeType, StringType)):
self.Namespaces[self.TargetNamespace][result["name"]] = result
return result
else:
return infos
elif typeinfos["type"] == COMPLEXTYPE:
return self.CreateClass(name, parent, typeinfos)
elif typeinfos["type"] == SIMPLETYPE:
return typeinfos
"""
Methods that generates the classes
"""
def CreateClasses(self):
self.ParseSchema()
for name, infos in self.Namespaces[self.TargetNamespace].items():
if infos["type"] == ELEMENT:
if not isinstance(infos["elmt_type"], (UnicodeType, StringType)) and \
infos["elmt_type"]["type"] == COMPLEXTYPE:
self.ComputeAfter.append((name, None, infos["elmt_type"], True))
while len(self.ComputeAfter) > 0:
result = self.CreateClass(*self.ComputeAfter.pop(0))
if result is not None and not isinstance(result, (UnicodeType, StringType)):
self.Namespaces[self.TargetNamespace][result["name"]] = result
elif infos["type"] == COMPLEXTYPE:
self.ComputeAfter.append((name, None, infos))
while len(self.ComputeAfter) > 0:
result = self.CreateClass(*self.ComputeAfter.pop(0))
if result is not None and \
not isinstance(result, (UnicodeType, StringType)):
self.Namespaces[self.TargetNamespace][result["name"]] = result
elif infos["type"] == ELEMENTSGROUP:
elements = []
if infos.has_key("elements"):
elements = infos["elements"]
elif infos.has_key("choices"):
elements = infos["choices"]
for element in elements:
if not isinstance(element["elmt_type"], (UnicodeType, StringType)) and \
element["elmt_type"]["type"] == COMPLEXTYPE:
self.ComputeAfter.append((element["name"], infos["name"], element["elmt_type"]))
while len(self.ComputeAfter) > 0:
result = self.CreateClass(*self.ComputeAfter.pop(0))
if result is not None and \
not isinstance(result, (UnicodeType, StringType)):
self.Namespaces[self.TargetNamespace][result["name"]] = result
return self.ComputedClasses
def CreateClass(self, name, parent, classinfos, baseclass = False):
if parent is not None:
classname = "%s_%s" % (parent, name)
else:
classname = name
# Checks that classe haven't been generated yet
if self.AlreadyComputed.get(classname, False):
if baseclass:
self.AlreadyComputed[classname].IsBaseClass = baseclass
return self.ComputedClassesInfos.get(classname, None)
# If base classes haven't been generated
bases = []
base_infos = classinfos.get("base", None)
if base_infos is not None:
result = self.ExtractTypeInfos("base", name, base_infos)
if result is None:
namespace, base_name = DecomposeQualifiedName(base_infos)
if self.AlreadyComputed.get(base_name, False):
self.ComputeAfter.append((name, parent, classinfos))
if self.TargetNamespace is not None:
return "%s:%s" % (self.TargetNamespace, classname)
else:
return classname
elif result is not None:
if self.FileName is not None:
classinfos["base"] = self.ComputedClasses[self.FileName].get(result["name"], None)
if classinfos["base"] is None:
for filename, classes in self.ComputedClasses.iteritems():
if filename != self.FileName:
classinfos["base"] = classes.get(result["name"], None)
if classinfos["base"] is not None:
break
else:
classinfos["base"] = self.ComputedClasses.get(result["name"], None)
if classinfos["base"] is None:
raise ValueError("No class found for base type")
bases.append(classinfos["base"])
bases.append(object)
bases = tuple(bases)
classmembers = {"__doc__": classinfos.get("doc", ""), "IsBaseClass": baseclass}
self.AlreadyComputed[classname] = True
for attribute in classinfos["attributes"]:
infos = self.ExtractTypeInfos(attribute["name"], name, attribute["attr_type"])
if infos is not None:
if infos["type"] != SIMPLETYPE:
raise ValueError("\"%s\" type is not a simple type!" % attribute["attr_type"])
attrname = attribute["name"]
if attribute["use"] == "optional":
classmembers[attrname] = None
classmembers["add%s"%attrname] = generateAddMethod(attrname, self, attribute)
classmembers["delete%s"%attrname] = generateDeleteMethod(attrname)
else:
classmembers[attrname] = infos["initial"]()
classmembers["set%s"%attrname] = generateSetMethod(attrname)
classmembers["get%s"%attrname] = generateGetMethod(attrname)
else:
raise ValueError("\"%s\" type unrecognized!" % attribute["attr_type"])
attribute["attr_type"] = infos
for element in classinfos["elements"]:
if element["type"] == CHOICE:
elmtname = element["name"]
choices = ComputeContentChoices(self, name, element)
classmembers["get%schoices"%elmtname] = generateGetChoicesMethod(element["choices"])
if element["maxOccurs"] == "unbounded" or element["maxOccurs"] > 1:
classmembers["append%sbytype" % elmtname] = generateAppendChoiceByTypeMethod(element["maxOccurs"], self, element["choices"])
classmembers["insert%sbytype" % elmtname] = generateInsertChoiceByTypeMethod(element["maxOccurs"], self, element["choices"])
else:
classmembers["set%sbytype" % elmtname] = generateSetChoiceByTypeMethod(self, element["choices"])
infos = GenerateContentInfos(self, name, choices)
elif element["type"] == ANY:
elmtname = element["name"] = "text"
element["minOccurs"] = element["maxOccurs"] = 1
infos = GenerateAnyInfos(element)
else:
elmtname = element["name"]
if element["elmt_type"] == "tag":
infos = GenerateTagInfos(element)
else:
infos = self.ExtractTypeInfos(element["name"], name, element["elmt_type"])
if infos is not None:
element["elmt_type"] = infos
if element["maxOccurs"] == "unbounded" or element["maxOccurs"] > 1:
classmembers[elmtname] = []
classmembers["append%s" % elmtname] = generateAppendMethod(elmtname, element["maxOccurs"], self, element)
classmembers["insert%s" % elmtname] = generateInsertMethod(elmtname, element["maxOccurs"], self, element)
classmembers["remove%s" % elmtname] = generateRemoveMethod(elmtname, element["minOccurs"])
classmembers["count%s" % elmtname] = generateCountMethod(elmtname)
else:
if element["minOccurs"] == 0:
classmembers[elmtname] = None
classmembers["add%s" % elmtname] = generateAddMethod(elmtname, self, element)
classmembers["delete%s" % elmtname] = generateDeleteMethod(elmtname)
elif not isinstance(element["elmt_type"], (UnicodeType, StringType)):
classmembers[elmtname] = element["elmt_type"]["initial"]()
else:
classmembers[elmtname] = None
classmembers["set%s" % elmtname] = generateSetMethod(elmtname)
classmembers["get%s" % elmtname] = generateGetMethod(elmtname)
classmembers["__init__"] = generateInitMethod(self, classinfos)
classmembers["__setattr__"] = generateSetattrMethod(self, classinfos)
classmembers["getStructure"] = generateStructureMethod(classinfos)
classmembers["loadXMLTree"] = generateLoadXMLTree(self, classinfos)
classmembers["generateXMLText"] = generateGenerateXMLText(self, classinfos)
classmembers["getElementAttributes"] = generateGetElementAttributes(self, classinfos)
classmembers["getElementInfos"] = generateGetElementInfos(self, classinfos)
classmembers["setElementValue"] = generateSetElementValue(self, classinfos)
classmembers["singleLineAttributes"] = True
classmembers["compatibility"] = lambda x, y: None
class_definition = classobj(str(classname), bases, classmembers)
class_infos = {"type": COMPILEDCOMPLEXTYPE,
"name": classname,
"check": generateClassCheckFunction(class_definition),
"initial": generateClassCreateFunction(class_definition),
"extract": generateClassExtractFunction(class_definition),
"generate": class_definition.generateXMLText}
if self.FileName is not None:
self.ComputedClasses[self.FileName][classname] = class_definition
else:
self.ComputedClasses[classname] = class_definition
self.ComputedClassesInfos[classname] = class_infos
return class_infos
"""
Methods that print the classes generated
"""
def PrintClasses(self):
items = self.ComputedClasses.items()
items.sort()
if self.FileName is not None:
for filename, classes in items:
print "File '%s':" % filename
class_items = classes.items()
class_items.sort()
for classname, xmlclass in class_items:
print "%s: %s" % (classname, str(xmlclass))
else:
for classname, xmlclass in items:
