This article was published as a part of the Data Science Blogathon
This article is part of an ongoing blog series on Natural Language Processing (NLP). From this article, we will start our discussion on Regular Expressions. When a data scientist comes across a text processing problem whether it is searching for titles in names or dates of birth in a dataset, regular expressions rear their ugly head very frequently.
They form part of the basic techniques in NLP and learning them will make you a more efficient programmer. Therefore, Regular Expression is one of the key concepts of Natural Language Processing that every NLP expert should be proficient in.
So, In this article, we will see all the necessary concepts related to Regular Expressions and also discuss important functionalities related to Regular Expressions.
This is part-13 of the blog series on the Step by Step Guide to Natural Language Processing.
1. What are Regular Expressions?
2. How Do Regular Expressions Work?
3. What are the Properties of Regular Expressions?
4. How can Regular Expressions be used in NLP?
5. The concept of Raw string in Regular Expressions
6. Common Regex Functions used in NLP
7. Basics in Regular Expressions
8. What are Anchors?
9. What are Quantifiers?
10. Whitespace, Pipe Operator and Wildcard Character
11. Escaping Special Characters
12. Character Sets and Meta Sequences
Regular expressions or RegEx is defined as a sequence of characters that are mainly used to find or replace patterns present in the text. In simple words, we can say that a regular expression is a set of characters or a pattern that is used to find substrings in a given string.
A regular expression (RE) is a language for specifying text search strings. It helps us to match or extract other strings or sets of strings, with the help of a specialized syntax present in a pattern.
For Example, extracting all hashtags from a tweet, getting email iD or phone numbers, etc from large unstructured text content.
Sometimes, we want to identify the different components of an email address.
Image Source: Google Images
Simply put, a regular expression is defined as an ”instruction” that is given to a function on what and how to match, search or replace a set of strings.
Regular Expressions are used in various tasks such as,
Let’s understand the working of Regular expressions with the help of an example:
Consider the following list of some students of a School,
Names: Sunil, Shyam, Ankit, Surjeet, Sumit, Subhi, Surbhi, Siddharth, Sujan
And our goal is to select only those names from the above list which match a certain pattern such as something like this S u _ _ _
The names having the first two letters as S and u, followed by only three positions that can be taken up by any of the letters present in the dictionary. What do you think, which names from the above list fit this criterion?
Let’s go one by one, the name Sunil, Sumit, and Sujan fit this criterion as they have S and u in the beginning and three more letters after that. While the rest of the three names are not following the given criteria. So, the new list extracted is given by,
Extracted Names: Sunil, Sumit, Sujan
What exactly we have done here is that we have a pattern and a list of student names and we have to find the name that matches the given pattern. That’s exactly how regular expressions work.
In RegEx, we have different types of patterns to recognize different strings of characters.
Some of the important properties of Regular Expressions are as follows:
1. The Regular Expression language is formalized by an American Mathematician named Stephen Cole Kleene.
2. Regular Expression(RE) is a formula in a special language, which can be used for specifying simple classes of strings, a sequence of symbols. In simple words, we can say that Regular Expression is an algebraic notation for characterizing a set of strings.
3. Regular expression requires two things, one is the pattern that we want to search and the other is a corpus of text or a string from which we need to search the pattern.
Mathematically, we can define the concept of Regular Expression in the following manner:
1. ε is a Regular Expression, which indicates that the language is having an empty string.
2. φ is a Regular Expression which denotes that it is an empty language.
3. If X and Y are Regular Expressions, then the following expressions are also regular.
4. If a string is derived from the above rules then that would also be a regular expression.
In NLP, we can use Regular expressions at many places such as,
1. To Validate data fields.
For Example, dates, email address, URLs, abbreviations, etc.
2. To Filter a particular text from the whole corpus.
For Example, spam, disallowed websites, etc.
3. To Identify particular strings in a text.
For Example, token boundaries
4. To convert the output of one processing component into the format required for a second component.
Now let’s discuss a crucial concept which you must know while studying Regular Expressions. On the basis of your prior knowledge of Python Programming language, you might know that Python raw string treats backslash() as a literal character.
To understand this thing, let’s look at the following example:
In the following example, we have a couple of backslashes present in the string. But in string python treats n as “move to a new line”.
After seeing the output, you can observe that n has moved the text after it to a new line. Here “nayan” has become “ayan” and n disappeared from the path. This is not what we want.
So, to resolve this issue, now we use the “r” expression to create a raw string:
Again after seeing the output, we have observed that now the entire path has printed out here by simply using “r” in front of the path.
Therefore, It is always recommended to use raw string instead of normal string while dealing with Regular expressions.
To work with Regular Expressions, Python has a built-in module known as “re”. Some common functions from this module are as follows:
Let us look at each function with the help of an example:
This function helps us to detect whether the given regular expression pattern is present in the given input string. It matches the first occurrence of a pattern in the entire string and not just at the beginning. It returns a Regex Object if the pattern is found in the string, else it returns a None object.
Syntax: re.search(patterns, string)
Within search functions, we can use different flags to perform specific operations. For Example,
‘re.I’ — to ignore the case (either uppercase or lowercase) of the text 're.M' — enables to search the string in multiple lines re.search(pattern, string, flags=re.I | re.M)
In the following example, we search for the pattern “founder” in a given string
This function will only match the string if the pattern is present at the very start of the string.
Syntax: re.match(patterns, string)
In the following example, we match a word at the beginning of the string:
Here Pattern = ‘Analytics’ and String = ‘Analytics Vidhya is the largest data Scientists community’. Since the required pattern is present at the beginning of the string we got the matching Object as an output. And we know that the output of the re.match is an object, so to get the matched expression, we will use the group() function of the match object.
As we can observe that we have got our required output using the group() function. Now let us have a look at the other example which presents the second case:
Here as you can notice, our pattern(Scientists) is not present at the beginning of the string, hence we got None as our output.
This function is used to substitute a substring with another substring.
Syntax: re.sub(patterns, Substitute, Input text)
In the following example, we replace xxx and yyy with abc in the given string:
This function stores the regular expression pattern in the cache memory for faster searches. So, we have to pass the regex pattern to re.compile() function.
Syntax: re.compile(patterns, repl, string)
This function will return all the occurrences of the pattern from the string. I would recommend you to always use re.findall(). It can work like both re.search() and re.match(). Therefore, the result of the findall() function is a list of all the matches
Syntax: re.findall(patterns, string)
Let’s now discuss some of the basics used in Regular Expressions:
They are used to specify a disjunction of characters.
For Examples,
/[cC]hirag/ → Chirag or chirag /[xyz]/ → ‘x’, ‘y’, or ‘z’ /[1234567890]/ → any digit
Here slashes represent the start and end of a particular expression.
They are used to specify a range.
For Examples,
/[A-Z]/ → matches an uppercase letter /[a-z]/ → matches a lowercase letter /[0–9]/ → matches a single digit
They can be used for negation or just to mean ^.
For Examples,
/[ˆa-z]/ → not an lowercase letter /[ˆCc]/ → neither ‘C’ nor ‘c’ /[ˆ.]/ → not a period /[cˆ]/ → either ‘c’ or ‘ˆ’ /xˆy/ → the pattern ‘xˆy’
It marks the optionality of the previous expression.
For Examples,
/maths?/ → math or maths /colou?r/ → color or colour
Used to specify any character between two expressions.
For Examples,
/beg.n/ → Match any character between which fits between beg and n such as begin, begun
These are special characters that help us to perform string operations either at the beginning or at the end of text input. They are used to assert something about the string or the matching process. Generally, they are not used in a specific word or character but used while we are dealing with more general queries.
It specifies the start of the string. For a string to match the pattern, the character followed by the ‘^’ in the pattern should be the first character of the string.
It specifies the end of the string. For a string to match the pattern, the character that precedes the ‘$’ in the pattern should be the last character in the string.
For Examples,
^The: Matches a string that starts with ‘The’ end$: Matches a string that ends with ‘end’ ^The end$’: Exact string match (starts and ends with ‘The end’) roar: Matches a string that has the text roar in it.
Some common Quantifiers are: ( *, +, ? and { } )
They allow us to mention and control over how many times a specific character(s) pattern should occur in the given text.
Image Source: Google Images
For Example, Let’s in a given data, we have variations of the word ‘Program’ such as ‘Program’, ‘Programmed’, ‘Programmer’. Our goal is to find only those words where one or more occurrences of ‘e’ appearing in the word ‘Program’. So, to achieve our goal, we can use any of the following quantifiers to indicate the presence of a particular character.
Let’s discuss all the quantifiers one by one:
This quantifier matches the preceding character either zero or one time. Generally, It is used to mark the optional presence of a character.
