Writing a Conversational User Interface Library - Full Series
MiguelMJ
Posted on December 10, 2020
For the last months, I've been writing this series on the development of JTASCHE (Java Text Adventure and Simple Chatbot Engine). This post is meant to merge all the chapters. I don't expect anyone to read it all... maybe someone will find a cool idea or some inspiration, but the real purpose to publish it is to unify this journal in a single file.
Table of contents
- 1. The idea
- 2. The design
- 3. Regular Expressions for I/O
- 4. Scripting Language for Inner State
- 5. Structures
- 6. Serialization of the dialogue flow
- 7. Variables and Placeholders
- 8. Adapted Regular Expressions
- Closing the project
1. The idea [TOC]
One of the things that caught my attention before I started studying Computer Science were chatbots. I'd always loved the idea of speaking to machines, but the quality of real chatbots obviously wouldn't be up the incredible AIs of sci-fi movies.
When I learnt the two main approaches to chatbot-like applications used today, machine learning based and rule based, I knew I had the spirit but lacked the skills to follow the first one. Therefore, I did my research on the second one and found AIML.
Yet, as time passed, I started to become more and more interested in developing my own tool, rather than the chatbot itself. I wanted to make something at least as powerful as AIML and hopefully better.
After a year or two, between studies and other projects, I managed to finish the first version of TASCHE (link below), a library to design dialogue flows in JSON, a custom format for the patterns and a custom pseudolanguage to modify its internal state. It was not as great as my first-year-in-uni self would dream, but it worked and was definitely set on the right path.
As I was still learning during the process, it suffered a lot of transformations. It's enough to say that the first pattern parser was written from scratch in several thousand lines of code, before being replaced by a more legible Flex + Bison version. I wrote it in C++ because its my main language and I needed to focus on the structures and algorithms. Now, five years after the first draft, I've chosen Java to rewrite it and try to improve it in the process.
I'll keep this series to explain the internals of TASCHE and its evolution. I think my first-year-in-uni self will enjoy it.
2. The design [TOC]
Before we properly start to code, we must define the requisites of the project to have a general understanding of what we have to implement and how we plan to do it.
General description
The Conversational Interface Library will provide the user with a Conversational User Interface (CUI from now) class. A CUI must be able to load a dialogue flow specified by the user and answer their input according to it, modifying its internal state if it's necessary. It can be thought of as an automaton.
Requisites
Input
When we think about user input, we have to always assume that we won't consider all the possibilities. Anyways, we want to consider as many as possible in the shortest specification we can.
The most powerful tool we have to do this are regular expressions. But, as regular expressions can sometimes be a little too complicated, we will think about creating a simpler format, easier for the user, that translates underneath to a regular expression.
Output
If we want a chatbot to feel as natural as possible, diversity of answers is a must. For this we will not only use a list of possible expressions to randomly choose from, but we will also group many different answers with little variations in the same expression.
Again, we can use regular expressions to generate strings. This is not their usual purpose, but there are libraries that allow as to do it.
Internal state
The internal state of the chatbot creates the context of the conversation, so for the same input, different output comes depending on what's been said earlier.
The most flexible and powerful way to contain and modify the internal state is to use an embedded scripting language.
Dialogue flow format
The dialogue flow then must associate input and state with a list of possible answers and state modifications. The ideal format would be one legible, without redundant information (except when it's for clarity) and customizable.
We will design a structure to contain the proper dialogue flow and use JSON to store it.
Synopsis
From all we've said, the following specifications are extracted:
We will use
regular expressions for input matching.
regular expressions for output generation.
optional simplification of regular expressions for the user.
scripting language for internal state representation and modification.
custom data structure to associate input, state and output.
JSON to store such structure.
The first implementation I did in C++ (see Part 1 of this series) used its own version, built from scratch, of most of these features. But this time I'll find out what Java libraries I can use for the same purpose, because once you've reinvented the wheel in order to learn (which is a noble cause), you should use professionally built, tested and maintained wheels. That will reduce the effort you need to build, test and maintain your project.
3. Regular Expressions for I/O [TOC]
In the last post we defined the requisites of the project. I started in order and began with the input and output based on regular expressions.
Regular expressions in Java
Regular expressions are supported in Java with the package java.util.regex. Its usage is pretty straightforward for the pattern matching, but does not support string generation.
As usual, someone had already asked what I needed to know in stackoverflow, and thus I found the library Generex, a Java library for generating String from a regular expression.
Setting up the project
Almost always I prefer to work from the terminal. I strongly believe that being able to manage your code without an IDE gives you better understanding of the underlying processes of compiling and debugging. Still, I am not going to refuse the facility of an IDE if what I care about is that the project moves forward.
At first, I tried to build Generex from source, but I'm not familiar with this process in Java and it looked like more effort than it was worth, so I decided to go with Maven.
I tried to use Maven from the command line. I read some tutorials and got a Hello World compiled, but again I had problems using the dependencies for the real project.
What I had to do was clear; I didn't switch from C++ to Java to complicate my life, so I launched Eclipse, imported the Maven project(1)(2) and had Generex up and running in seconds.
A custom Pattern class
Once with my work environment ready, I created a Pattern
class. Initially I debated whether it was necessary to make a unified class for the input and output patterns, instead of a separate one for each, but I came to the conclusion that for now I needed simplicity and in the end there was not a big conceptual difference.
This class contained a java.util.regex.Pattern
for the matching and a Generex
for the generation. I was worried I was using more memory than necesary ,given that I won't be using them at the same time, but again, I followed this quote whose author I never remember:
Is easier to optimize clean code than to clean optimized code.
Testing
I have not used JUnit before, so I was glad to discover it's not a big deal. I prepared a single test to check that a simple Pattern
could generate different strings, and match them all as true.
The regular expression used for the test is:
(Hi|Hello), how are you( today)?\?
and everything went well, as the output shows ([OK]
means that the pattern matched the generated string).
Generated: Hi, how are you today?[OK]
Generated: Hello, how are you?[OK]
Generated: Hi, how are you today?[OK]
Generated: Hello, how are you?[OK]
Generated: Hi, how are you?[OK]
Generated: Hi, how are you today?[OK]
Generated: Hello, how are you today?[OK]
Generated: Hi, how are you today?[OK]
Generated: Hello, how are you?[OK]
Generated: Hello, how are you?[OK]
Conclusion
This was still the easy part and I didn't really expect the test to fail, but this kind of motivation is important, even in the beginning.
I decided to name this project JTASCHE, to make the difference with TASCHE. The code is available on GitHub.
4. Scripting Language for Inner State [TOC]
In the last post we made Pattern
, a class to recognize input and produce output. Now we'll make another one that let us interact with the inner state of the CUI.
As we decided during the design, we will contain and modify the inner state via an embedded scripting language. Java supports several scripting languages and for this project we'll be using Jython.
Jython
As its official page says, Jython is a Java implementation of Python that combines expressive power with clarity. Its advantages are that it's super easy to embed in Java and the simplicity of the Python language. The main downside is that the last Python supported version is the 2.7, which is not currently mantained. As this is a hobby project, I won't take that on count, but in a different case I would probably consider another option (e.g. I'd like to embed Lua in the original TASCHE).
Embed it to the project
The normal version of Jython requires it installed in your machine, but there is a stand-alone version which runs on its own and can be added as a simple Maven dependency (as we did with Generex in the last part). We'll be using that one.
Script class
In our library, there are two main purposes for the Script
class:
Check a condition against the inner state.
Modify the inner state.
So the structure of this class is pretty straightforward. We have:
A static reference to the
PythonInterpreter
that contains the inner state.A
String
that contains the code of the script.A function to evaluate it as a boolean (with the Jython
__nonzero__
function).A function to simply execute the code.
Testing
// A SUCCESSFUL TEST
Script[] scripts = new Script[10];
Script.pyMachine.exec("a = 5; b=3; c='hola'");
// this should eval true
scripts[0] = new Script("a == 5");
scripts[1] = new Script("b ==3");
scripts[2] = new Script("c[b] == 'a'");
scripts[3] = new Script("'0'");
scripts[4] = new Script("1");
// this should eval false
scripts[5] = new Script("a==b");
scripts[6] = new Script("h=4;False");
scripts[7] = new Script("c[0]=='o'");
scripts[8] = new Script("0");
scripts[9] = new Script("''");
boolean ok = true; int i=0;
for(Script s: scripts) {
boolean ev = s.evaluate();
ok &= i++ < 5 == ev;
}
As this class is mainly a wrapper of Jython's PyCode
, there was little to test but the basic functionality. The only thing worth mentioning is that, as intuitive as it may sound, the state of the PythonInterpreter
object persists between different Scripts
executions and evaluations.
Note that if, in the future, we wanted to have different Conversational Interfaces running with different inner states (be it sequentially or concurrently), we would have to set the static instance before executing/evaluating any script.
Conclusion
Now with our Pattern
and Script
classes we have the basic building blocks to define a structure that associates input and conditions to output and state changes. From now we won't rely much more in third-party libraries (except Gson, which I'll explain).
After we have this structure, we will be able to write dialogue flow examples to test some new features like patterns modifying the inner state and possibly the regex simplification we planned during the design.
Don't forget to check the repository for the code!
5. Structures [TOC]
The classes we've got right now are Pattern
, for matching input and producing output, and Script
for checking and modifying the inner state of the CUI. With these two, we want to make a structure that:
- Receives user input.
- Matches it against a pattern.
- Checks a condition in the inner state.
- If the input matches and the condition is satisfied, it either:
- a) Produces some output and executes a change in the state.
- b) Processes the input further until it gets to produce an output or discard the response.
Some notation
- We will call question to the user input, that the
Response
tries to match. - Given a question, a
Response
is valid when the question matches the input pattern and the condition is satisfied.
The `Response` class
We'll make a base Response
class, which performs the first three steps and SimpleResponse
and RecursiveResponse
, that derive from it and implement an answer
function, respectively for a options a) and b).
Note that the return type of the answer
function is an Optional
, because if the question
is not valid, the function should not return anything.
Valid responses
public boolean isValid(String question) {
return (input == null || input.matches(question)) &&
(condition == null || condition.evaluate());
}
We will use null input patterns for responses that should adapt to any question and null conditions for responses that should not depend on the inner state.
Simple response
The algorithm that SimpleResponse
uses to answer a question is:
public Optional<String> answer(String question) {
Optional<String> ans = Optional.empty();
if(isValid(question)){
ans = Optional.of(output.generate());
if(execute != null) execute.execute();
}
return ans;
}
The execute
script doesn't need to be present, but the output pattern can't be null, as something needs to be returned, even if it's an empty string.
Recursive Response
The algorithm used by a RecursiveResponse
, instead, is:
public Optional<String> answer(String question) {
Optional <String> ans = Optional.empty();
if(isValid(question)) {
if(new_question != null) {
question = new_question;
}
for(Response response : responses) {
ans = response.answer(question);
if(ans.isPresent()) break;
}
}
return ans;
}
In this case, the first sub-response able to answer the question will be the only one returned. This could be tweaked later, to enable recursive responses that append all possible answers, but for now we'll leave it this way.
The `Module` class
We may want a default value for certain variables the first time we check a condition or define some useful functions to avoid repeating code. The Module
class will be used to group a set of responses that can be related or use the same variables of the inner state, and also include a initialization script to run before any of its Response
s is used.
The answer
method behaves the same way as the one from RecursiveResponse
.
The `CUI` class
At last, we can create the CUI class, which is no more than a collection of Module
s and a PythonInterpreter
to set the static reference of the Script
, which we explained in the last part.
The answer
function in this class doesn't return a Optional
because defaults any response to an empty string, and appends the result of calling answer
on every one of its modules when they don't return an empty Optional
.
Conclusion
Now we have the structures and the logic necessary for the basic functionality of our library! The following step to take will be to implement the serialization and deserialization of these structures, which will be done to a JSON format via the GSON library.
The real code is on GitHub, if you want to check it and star the project if you like it!
6. Serialization of the dialogue flow [TOC]
In the last post we defined the structures which contain the logic and data for the basic behaviour of a Conversational User Interface, which were SimpleResponse
, RecursiveResponse
, Module
and CUI
. But unless we want to hard code their content in every application, we need to serialize and deserialize them.
GSON
We are going to store our data in JSON format, so we'll make use of the GSON a Java serialization/deserialization library to convert Java Objects into JSON and back, devolped by Google. As we did before with Generex and Jython, we just have to add the dependency to the pom.xml
file of our Maven project and it will be ready to use.
GSON is a flexible and powerful library that could take more than one post to explain. Honestly, I didn't dive much into it, so I'm pretty sure there are better ways to do what I'm about to explain, but my task was not that complicated, so this solution is still flexible and open to future adaptations.
Intermediate classes for serialization
Due to their complexity, our Response
and Module
classes can't be serialized directly by GSON, so the simplest way I came up with to deal with that was to make a serializable version of each one (SerializableResponse
and SerializableModule
) as an intermediary.
`SerializableResponse`
This class just holds the String
version of all possible attributes from each child of Response
, which are:
class SerializableResponse{
public String input; // both
public String output; // SimpleResponse
public String condition; // both
public String execute; // SimpleResponse
public String new_question; // RecursiveResponse
public List<SerializableResponse> responses; // RecursiveResponse
public Response getResponse(){...}
}
Java to JSON
The Response
class needs a new abstract function SerializableResponse serializable()
that will be implemented for each child and only has to fill each attribute of the serializable calling toString()
.
Note that:
In the case of the
Script
s,PyCode
from Jython doesn't keep the code string, so we have to modify our class to do it in order to return it in itstoString
function.In the
RecursiveResponse
attributeresponses
this is a recursive call.
Now to serialize a Response
we only need to do:
jsonString = gson.toJson(myResponse.serializable());
JSON to Java
Now we use the SerializableResponse
kind of like a factory, with a function Response getResponse()
. The only thing we have to do to discern wehter to return a SimpleResponse
or a RecursiveResponse
is:
// SerializableResponse getResponse
if (this.output != null){ // SimpleResponse (we allow this.execute to be null)
// build a SimpleResponse with the string attributes
// and return it
}else if(this.responses != null){ // RecursiveResponse (we allow new_question to be null)
// build a RecursiveResponse with the string attributes
// and return it
}else{
// error
}
And so, to deserialize a Response
we only have to:
Response myResponse = gson(jsonString ,SerializableResponse.class).getResponse();
`SerializableModule`
As you may be already expecting, this class is just a list of SerializableResponse
s and a single additional String
for the initialization script.
class SerializableModule{
public String init;
public List<SerializableResponse> responses;
}
And the remaining logic to serialize and deserialize is similar to the explained previously.
Load and save a `CUI`
With the logic to convert Modules
to JSON and back, the function to load and save modules would take just a few lines. The only thing we still cannot load nor store yet would be the inner state, so for now our conversational applications won't keep any memory between sessions.
Let's see a basic example
{
"init":"greeted=False",
"responses":[{
"input":"(hello|hi)!*",
"responses":[{
"condition":"not greeted",
"output":"Hi(, traveler)?",
"execute":"greeted = True"
},
{
"output":"Hello(, again|there)"
}]
}]
}
Possible exchange:
User: hi!!
Bot: Hi, traveler
User: hello
Bot: Hello there
user: hello!!!
Bot: Hello, again
Conclusion
Finally we have covered what's necessary to define functional dialogue flows and test new features. From now on, all we'll do is extend what we have, because as the example shows, the scope of what this library offers is very limited compared to what we can still make.
The next step to take is to implement variables, so we can access and temporally modify the inner state directly from the Pattern
class, in order to interpret the user input more intelligently. For this, we I will be explaining more advanced features of the regular expressions in Java.
You can check the code in GitHub, give it a star if you like it and see the documentation in my new website.
7. Variables and Placeholders [TOC]
We already have a working chatbot engine, but as we saw in the example of the last post, it's not very powerful. Now we are going to link the pattern matching and the inner state so we can make more specific checks on the user's input.
To do this we will have to make some preprocessing on the regular expressions we use, and even regenerate them several times during a session. We will be making really heavy use of regular expressions, so be prepared.
Note: In this post the word pattern can refer to different things, so before anything I want to make clear what it means depending on the format I use:
Pattern, with capital P, refers to our custom class Pattern, that we defined in Part 3.
java.util.regex.Pattern refers to the native class of Java.
pattern
refers to the java.util.regex.Pattern contained as an attribute in our custom Pattern class.
Regex Named Capturing Groups in Java
Both for the preprocessing and for the inner state interaction, we need to handle this concept at least in a basic level. I won't dive much more than needed in it, so here we go.
In a java.util.regex.Matcher
you can capture a specific part of your string using a regular expression, and furthermore, name it. The syntax for it, inside the regex, is the following:
(?<name>subregex)
so the following code
String regex = "I am (?<age>[0-9]+) years old";
String str = "I am 23 years old"
Matcher m = java.util.regex.Pattern.compile(regex).matcher(str);
if(m.matches())
System.out.println(m.group("age"));
will output:
23
Backreferencing
You can also use capturing groups in the replace function, to replace the content of the string recycling the very match. To do this, you must use ${identifier}
in the replace string:
String regex = "I (?<word>[a-zA-Z]+)";
String str = "I write, I code, I learn";
Matcher m = java.util.regex.Pattern.compile(regex).matcher(str);
String result = m.repaceAll("We ${word}");
System.out.println(result);
This code outputs:
We write, We code, We learn
Now we are ready to face the new features of our library.
Variables and placeholders
This is the way we will make use of these terms when talking of Patterns:
-
Variable: They are read-only parts of the Pattern, that match/generate the correspondent value of the inner state. We will note them in our Patterns with a dollar sign:
$identifier
, where the identifier follows the lexical rules of the identifiers in C-families - Don't mistake this with the${identifier}
I mentioned before, which works for the replace functions of the javaMatcher
, this is a construct of our own. The need of Pattern regeneration comes from these, because they change the strings recognized and generated.
Example: If we had in our inner state a variable flavour = coffee
, then the Pattern I like $flavour
would only match/generate I like coffee
.
- Placeholder: They are the parts of the pattern that store the matched value in the inner state. As you can imagine, we'll use the capturing groups for them.
Example: If the CUI uses this response
{
"input":"my name is (?<name>[a-Az-Z])",
"output":"hello $name!"
}
then the response to my name is Miguel
will be hello Miguel!
Implementation
The former implementation of Pattern we just had a java.util.regex.Pattern pattern
and a Generex generator
. Now, we may want to regenerate them before its use; let's see what are the conditions:
For output generation, the placeholders will be trated as variables (their difference is only notable when matching input).
This means that the
pattern
must be regenerated if the Pattern contains variables. Thegenerator
, furthermore, must be regenerated if the Pattern contains variables or placeholders.We need to add to our Pattern class the attributes
List<String> variables
,List<String> placeholders
,String inputTemplate
andString outputTemplate
. These last two will be used for regeneration.
Preprocessing the string to build a Pattern - I used the regex to preprocess the regex
Now, instead of building the pattern
and the generator
directly from the regex string (here we'll call it str
), we have to:
- Find the placeholders
String phPattStr = "\\(\\?<(?<id>[^>]*)>\\([^)]*\\)[^)]*\\)";
java.util.regex.Pattern phPatt = java.util.regex.Pattern.compile(phPattStr);
Matcher phFinder = phPatt.matcher(str);
while(phFinder.find()) {
placeholders.add(phFinder.group("id"));
}
- Find the variables
String varPattStr = "\\\\\\$(?<id>[a-zA-Z][a-zA-Z0-9]*])";
java.util.regex.Pattern varPatt = java.util.regex.Pattern.compile(varPattStr);
Matcher varFinder = varPatt.matcher(str);
while(varFinder.find()) {
variables.add(varFinder.group("id"));
}
- Set the templates for regeneration (remember that placeholders behave like variables in the output)
outputTemplate = phFinder.replaceAll("\\\\\\$${id}");
inputTemplate = str;
- Initialize the
pattern
andgenerator
in case they won't be needing regeneration:
if(variables.isEmpty()) {
pattern = java.util.regex.Pattern.compile(inputTemplate);
if(placeholders.isEmpty()) {
generator = new Generex(outputTemplate);
}
}
Pattern regeneration - Variable replacement
First of all, we'll make a static class called RegexAdapter
(that we'll extend in the following chapter) which, for now, will contain a single function replaceVariables
:
public static String replaceVars(String expr) {
String varPattStr = "\\\\\\$(?<id>[a-zA-Z][a-zA-Z0-9]*])";
java.util.regex.Pattern varPatt = java.util.regex.Pattern.compile(varPattStr);
Matcher matcher = varPatt.matcher(expr);
while(matcher.find()) {
PyObject pyValue = Script.pyMachine.get(matcher.group(1));
String value = pyValue == null? "" : pyValue.asString();
expr = matcher.replaceFirst(value);
matcher.reset(expr);
}
return expr;
}
Here we used the same regular expression as before to build varPatt. We could store it in a final static attribute in the RegexAdapter
to reuse it, instead of rewrite it each time.
In Matching
We have to make two main changes in the matching function:
- Now we have to check if we use the
pattern
or a new one we generate from theinputTemplate
:
java.util.regex.Pattern localPatt;
if(pattern != null){
localPatt = pattern;
}else {
String recognizerStr = RegexAdapter.remplaceVars(inputTemplate);
localPatt = java.util.regex.Pattern.compile(recognizerStr);
}
- Then, when it matches, update inner state if the pattern contains placeholders:
java.util.regex.Matcher matcher = localPatt.matcher(str);
boolean match = matcher.matches();
if(match)
for(String ph: placeholders) {
String value = matcher.group(ph);
if(!ph.isEmpty())
Script.pyMachine.set(ph, value);
}
In Generation
In the generation function there is only a change needed, as we don't have to modify the inner state.
- We have to check if we use the
generator
or a new one we generate from theoutputTemplate
:
Generex localGen;
if(generator != null) {
localGen = generator;
}else{
String generatorStr = RegexAdapter.remplaceVars(outputTemplate);
localGen = new Generex(generatorStr);
}
Conclusion
That's it, we have implemented variables in our chatbot engine. It is beginning to be obvious that the input and output patterns should be separated in different classes. Anyways, if I do those changes, I won't document them here.
There is something we must take on count when using placeholders: the modification of the inner state occurs independently of the validity of the response it belongs to. This means that a response could have an invalid condition, but the mere check of the input could modify the inner state. For now we have to rely on the common sense of the user to make an intelligent use of variables and that is not a very good idea. We will have to implement a scoping system for this modifications sometime in the future .
Anyways, the next chapter will be a special one. Even though it will be a part of this series, I intend it to be readable by its own. We will be extending the class RegexAdapter
, to offer to the user the option to use normal regular expressions or a version we'll craft to simplify the most common uses.
8. Adapted Regular Expressions [TOC]
The regular expressions that we will use in our library are mostly to process controlled natural language, so we are going to make an adapted version of them. We will have to give up some of the potential of regular expressions to gain usability for the most common cases in our library.
Note: We are going to use regular expressions to process regular expressions, so they can get a little confusing. You may want to check out my post on Correctly escaping regular expressions
Features
The Adapted Expressions (this is how I will be calling this adapted version of regular expressions) have the following features and syntax:
Optional parts: They will be enclosed between squared brackets
[]
and may be omitted.one two[ three]
recognizes bothone two
andone two three
.Eligible parts: They will be enclosed between parenthesis and separated by bars, and may be interchanged.
(one|two|three)
will recognizeone
,two
orthree
Word placeholder: They are used to recognize one or more words and store them in the inner state. The syntax is
@>id[quant]
for[quant]
words stored in a group namedid
.[quant]
can be any of the usual quantifiers of regular expressions in Java: this is*
,+
,{n}
or{min,max}
. For example,You can call me @>fullname{1,3}
will recognizeYou can call me Jon Doe
or any other name with one word minimum and three maximum.Number placeholder: They are used to recognize one or more numbers and store them in the inner state. The syntax is
#>id[quant]
, with a similar behavior to the word placeholders.Variables: They are used to represent the content of a variable of the inner state. The syntax is
$id
.
Note: Placeholders and variables refer to the same concepts explained in the last post.
Here's a table with the equivalences:
Adapted Expression | Regular Expression |
---|---|
[text] | (text)? |
(a|b|c) | (a|b|c) |
@>id | (?<id>\w+ ?) |
@>id{n} | (?<id>(\w+ ?){n}) |
#>id | (?<id>\d+ ?) |
#>id{n} | (?<id>(\d+ ?){n}) |
$id | $id |
Note: $id
variables doesn't belong to Regular Expressions, but to the extension we made in the last post.