print "%s: %s" % (classname, str(xmlclass))
def PrintClassNames(self):
classnames = self.XMLClassDefinitions.keys()
classnames.sort()
for classname in classnames:
print classname
"""
Method that generate the method for checking a class instance
"""
def generateClassCheckFunction(class_definition):
def classCheckfunction(instance):
return isinstance(instance, class_definition)
return classCheckfunction
"""
Method that generate the method for creating a class instance
"""
def generateClassCreateFunction(class_definition):
def classCreatefunction():
return class_definition()
return classCreatefunction
"""
Method that generate the method for extracting a class instance
"""
def generateClassExtractFunction(class_definition):
def classExtractfunction(node):
instance = class_definition()
instance.loadXMLTree(node)
return instance
return classExtractfunction
"""
Method that generate the method for loading an xml tree by following the
attributes list defined
"""
def generateSetattrMethod(factory, classinfos):
attributes = dict([(attr["name"], attr) for attr in classinfos["attributes"] if attr["use"] != "prohibited"])
optional_attributes = dict([(attr["name"], True) for attr in classinfos["attributes"] if attr["use"] == "optional"])
elements = dict([(element["name"], element) for element in classinfos["elements"]])
def setattrMethod(self, name, value):
if attributes.has_key(name):
attributes[name]["attr_type"] = FindTypeInfos(factory, attributes[name]["attr_type"])
if value is None:
if optional_attributes.get(name, False):
return object.__setattr__(self, name, None)
else:
raise ValueError("Attribute '%s' isn't optional." % name)
elif attributes[name].has_key("fixed") and value != attributes[name]["fixed"]:
raise ValueError, "Value of attribute '%s' can only be '%s'."%(name, str(attributes[name]["fixed"]))
elif attributes[name]["attr_type"]["check"](value):
return object.__setattr__(self, name, value)
else:
raise ValueError("Invalid value for attribute '%s'." % (name))
elif elements.has_key(name):
if CheckElementValue(factory, name, elements[name], value):
return object.__setattr__(self, name, value)
else:
raise ValueError("Invalid value for attribute '%s'." % (name))
elif classinfos.has_key("base"):
return classinfos["base"].__setattr__(self, name, value)
elif self.__class__.__dict__.has_key(name):
return object.__setattr__(self, name, value)
else:
raise AttributeError("'%s' can't have an attribute '%s'." % (self.__class__.__name__, name))
return setattrMethod
"""
Method that generate the method for generating the xml tree structure model by
following the attributes list defined
"""
def ComputeMultiplicity(name, infos):
if infos["minOccurs"] == 0:
if infos["maxOccurs"] == "unbounded":
return "(?:%s)*" % name
elif infos["maxOccurs"] == 1:
return "(?:%s)?" % name
else:
return "(?:%s){,%d}" % (name, infos["maxOccurs"])
elif infos["minOccurs"] == 1:
if infos["maxOccurs"] == "unbounded":
return "(?:%s)+" % name
elif infos["maxOccurs"] == 1:
return "(?:%s)" % name
else:
return "(?:%s){1,%d}" % (name, infos["maxOccurs"])
else:
if infos["maxOccurs"] == "unbounded":
return "(?:%s){%d,}" % (name, infos["minOccurs"], name)
else:
return "(?:%s){%d,%d}" % (name, infos["minOccurs"],
infos["maxOccurs"])
def GetStructure(classinfos):
elements = []
for element in classinfos["elements"]:
if element["type"] == ANY:
infos = element.copy()
infos["minOccurs"] = 0
elements.append(ComputeMultiplicity("#text |#cdata-section |\w* ", infos))
elif element["type"] == CHOICE:
choices = []
for infos in element["choices"]:
if infos["type"] == "sequence":
structure = "(?:%s)" % GetStructure(infos)
else:
structure = "%s " % infos["name"]
choices.append(ComputeMultiplicity(structure, infos))
elements.append(ComputeMultiplicity("|".join(choices), element))
elif element["name"] == "content" and element["elmt_type"]["type"] == SIMPLETYPE:
elements.append("(?:#text |#cdata-section )?")
