I finally found an acceptable solution by using a combination of SPARK (for grammar parsing / syntactic analysis) and my own code for autocompletion.
SPARK stands for the Scanning, Parsing, and Rewriting Kit. It formerly
had no name, and was referred to as the "little language framework."
The first version (circa 1998) was described in the paper Compiling
Little Languages in Python at the 7th International Python Conference.
SPARK is written in 100% pure Python, and is made available as open
The autocompletion code
In the following code:
category is the kind of word we are autocompleting. This is obtained by parsing the current command line. For example: if the user is typing "drink m", the parser will know to expect a word in the category "liquids" defined in the grammar.
- The user input is stored in a list (
_get_list_of_existing() returns a list of existing words in a given category
_get_common_beginning() return - if available - the longest initial supersequence for multiple matches. For example if the user input is writing "ma" and possible autocompletion words are [magnolia, magnifying glass] the
_get_common_beginning() will return "magn".
Here's the relevant code snippets:
def autocomplete(self, category):
If possible, autocomplete a word according to its category.
root = ''.join(self.chars).split()[-1] #The bit after the last space
pool = self._get_list_of_existing(category)
matches = [i for i in pool if i.find(root) == 0]
if len(matches) == 1:
match = matches+' '
elif len(matches) > 1:
match = self._get_common_beginning(matches)
def _get_common_beginning(self, strings):
Return the strings that is common to the beginning of each string in
the strings list.
result = 
limit = min([len(s) for s in strings])
for i in range(limit):
chs = set([s[i] for s in strings])
if len(chs) == 1: