Library for creating state-machine-based chatbots.
Project description
State Transition Dialogue Manager
Defines a dialogue management framework based on state machines and regular expressions.
Installation
Users install using pip install emora_stdm
Developers install using:
git clone https://github.com/emora-chat/emora_stdm.git
pip install -r emora_stdm/requirements.txt
Example usage
from emora_stdm import DialogueFlow
from enum import Enum
# states are typically represented as an enum
class State(Enum):
START = 0
FAM_ANS = 1
FAM_Y = 2
FAM_N = 3
FAM_ERR = 4
WHATEV = 5
# initialize the DialogueFlow object, which uses a state-machine to manage dialogue
df = DialogueFlow(State.START)
# add transitions to create an arbitrary graph for the state machine
df.add_system_transition(State.START, State.FAM_ANS, '[!do you have a $F={brother, sister, son, daughter, cousin}]')
df.add_user_transition(State.FAM_ANS, State.FAM_Y, '[{yes, yea, yup, yep, i do, yeah}]')
df.add_user_transition(State.FAM_ANS, State.FAM_N, '[{no, nope}]')
df.add_system_transition(State.FAM_Y, State.WHATEV, 'thats great i wish i had a $F')
df.add_system_transition(State.FAM_N, State.WHATEV, 'ok then')
df.add_system_transition(State.FAM_ERR, State.WHATEV, 'im not sure i understand')
# each state that will be reached on the user turn should define an error transition if no other transition matches
df.set_error_successor(State.FAM_ANS, State.FAM_ERR)
df.set_error_successor(State.WHATEV, State.START)
if __name__ == '__main__':
# automatic verification of the DialogueFlow's structure (dumps warnings to stdout)
df.check()
# run the DialogueFlow in interactive mode to test
df.run(debugging=True)
Class DialogueFlow
is the main class to initialize. It defines
a state machine that drives natural language conversation. State
transitions in the state machine (alternately) represent either
system or user turns.
dialogue_manager = DialogueFlow(start_state)
initializes a new DialogueFlow
object with start_state
as the
initial state of the state machine.
To add transitions, use either:
.add_system_transition(source_state, target_state, NatexNLG)
method to add a system transition,
or .add_user_transition(source_state, target_state, NatexNLU)
method to add a user transition.
The first two arguments are the source and target states of the transition, the third argument is a string that defines a set of natural language expressions given by a user that satisfy the transition (see NatexNLU/NatexNLG below).
NatexNLU
Strings created for transition NLU define a set of user expressions that satisfy the transition by compiling into regular expressions.
You can also create and test standalone Natex objects:
from emora_stdm import NatexNLU, NatexNLG
natex_nlu = NatexNLU('[{hi, hello} you]')
assert natex_nlu.match('hi there how are you', debugging=True)
natex_nlg = NatexNLG('[!well {hi, hello} there you look {good, fine, great} today]')
print(natex_nlg.generate(debugging=True))
Natex expressions can be formed using the below constructs, which are arbitrarily nestable and concatenable.
Literal
Literals can be formed in three ways:
hello there
sequences of alphabetical characters and whitespace are interpreted as literals. The above matches "hello there".
"Hello there!"
quotes can also be used to escape from natex syntax, allowing any characters inside the quotes to be interpreted as a literal. The above term matches 'Hello there!' exactly.
`she said "hi" 3 times!`
If you want to use quotes as part of the literal, wrap literal in `` instead.
Disjunction
'{hello there, hi}'
matches a substring containing exactly one term inside {}
, in this case
"hello there" and "hi" both match.
Conjunction
'<bob, hi>'
matches a substring that contains at least all terms inside <>
,
in this case, "hi bob" and "oh bob well hi there" both would match, but not
"hi"
Flexible sequence
'[hi, bob, how, you]'
matches as long as the substring contains all terms inside []
,
and the terms are ordered properly within the utterance. Matches
in the example include "hi bob how are you", but not "how are you
bob". Note that this expression matches any amount of characters
before and after the requisite sequence.
Inflexible sequence
'[!how, are, you]'
matches an exact sequence of terms with no words inserted between terms. The only utterance matching the example is "how are you". This construct is helpful with nested constructs inside of it that require an exact ordering, with no extra characters between each element.
Negation
'[!i am -bad]'
prepend -
to negate the next term in the expression. The example
will match any expression starting with "i am" where "bad" does NOT
follow. Note that the scope of the negation extends to the end
of the substring due to limitations in regex.
Regular expression
'/[A-Z a-z]+/'
substrings within //
define a python regex directly.
Nesting
'[!{hi, hello} [how, weekend]]'
would match "hi how was your weekend", "oh hello so how is the weekend going", ...
Variable assignment
'[!i am $f={good, bad}]'
using $var=
will assign variable var
to the next term in
the expression. The variable will persist until overwritten,
and can be referenced in future NLU or NLG expressions.
The example would match either "i am good" or "i am bad", and
assigns variable "f" to either "good" or "bad" depending
on what the user said.
Variable reference
'[!why are you $f today]'
using $
references a previously assigned variable. If no such
variable exists, the expression as a whole returns with no match.
The example would match "why are you good today" if f="good"
,
but would not match if f="bad"
Macros
Macros define arbitrary functions that can run within NatexNLU or NatexNLG evaluation. Create a Macro as follows:
from emora_stdm import Macro
class MyMacro(Macro):
# optionally, define constructor if macro needs access to additional data
def __init__(self, x):
self.x = x
# define method to run when macro is evaluated in Natex
def run(self, ngrams, vars, args):
question_natex
return ' '.join(['hello ' + args[0]] * self.x)
from emora_stdm import NatexNLU
if __name__ == '__main__':
natex = NatexNLU('[!oh #MyMacro(there) how are you]', macros={'MyMacro': MyMacro(2)})
assert natex.match('oh hello there hello there how are you')
NatexNLG
NatexNLG objects work very similarly to NatexNLU objects, but they are used to create a response string instead of match a user utterance.
from emora_stdm import NatexNLG
natex = NatexNLG('[!{this, here} is a {example, test}, `, testing! 1, 2, 3...`]')
print(natex.generate())
The above example might print "this is a test, testing! 1, 2, 3..."
Options (disjunctions) in a NatexNLG will result in one of the set of options to be selected to generate the response.
Some constructs (e.g. conjunction, negation) don't make sense in NatexNLGs. Here is the full list of supported constructs for NatexNLGs:
- literal
- rigid sequence [!...]
- disjunction {...}
- variable reference $var
- variable assignment $var=...
- macro call #MACRO(...)
All the above constructs share the same syntax as the NatexNLU syntax.
Built-In Macros
Ontology reference
#NER(ner_tag)
runs SpaCy Named Entity Recognizer to tag the user utterance, and returns a set representing all named entities present in the user utterance. Optionally, a ner_tag from the below set of tags can be provided to filter by entity type.
PERSON, NORP, FAC, ORG, GPE, LOC, PRODUCT, EVENT, WORK_OF_ART, LAW, LANGUAGE, DATE, TIME, PERCENT, MONEY, QUANTITY, ORDINAL, CARDINAL
https://spacy.io/api/annotation
#GATE(var1, var2, ...)
records the values of the provided variables, and returns True
if that set of variable:value
pairs has not yet been recorded while taking the transition. If the transition is evaluated
with the specified variable signature matching a previously recorded one, False
is returned.
Note that using no arguments, #GATE()
, will avoid the transition being taken more than once
regardless of variable values.
Optionally, an argument can be written of the form variable:value
.
This notation requires variable
to be set to value
for the macro to return True
.
#ONTE(ontology_node_1, ontology_node_2, ...)
gets all expressions of all nodes that are ontology descendents of the nodes provided as arguments, and returns them as a set of strings.
#KBQ(node, relation1, relation2, ...)
defines a knowledge base traversal starting at node
,
and traversing relations labeled relation1
, then relation2
, and so on. All nodes that can be reached
by the specified relation path from node
are returned as a set of strings.
#EXP(node)
returns the set of all expressions associated with a node.
#NOT(term1, term2, ...)
returns False
if any term string matches any ngram of the user utterance,
True
otherwise.
#U(set_or_str_1, set_or_str_2, ...)
returns a set representing the union of all arguments. String arguments are converted to a set containing the string as a single element.
#I(set1, set2, ...)
returns a set representing the intersection of all arguments.
#ALL($var1=val1, $var2=val2, ...)
returns True
if all variables are set to their provided values,
where each argument is a string of the form $var=val
#ANY($var1=val1, $var2=val2, ...)
returns True
if any of the variables are set to their provided values,
where each argument is a string of the form $var=val
#EQ(arg1, arg2, ...)
returns True
if all arguments are equal, False
otherwise
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