else:
elements.append(ComputeMultiplicity("%s " % element["name"], element))
if classinfos.get("order", True) or len(elements) == 0:
return "".join(elements)
else:
raise ValueError("XSD structure not yet supported!")
def generateStructureMethod(classinfos):
def getStructureMethod(self):
structure = GetStructure(classinfos)
if classinfos.has_key("base"):
return classinfos["base"].getStructure(self) + structure
return structure
return getStructureMethod
"""
Method that generate the method for loading an xml tree by following the
attributes list defined
"""
def generateLoadXMLTree(factory, classinfos):
attributes = dict([(attr["name"], attr) for attr in classinfos["attributes"] if attr["use"] != "prohibited"])
elements = dict([(element["name"], element) for element in classinfos["elements"]])
def loadXMLTreeMethod(self, tree, extras=[], derived=False):
self.compatibility(tree)
if not derived:
children_structure = ""
for node in tree.childNodes:
if not (node.nodeName == "#text" and node.data.strip() == "") and node.nodeName != "#comment":
children_structure += "%s " % node.nodeName
structure_pattern = self.getStructure()
if structure_pattern != "":
structure_model = re.compile("(%s)$" % structure_pattern)
result = structure_model.match(children_structure)
if not result:
raise ValueError("Invalid structure for \"%s\" children!." % tree.nodeName)
required_attributes = dict([(attr["name"], True) for attr in classinfos["attributes"] if attr["use"] == "required"])
if classinfos.has_key("base"):
extras.extend([attr["name"] for attr in classinfos["attributes"] if attr["use"] != "prohibited"])
classinfos["base"].loadXMLTree(self, tree, extras, True)
for attrname, attr in tree._attrs.iteritems():
if attributes.has_key(attrname):
attributes[attrname]["attr_type"] = FindTypeInfos(factory, attributes[attrname]["attr_type"])
object.__setattr__(self, attrname, attributes[attrname]["attr_type"]["extract"](attr))
elif not classinfos.has_key("base") and attrname not in extras:
raise ValueError("Invalid attribute \"%s\" for \"%s\" element!" % (attrname, tree.nodeName))
required_attributes.pop(attrname, None)
if len(required_attributes) > 0:
raise ValueError("Required attributes %s missing for \"%s\" element!" % (", ".join(["\"%s\""%name for name in required_attributes]), tree.nodeName))
first = {}
for node in tree.childNodes:
name = node.nodeName
if name == "#text" and node.data.strip() == "" or name == "#comment":
continue
elif elements.has_key(name):
elements[name]["elmt_type"] = FindTypeInfos(factory, elements[name]["elmt_type"])
if elements[name]["maxOccurs"] == "unbounded" or elements[name]["maxOccurs"] > 1:
if first.get(name, True):
object.__setattr__(self, name, [elements[name]["elmt_type"]["extract"](node)])
first[name] = False
else:
getattr(self, name).append(elements[name]["elmt_type"]["extract"](node))
else:
object.__setattr__(self, name, elements[name]["elmt_type"]["extract"](node))
elif elements.has_key("text"):
if elements["text"]["maxOccurs"] == "unbounded" or elements["text"]["maxOccurs"] > 1:
if first.get("text", True):
object.__setattr__(self, "text", [elements["text"]["elmt_type"]["extract"](node)])
first["text"] = False
else:
getattr(self, "text").append(elements["text"]["elmt_type"]["extract"](node))
else:
object.__setattr__(self, "text", elements["text"]["elmt_type"]["extract"](node))
elif elements.has_key("content"):
if name in ["#cdata-section", "#text"]:
if elements["content"]["elmt_type"]["type"] == SIMPLETYPE:
object.__setattr__(self, "content", elements["content"]["elmt_type"]["extract"](node.data, False))
else:
content = getattr(self, "content")
if elements["content"]["maxOccurs"] == "unbounded" or elements["content"]["maxOccurs"] > 1:
if first.get("content", True):
object.__setattr__(self, "content", [elements["content"]["elmt_type"]["extract"](node, None)])
first["content"] = False
else:
content.append(elements["content"]["elmt_type"]["extract"](node, content))
else:
object.__setattr__(self, "content", elements["content"]["elmt_type"]["extract"](node, content))
return loadXMLTreeMethod
"""
Method that generates the method for generating an xml text by following the
attributes list defined
"""
def generateGenerateXMLText(factory, classinfos):
def generateXMLTextMethod(self, name, indent=0, extras={}, derived=False):
ind1, ind2 = getIndent(indent, name)
if not derived:
text = ind1 + u'<%s' % name
else:
text = u''
first = True
if not classinfos.has_key("base"):
for attr, value in extras.items():
if not first and not self.singleLineAttributes:
text += u'\n%s' % (ind2)
text += u' %s=%s' % (attr, quoteattr(value))
first = False
extras.clear()
for attr in classinfos["attributes"]:
if attr["use"] != "prohibited":
attr["attr_type"] = FindTypeInfos(factory, attr["attr_type"])
value = getattr(self, attr["name"], None)
if value != None:
computed_value = attr["attr_type"]["generate"](value)
else:
computed_value = None
if attr["use"] != "optional" or (value != None and \
computed_value != attr.get("default", attr["attr_type"]["generate"](attr["attr_type"]["initial"]()))):
if classinfos.has_key("base"):
extras[attr["name"]] = computed_value
else:
if not first and not self.singleLineAttributes:
text += u'\n%s' % (ind2)
text += ' %s=%s' % (attr["name"], quoteattr(computed_value))
first = False
if classinfos.has_key("base"):
first, new_text = classinfos["base"].generateXMLText(self, name, indent, extras, True)
text += new_text
else:
first = True
for element in classinfos["elements"]:
element["elmt_type"] = FindTypeInfos(factory, element["elmt_type"])
value = getattr(self, element["name"], None)
if element["minOccurs"] == 0 and element["maxOccurs"] == 1:
if value is not None:
if first:
text += u'>\n'
first = False
text += element["elmt_type"]["generate"](value, element["name"], indent + 1)
elif element["minOccurs"] == 1 and element["maxOccurs"] == 1:
if first:
text += u'>\n'
first = False
if element["name"] == "content" and element["elmt_type"]["type"] == SIMPLETYPE:
text += element["elmt_type"]["generate"](value)
else:
text += element["elmt_type"]["generate"](value, element["name"], indent + 1)
else:
if first and len(value) > 0:
text += u'>\n'
first = False
for item in value:
text += element["elmt_type"]["generate"](item, element["name"], indent + 1)
if not derived:
if first:
text += u'/>\n'
else:
text += ind1 + u'</%s>\n' % (name)
return text
else:
return first, text
return generateXMLTextMethod
def gettypeinfos(name, facets):
if facets.has_key("enumeration") and facets["enumeration"][0] is not None:
return facets["enumeration"][0]
elif facets.has_key("maxInclusive"):
limits = {"max" : None, "min" : None}
if facets["maxInclusive"][0] is not None:
limits["max"] = facets["maxInclusive"][0]
elif facets["maxExclusive"][0] is not None:
limits["max"] = facets["maxExclusive"][0] - 1
if facets["minInclusive"][0] is not None:
limits["min"] = facets["minInclusive"][0]
elif facets["minExclusive"][0] is not None:
limits["min"] = facets["minExclusive"][0] + 1
if limits["max"] is not None or limits["min"] is not None:
return limits
return name
def generateGetElementAttributes(factory, classinfos):
def getElementAttributes(self):
attr_list = []
if classinfos.has_key("base"):