RegexAdapter class
In the previous we created this class to make a function to replace the variable names with the associated content in the inner state. Now we will add a new function to adapt the string of a Adapted Expression to a Regular Expression. It is very important to have clear that the reserved characters of the Adapted Expressions are not the same as in the Regular Expressions. For this reason, the first step of this transformation is to escape the characters with special meaning in a Regular Expression that are present in our Adapted Expression. This means that we have to assume that those characters are going to be escaped when we process them, and change that if necessary.
We are going to need the definition of certain constants.
// The characters reserved in the Regular Expressions for which we don't want a
// special meaning
final static private char[] reserved = {'?', '^', '.', '$', '[', ']'};
// The strings used to build the regex that contain common concepts in our expressions
final static private String id = "[a-zA-Z_]\\w*";
final static private String num = "\\d+";
final static private String print = "\\\\w+";
final static private String quant = "\\{\\d+,\\d*\\}|\\+|\\*";
// The regular expressions that we will use to make the transformation
final static private java.util.regex.Pattern optional_open
= java.util.regex.Pattern.compile("\\\\\\[");
final static private java.util.regex.Pattern optional_close
= java.util.regex.Pattern.compile("\\\\\\]");
final static private java.util.regex.Pattern alphaplaceholder
= java.util.regex.Pattern.compile("\\@>(?<id>"+id+")(?<quant>"+quant+")?");
final static private java.util.regex.Pattern numplaceholder
= java.util.regex.Pattern.compile("\\#>(?<id>"+id+")(?<quant>"+quant+")?");
final static public java.util.regex.Pattern variable
= java.util.regex.Pattern.compile("\\\\\\$(?<id>"+id+")");
With this constants defined, we can define the function to escape the Regular Expressions:
static private String quoteRegex(String regex){
for(char ch: reserved){
regex = regex.replaceAll("\\"+ch, Matcher.quoteReplacement("\\"+ch));
}
return regex;
}
And finally we can define the function to make the translation using replacing with backreferencing:
static public String adapt(String expr){
Matcher matcher;
matcher = optional_open.matcher(expr);
expr = matcher.replaceAll("(");
matcher = optional_close.matcher(expr);
expr = matcher.replaceAll(")?");
matcher = alphaplaceholder.matcher(expr);
expr = matcher.replaceAll("(?<${id}>("+print+" ?)${quant})");
matcher = numplaceholder.matcher(expr);
expr = matcher.replaceAll("(?<${id}>("+num+" ?)${quant})");
return expr;
}
Example
Now, instead of writing a response like this:
{
"input": "Remind((er| me)? to)? (?<action>(\w ?)+) on (?<day>\w+)",
"output": "I will you to $action on $day"
}
We can write it like this:
{
"input": "Remind[[er| me] to] @>action+ on @>day",
"output": "I will remind you to $action on $day"
}
Conclusion and revision
Now we could add an option on each module or even each response that lets the user choose to either use a Regular Expression or an Adapted Expression, and use this function to transform these to those.
Since we had our first functional version, we have added_
The possibility to read/write the inner state during the input matching and output generation.
A simplified yet extensible version of the regular expressions for the user.
This leaves us with the following issues:
We still have to make a scoping system to control the modifications made during a match that was finally not successful.
Add some options to the Pattern deserialization, to choose between Regular or Adapted expressions.
As those are tweaks, more than essential features, I will document them in a post about the final tweaks to the library. For now, the next post will be about adding knowledge to our chatbots. We will add a feature to let the user to specify sets of words under concept categories.
Closing the project [TOC]
That final post didn't came out. I didn't have the time to program the last part and I honestly didn't want to dedicate that much energy to a side project, specially one that is already effectively functional and is intended for other hobby projects.
This project has been fun. If you have read all, I hope you have extracted some value... if not, I can't blame you. For me, this was what I needed to start blogging and an excuse to revisit an old ambition. If I ever come back to work with JTASCHE, I highly doubt I'll write about it, but who knows.
Posted on December 10, 2020
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