This quantifier is used to mark the presence of the preceding character either zero or more times.
This quantifier matches the preceding character either one or more times. That means for the pattern to match the string, the preceding character has to be present at least once.
There are four variants of {m, n} quantifier. Let’s discuss each of them:
This quantifier matches the preceding character from ‘m’ number of times to ’n’ number of times.
This quantifier matches the preceding character from ‘m’ number of times infinite times, therefore, there is no upper limit on the occurrence of the preceding character.
This quantifier matches the preceding character from zero to ’n’ number of times, therefore, the upper limit is fixed for the occurrence of the preceding character.
This quantifier matches if the preceding character occurs exactly ’n’ number of times.
Each of the earlier mentioned quantifiers can be written in the form of {m,n} quantifier in the following way:
For Examples,
abc*: matches a string that has 'ab' followed by zero or more 'c'. abc+: matches 'ab' followed by one or more 'c' abc?: matches 'ab' followed by zero or one 'c' abc{2}: matches 'ab' followed by 2 'c' abc{2, }: matches 'ab' followed by 2 or more 'c' abc{2, 5}: matches 'ab' followed by 2 upto 5 'c' a(bc)*: matches 'a' followed by zero or more copies of the sequence 'bc'
A white space can include a single space, multiple spaces, tab space, or a newline character (also known as a vertical space). It will match the corresponding spaces in the string.
For Examples,
‘ +’, i.e. a space followed by a plus sign will match one or more spaces. ‘Chirag Goyal’ will allow you to look for the name ‘Chirag Goyal’ in any given string.
It’s denoted by ‘|’. It is used as an OR operator. We have to use it inside the parentheses.
For Example, Consider the pattern ‘(play|walk)ed’ –
The above pattern will match both the strings — ‘played’ and ‘walked’.
Therefore, the pipe operator tells us about the place inside the parentheses that can be either of the strings or the characters.
The ‘.’ (dot) character is also known as the wildcard character. It acts as a placeholder and can match any of the characters.
For Example, if a string starts with three characters, followed by two 0s and three 1s, followed by any four characters. Then, the valid strings that follow the above condition can be
cgh00111opqk, kgh00111pksr, etc.
The pattern that satisfies this kind of condition would be ‘.{3}0{2}1{3}.{4}’
You can also use ‘….00111..’ where the dot acts as a placeholder which means anything can sit in the place of the dot.
The characters which we discussed above in quantifiers such as ‘?’, ‘*’, ‘+’, ‘(‘, ‘)’, ‘{‘, etc. can also appear in the input text. So, In such cases to extract these specific characters, we have to use the escape sequences. The escape sequence, represented by a backslash ‘’, is used to escape the special meaning of the special characters.
It is used to escape the star
It is used to escape the dot
It is used to escape the plus sign (to match a ‘+’ sign)
It is used to escape the question mark(to match a question mark)
The ‘’ itself is a special character, and to match the ‘’ character, we have to use the pattern ‘\’ to escape the backslash.
1. Character sets provide a lot more flexibility than just typing a wildcard or the literal characters. These are groups of characters specified inside square brackets.
2. Character sets can be specified with or without the help of a quantifier.
3. When no quantifier succeeds the character set, it matches only one character and the match is successful only if the character in the string is one of the characters present inside the character set.
For Examples,
Example-1: The pattern ‘[a-z]ed’ will match strings such as ‘ted’, ‘bed’, ‘red’ and so on because the first character of each string — ‘t’, ‘b’ and ‘r’ — is present inside the range of the character set.
Example-2: When we use a character set with a quantifier, such as ‘[a-z]+ed’, it will match only those words that end with ‘ed’ like ‘watched’, ‘baked’, ‘jammed’, ‘educated’, and so on.
From the above examples, we have observed that when a quantifier is present inside the character set, then it loses its special meaning and treated as a normal character.
Let’s discuss the two use-cases of ‘^’ :
For Example, The pattern [0–9] matches any single-digit number but on the contrary, the pattern ‘[^ 0-9]’ matches any single digit character that is not a digit.
Basically, Meta Sequences are a shorthand way to write commonly used character sets in the form of regular expressions. The commonly used meta-sequences are as follows:
Image Source: Google Images
We can use meta-sequences in the following two different ways:
Use them without the square brackets.
For Example, the pattern ‘w+’ will match any alphanumeric character.
Use them inside the square brackets.
For Example, the pattern ‘[w]+’ is the same as ‘w+’.
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