attr_list.extend(classinfos["base"].getElementAttributes(self))
for attr in classinfos["attributes"]:
if attr["use"] != "prohibited":
attr_params = {"name" : attr["name"], "use" : attr["use"],
"type" : gettypeinfos(attr["attr_type"]["basename"], attr["attr_type"]["facets"]),
"value" : getattr(self, attr["name"], "")}
attr_list.append(attr_params)
return attr_list
return getElementAttributes
def generateGetElementInfos(factory, classinfos):
attributes = dict([(attr["name"], attr) for attr in classinfos["attributes"] if attr["use"] != "prohibited"])
elements = dict([(element["name"], element) for element in classinfos["elements"]])
def getElementInfos(self, name, path=None, derived=False):
attr_type = "element"
value = None
use = "required"
children = []
if path is not None:
parts = path.split(".", 1)
if attributes.has_key(parts[0]):
if len(parts) != 0:
raise ValueError("Wrong path!")
attr_type = gettypeinfos(attributes[parts[0]]["attr_type"]["basename"],
attributes[parts[0]]["attr_type"]["facets"])
value = getattr(self, parts[0], "")
elif elements.has_key(parts[0]):
if elements[parts[0]]["elmt_type"]["type"] == SIMPLETYPE:
if len(parts) != 0:
raise ValueError("Wrong path!")
attr_type = gettypeinfos(elements[parts[0]]["elmt_type"]["basename"],
elements[parts[0]]["elmt_type"]["facets"])
value = getattr(self, parts[0], "")
elif parts[0] == "content":
return self.content["value"].getElementInfos(self.content["name"], path)
else:
attr = getattr(self, parts[0], None)
if attr is None:
raise ValueError("Wrong path!")
if len(parts) == 1:
return attr.getElementInfos(parts[0])
else:
return attr.getElementInfos(parts[0], parts[1])
else:
raise ValueError("Wrong path!")
else:
if not derived:
children.extend(self.getElementAttributes())
if classinfos.has_key("base"):
children.extend(classinfos["base"].getElementInfos(self, name, derived=True)["children"])
for element_name, element in elements.items():
if element["minOccurs"] == 0:
use = "optional"
if element_name == "content" and element["type"] == CHOICE:
attr_type = [(choice["name"], None) for choice in element["choices"]]
if self.content is None:
value = ""
else:
value = self.content["name"]
if self.content["value"] is not None:
if self.content["name"] == "sequence":
choices_dict = dict([(choice["name"], choice) for choice in element["choices"]])
sequence_infos = choices_dict.get("sequence", None)
if sequence_infos is not None:
children.extend([item.getElementInfos(infos["name"]) for item, infos in zip(self.content["value"], sequence_infos["elements"])])
else:
children.extend(self.content["value"].getElementInfos(self.content["name"])["children"])
elif element["elmt_type"]["type"] == SIMPLETYPE:
children.append({"name": element_name, "require": element["minOccurs"] != 0,
"type": gettypeinfos(element["elmt_type"]["basename"],
element["elmt_type"]["facets"]),
"value": getattr(self, element_name, None)})
else:
instance = getattr(self, element_name, None)
if instance is None:
instance = element["elmt_type"]["initial"]()
children.append(instance.getElementInfos(element_name))
return {"name": name, "type": attr_type, "value": value, "use": use, "children": children}
return getElementInfos
def generateSetElementValue(factory, classinfos):
attributes = dict([(attr["name"], attr) for attr in classinfos["attributes"] if attr["use"] != "prohibited"])
elements = dict([(element["name"], element) for element in classinfos["elements"]])
def setElementValue(self, path, value):
if path is not None:
parts = path.split(".", 1)
if attributes.has_key(parts[0]):
if len(parts) != 1:
raise ValueError("Wrong path!")
