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# Copyright (C) 2020 VyOS maintainers and contributors
#
# This library is free software; you can redistribute it and/or modify it under the terms of
# the GNU Lesser 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 Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser 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
from vyos.xml import kw
# As we index by key, the name is first and then the data:
# {'dummy': {
# '[node]': '[tagNode]',
# 'address': { ... }
# } }
# so when we encounter a tagNode, we are really encountering
# the tagNode data.
class XML(dict):
def __init__(self):
self[kw.tree] = {}
self[kw.priorities] = {}
self[kw.owners] = {}
self[kw.default] = {}
self[kw.tags] = []
dict.__init__(self)
self.tree = self[kw.tree]
# the options which matched the last incomplete world we had
# or the last word in a list
self.options = []
# store all the part of the command we processed
self.inside = []
# should we check the data pass with the constraints
self.check = False
# are we still typing a word
self.filling = False
# do what have the tagNode value ?
self.filled = False
# last word seen
self.word = ''
# do we have all the data we want ?
self.final = False
# do we have too much data ?
self.extra = False
# what kind of node are we in plain vs data not
self.plain = True
def reset(self):
self.tree = self[kw.tree]
self.options = []
self.inside = []
self.check = False
self.filling = False
self.filled = False
self.word = ''
self.final = False
self.extra = False
self.plain = True
# from functools import lru_cache
# @lru_cache(maxsize=100)
# XXX: need to use cachetool instead - for later
def traverse(self, cmd):
self.reset()
# using split() intead of split(' ') eats the final ' '
words = cmd.split(' ')
passed = []
word = ''
data_node = False
space = False
while words:
word = words.pop(0)
space = word == ''
perfect = False
if word in self.tree:
passed = []
perfect = True
self.tree = self.tree[word]
data_node = self.tree[kw.node]
self.inside.append(word)
word = ''
continue
if word and data_node:
passed.append(word)
is_valueless = self.tree.get(kw.valueless, False)
is_leafNode = data_node == kw.leafNode
is_dataNode = data_node in (kw.leafNode, kw.tagNode)
named_options = [_ for _ in self.tree if not kw.found(_)]
if is_leafNode:
self.final = is_valueless or len(passed) > 0
self.extra = is_valueless and len(passed) > 0
self.check = len(passed) >= 1
else:
self.final = False
self.extra = False
self.check = len(passed) == 1 and not space
if self.final:
self.word = ' '.join(passed)
else:
self.word = word
if self.final:
self.filling = True
else:
self.filling = not perfect and bool(cmd and word != '')
self.filled = self.final or (is_dataNode and len(passed) > 0 and word == '')
if is_dataNode and len(passed) == 0:
self.options = []
elif word:
if data_node != kw.plainNode or len(passed) == 1:
self.options = [_ for _ in self.tree if _.startswith(word)]
self.options.sort()
else:
self.options = []
else:
self.options = named_options
self.options.sort()
self.plain = not is_dataNode
# self.debug()
return self.word
def speculate(self):
if len(self.options) == 1:
self.tree = self.tree[self.options[0]]
self.word = ''
if self.tree.get(kw.node,'') not in (kw.tagNode, kw.leafNode):
self.options = [_ for _ in self.tree if not kw.found(_)]
self.options.sort()
def checks(self, cmd):
# as we move thought the named node twice
# the first time we get the data with the node
# and the second with the pass parameters
xml = self[kw.tree]
words = cmd.split(' ')
send = True
last = []
while words:
word = words.pop(0)
if word in xml:
xml = xml[word]
send = True
last = []
continue
if xml[kw.node] in (kw.tagNode, kw.leafNode):
if kw.constraint in xml:
if send:
yield (word, xml[kw.constraint])
send = False
else:
last.append((word, None))
if len(last) >= 2:
yield last[0]
def summary(self):
yield ('enter', '[ summary ]', str(self.inside))
if kw.help not in self.tree:
yield ('skip', '[ summary ]', str(self.inside))
return
if self.filled:
return
yield('', '', '\nHelp:')
if kw.help in self.tree:
summary = self.tree[kw.help].get(kw.summary)
values = self.tree[kw.help].get(kw.valuehelp, [])
if summary:
yield(summary, '', '')
for value in values:
yield(value[kw.format], value[kw.description], '')
def constraint(self):
yield ('enter', '[ constraint ]', str(self.inside))
if kw.help in self.tree:
yield ('skip', '[ constraint ]', str(self.inside))
return
if kw.error not in self.tree:
yield ('skip', '[ constraint ]', str(self.inside))
return
if not self.word or self.filling:
yield ('skip', '[ constraint ]', str(self.inside))
return
yield('', '', '\nData Constraint:')
yield('', 'constraint', str(self.tree[kw.error]))
def listing(self):
yield ('enter', '[ listing ]', str(self.inside))
# only show the details when we passed the tagNode data
if not self.plain and not self.filled:
yield ('skip', '[ listing ]', str(self.inside))
return
yield('', '', '\nPossible completions:')
options = list(self.tree.keys())
options.sort()
for option in options:
if kw.found(option):
continue
if not option.startswith(self.word):
continue
inner = self.tree[option]
prefix = '+> ' if inner.get(kw.node, '') != kw.leafNode else ' '
if kw.help in inner:
yield (prefix + option, inner[kw.help].get(kw.summary), '')
else:
yield (prefix + option, '(no help available)', '')
def debug(self):
print('------')
print("word '%s'" % self.word)
print("filling " + str(self.filling))
print("filled " + str(self.filled))
print("final " + str(self.final))
print("extra " + str(self.extra))
print("plain " + str(self.plain))
print("options " + str(self.options))
# from functools import lru_cache
# @lru_cache(maxsize=100)
# XXX: need to use cachetool instead - for later
def defaults(self, lpath, flat):
d = self[kw.default]
for k in lpath:
d = d.get(k, {})
if not flat:
r = {}
for k in d:
under = k.replace('-','_')
if isinstance(d[k],dict):
r[under] = self.defaults(lpath + [k], flat)
continue
r[under] = d[k]
return r
def _flatten(inside, index, d):
r = {}
local = inside[index:]
prefix = '_'.join(_.replace('-','_') for _ in local) + '_' if local else ''
for k in d:
under = prefix + k.replace('-','_')
level = inside + [k]
if isinstance(d[k],dict):
r.update(_flatten(level, index, d[k]))
continue
if self.is_multi(level, with_tag=False):
r[under] = [_.strip() for _ in d[k].split(',')]
continue
r[under] = d[k]
return r
return _flatten(lpath, len(lpath), d)
# from functools import lru_cache
# @lru_cache(maxsize=100)
# XXX: need to use cachetool instead - for later
def _tree(self, lpath, with_tag=True):
"""
returns the part of the tree searched or None if it does not exists
if with_tag is set, this is a configuration path (with tagNode names)
and tag name will be removed from the path when traversing the tree
"""
tree = self[kw.tree]
spath = lpath.copy()
while spath:
p = spath.pop(0)
if p not in tree:
return None
tree = tree[p]
if with_tag and spath and tree[kw.node] == kw.tagNode:
spath.pop(0)
return tree
def _get(self, lpath, tag, with_tag=True):
tree = self._tree(lpath, with_tag)
if tree is None:
return None
return tree.get(tag, None)
def is_multi(self, lpath, with_tag=True):
tree = self._get(lpath, kw.multi, with_tag)
if tree is None:
return None
return tree is True
def is_tag(self, lpath, with_tag=True):
tree = self._get(lpath, kw.node, with_tag)
if tree is None:
return None
return tree == kw.tagNode
def is_leaf(self, lpath, with_tag=True):
tree = self._get(lpath, kw.node, with_tag)
if tree is None:
return None
return tree == kw.leafNode
def exists(self, lpath, with_tag=True):
return self._get(lpath, kw.node, with_tag) is not None
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