if attributes[parts[0]]["attr_type"]["basename"] == "boolean":
setattr(self, parts[0], value)
else:
setattr(self, parts[0], attributes[parts[0]]["attr_type"]["extract"](value, False))
elif elements.has_key(parts[0]):
if elements[parts[0]]["elmt_type"]["type"] == SIMPLETYPE:
if len(parts) != 1:
raise ValueError("Wrong path!")
if elements[parts[0]]["elmt_type"]["basename"] == "boolean":
setattr(self, parts[0], value)
else:
setattr(self, parts[0], elements[parts[0]]["elmt_type"]["extract"](value, False))
else:
instance = getattr(self, parts[0], None)
if instance != None:
if len(parts) > 1:
instance.setElementValue(parts[1], value)
else:
instance.setElementValue(None, value)
elif elements.has_key("content"):
if len(parts) > 0:
self.content["value"].setElementValue(path, value)
elif classinfos.has_key("base"):
classinfos["base"].setElementValue(self, path, value)
elif elements.has_key("content"):
if value == "":
if elements["content"]["minOccurs"] == 0:
self.setcontent(None)
else:
raise ValueError("\"content\" element is required!")
else:
self.setcontentbytype(value)
return setElementValue
"""
Methods that generates the different methods for setting and getting the attributes
"""
def generateInitMethod(factory, classinfos):
def initMethod(self):
if classinfos.has_key("base"):
classinfos["base"].__init__(self)
for attribute in classinfos["attributes"]:
attribute["attr_type"] = FindTypeInfos(factory, attribute["attr_type"])
if attribute["use"] == "required":
setattr(self, attribute["name"], attribute["attr_type"]["initial"]())
elif attribute["use"] == "optional":
if attribute.has_key("default"):
setattr(self, attribute["name"], attribute["attr_type"]["extract"](attribute["default"], False))
else:
setattr(self, attribute["name"], None)
for element in classinfos["elements"]:
setattr(self, element["name"], GetElementInitialValue(factory, element))
return initMethod
def generateSetMethod(attr):
def setMethod(self, value):
setattr(self, attr, value)
return setMethod
def generateGetMethod(attr):
def getMethod(self):
return getattr(self, attr, None)
return getMethod
def generateAddMethod(attr, factory, infos):
def addMethod(self):
if infos["type"] == ATTRIBUTE:
infos["attr_type"] = FindTypeInfos(factory, infos["attr_type"])
initial = infos["attr_type"]["initial"]
extract = infos["attr_type"]["extract"]
elif infos["type"] == ELEMENT:
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
initial = infos["elmt_type"]["initial"]
extract = infos["elmt_type"]["extract"]
else:
raise ValueError("Invalid class attribute!")
if infos.has_key("default"):
setattr(self, attr, extract(infos["default"], False))
else:
setattr(self, attr, initial())
return addMethod
def generateDeleteMethod(attr):
def deleteMethod(self):
setattr(self, attr, None)
return deleteMethod
def generateAppendMethod(attr, maxOccurs, factory, infos):
def appendMethod(self, value):
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
attr_list = getattr(self, attr)
if maxOccurs == "unbounded" or len(attr_list) < maxOccurs:
if infos["elmt_type"]["check"](value):
attr_list.append(value)
else:
raise ValueError("\"%s\" value isn't valid!" % attr)
else:
raise ValueError("There can't be more than %d values in \"%s\"!" % (maxOccurs, attr))
return appendMethod
def generateInsertMethod(attr, maxOccurs, factory, infos):
def insertMethod(self, index, value):
infos["elmt_type"] = FindTypeInfos(factory, infos["elmt_type"])
attr_list = getattr(self, attr)
if maxOccurs == "unbounded" or len(attr_list) < maxOccurs:
if infos["elmt_type"]["check"](value):
attr_list.insert(index, value)
else:
raise ValueError("\"%s\" value isn't valid!" % attr)
else:
raise ValueError("There can't be more than %d values in \"%s\"!" % (maxOccurs, attr))
return insertMethod
def generateGetChoicesMethod(choice_types):
def getChoicesMethod(self):
return [choice["name"] for choice in choice_types]
return getChoicesMethod
def generateSetChoiceByTypeMethod(factory, choice_types):
choices = dict([(choice["name"], choice) for choice in choice_types])
def setChoiceMethod(self, type):
if not choices.has_key(type):
raise ValueError("Unknown \"%s\" choice type for \"content\"!" % type)
choices[type]["elmt_type"] = FindTypeInfos(factory, choices[type]["elmt_type"])
new_element = choices[type]["elmt_type"]["initial"]()
self.content = {"name": type, "value": new_element}
return new_element
return setChoiceMethod
def generateAppendChoiceByTypeMethod(maxOccurs, factory, choice_types):
choices = dict([(choice["name"], choice) for choice in choice_types])
def appendChoiceMethod(self, type):
if not choices.has_key(type):
raise ValueError("Unknown \"%s\" choice type for \"content\"!" % type)
choices[type]["elmt_type"] = FindTypeInfos(factory, choices[type]["elmt_type"])
if maxOccurs == "unbounded" or len(self.content) < maxOccurs:
new_element = choices[type]["elmt_type"]["initial"]()
self.content.append({"name": type, "value": new_element})
return new_element
else:
raise ValueError("There can't be more than %d values in \"content\"!" % maxOccurs)
return appendChoiceMethod
def generateInsertChoiceByTypeMethod(maxOccurs, factory, choice_types):
choices = dict([(choice["name"], choice) for choice in choice_types])
def insertChoiceMethod(self, index, type):
if not choices.has_key(type):
raise ValueError("Unknown \"%s\" choice type for \"content\"!" % type)
choices[type]["elmt_type"] = FindTypeInfos(factory, choices[type]["elmt_type"])
if maxOccurs == "unbounded" or len(self.content) < maxOccurs:
new_element = choices[type]["elmt_type"]["initial"]()
self.content.insert(index, {"name" : type, "value" : new_element})
return new_element
else:
raise ValueError("There can't be more than %d values in \"content\"!" % maxOccurs)
return insertChoiceMethod
def generateRemoveMethod(attr, minOccurs):
def removeMethod(self, index):
attr_list = getattr(self, attr)
if len(attr_list) > minOccurs:
getattr(self, attr).pop(index)
else:
raise ValueError("There can't be less than %d values in \"%s\"!" % (minOccurs, attr))
return removeMethod
def generateCountMethod(attr):
def countMethod(self):
return len(getattr(self, attr))
return countMethod
"""
This function generate the classes from a class factory
"""
def GenerateClasses(factory, declare=False):
ComputedClasses = factory.CreateClasses()
#factory.PrintClasses()
if declare:
for ClassName, Class in pluginClasses.items():
sys._getframe(1).f_locals[ClassName] = Class
for TypeName, Type in pluginTypes.items():
sys._getframe(1).f_locals[TypeName] = Type
if factory.FileName is not None and len(ComputedClasses) == 1:
globals().update(ComputedClasses[factory.FileName])
return ComputedClasses[factory.FileName]
else:
globals().update(ComputedClasses)
return ComputedClasses