How to read file in Java using Scanner Example — text files
From Java 5 onwards java.util.Scanner class can be used to read file in Java. Earlier we have seen examples of reading file in Java using FileInputStream and reading file line by line using BufferedInputStream and in this Java tutorial, we will See How can we use Scanner to read files in Java. Scanner is a utility class in java.util package and provides several convenient methods to read int , long , String , double etc from a source which can be an InputStream, a file, or a String itself.
As noted on How to get input from User, Scanner is also an easy way to read user input using System.in (InputStream) as the source. The main advantage of using Scanner for reading files is that it allows you to change delimiter using the useDelimiter() method, So you can use any other delimiter like comma, pipe instead of white space.
How to Read File in Java — Scanner Example
In this Java program, we have used java.util.Scanner to read file line by line in Java. We have first created a File instance to represent a text file in Java and then we passed this File instance to java.util.Scanner for scanning.
The scanner provides methods like hasNextLine() and readNextLine() which can be used to read file line by line. It’s advised to check for next line before reading next the line to avoid NoSuchElementException in Java.
import java.io.File ;
import java.io.FileNotFoundException ;
import java.util.Scanner ;
/**
*
* Java program to read files using Scanner class in Java.
* java.util.Scanner is added on Java 5 and offers a convenient method to read data
*
* @author
*/
public class ScannerExample
public static void main ( String args []) throws FileNotFoundException
//creating File instance to reference text file in Java
File text = new File ( «C:/temp/test.txt» ) ;
//Creating Scanner instance to read File in Java
Scanner scnr = new Scanner ( text ) ;
//Reading each line of the file using Scanner class
int lineNumber = 1 ;
while ( scnr. hasNextLine ()) <
String line = scnr. nextLine () ;
System. out . println ( «line » + lineNumber + » :» + line ) ;
lineNumber++ ;
>
Output:
line 1 :——————— START——
————————————————
line 2 :Java provides several way to read files.
line 3 :You can read file using Scanner, FileReader,
FileInputStream and BufferedReader.
line 4 :This Java program shows How to read file using java. util .Scanner class .
line 5 :——————— END————————
———————————
This is the content of test.txt file exception line numbers. You see it doesn’t require much coding to read file in Java using Scanner . You just need to create an instance of Scanner and you are ready to read file.
Class Scanner
A Scanner breaks its input into tokens using a delimiter pattern, which by default matches whitespace. The resulting tokens may then be converted into values of different types using the various next methods.
For example, this code allows a user to read a number from System.in :
Scanner sc = new Scanner(System.in); int i = sc.nextInt(); As another example, this code allows long types to be assigned from entries in a file myNumbers :
Scanner sc = new Scanner(new File("myNumbers")); while (sc.hasNextLong()) The scanner can also use delimiters other than whitespace. This example reads several items in from a string:
String input = "1 fish 2 fish red fish blue fish"; Scanner s = new Scanner(input).useDelimiter("\\s*fish\\s*"); System.out.println(s.nextInt()); System.out.println(s.nextInt()); System.out.println(s.next()); System.out.println(s.next()); s.close(); prints the following output:
The same output can be generated with this code, which uses a regular expression to parse all four tokens at once:
String input = "1 fish 2 fish red fish blue fish"; Scanner s = new Scanner(input); s.findInLine("(\\d+) fish (\\d+) fish (\\w+) fish (\\w+)"); MatchResult result = s.match(); for (int i=1; i The default whitespace delimiter used by a scanner is as recognized by Character.isWhitespace() . The reset() method will reset the value of the scanner's delimiter to the default whitespace delimiter regardless of whether it was previously changed.
A scanning operation may block waiting for input.
The next() and hasNext() methods and their companion methods (such as nextInt() and hasNextInt() ) first skip any input that matches the delimiter pattern, and then attempt to return the next token. Both hasNext() and next() methods may block waiting for further input. Whether a hasNext() method blocks has no connection to whether or not its associated next() method will block. The tokens() method may also block waiting for input.
The findInLine() , findWithinHorizon() , skip() , and findAll() methods operate independently of the delimiter pattern. These methods will attempt to match the specified pattern with no regard to delimiters in the input and thus can be used in special circumstances where delimiters are not relevant. These methods may block waiting for more input.
When a scanner throws an InputMismatchException , the scanner will not pass the token that caused the exception, so that it may be retrieved or skipped via some other method.
Depending upon the type of delimiting pattern, empty tokens may be returned. For example, the pattern "\\s+" will return no empty tokens since it matches multiple instances of the delimiter. The delimiting pattern "\\s" could return empty tokens since it only passes one space at a time.
A scanner can read text from any object which implements the Readable interface. If an invocation of the underlying readable's read() method throws an IOException then the scanner assumes that the end of the input has been reached. The most recent IOException thrown by the underlying readable can be retrieved via the ioException() method.
When a Scanner is closed, it will close its input source if the source implements the Closeable interface.
A Scanner is not safe for multithreaded use without external synchronization.
Unless otherwise mentioned, passing a null parameter into any method of a Scanner will cause a NullPointerException to be thrown.
A scanner will default to interpreting numbers as decimal unless a different radix has been set by using the useRadix(int) method. The reset() method will reset the value of the scanner's radix to 10 regardless of whether it was previously changed.
Localized numbers
An instance of this class is capable of scanning numbers in the standard formats as well as in the formats of the scanner's locale. A scanner's initial locale is the value returned by the Locale.getDefault(Locale.Category.FORMAT) method; it may be changed via the useLocale() method. The reset() method will reset the value of the scanner's locale to the initial locale regardless of whether it was previously changed.
The localized formats are defined in terms of the following parameters, which for a particular locale are taken from that locale's DecimalFormat object, df , and its and DecimalFormatSymbols object, dfs .
LocalGroupSeparator The character used to separate thousands groups, i.e., dfs. getGroupingSeparator() LocalDecimalSeparator The character used for the decimal point, i.e., dfs. getDecimalSeparator() LocalPositivePrefix The string that appears before a positive number (may be empty), i.e., df. getPositivePrefix() LocalPositiveSuffix The string that appears after a positive number (may be empty), i.e., df. getPositiveSuffix() LocalNegativePrefix The string that appears before a negative number (may be empty), i.e., df. getNegativePrefix() LocalNegativeSuffix The string that appears after a negative number (may be empty), i.e., df. getNegativeSuffix() LocalNaN The string that represents not-a-number for floating-point values, i.e., dfs. getNaN() LocalInfinity The string that represents infinity for floating-point values, i.e., dfs. getInfinity()
Number syntax
The strings that can be parsed as numbers by an instance of this class are specified in terms of the following regular-expression grammar, where Rmax is the highest digit in the radix being used (for example, Rmax is 9 in base 10). NonAsciiDigit: A non-ASCII character c for which Character.isDigit (c) returns true Non0Digit: [1- Rmax ] | NonASCIIDigit Digit: [0- Rmax ] | NonASCIIDigit GroupedNumeral: ( Non0Digit Digit ? Digit ? ( LocalGroupSeparator Digit Digit Digit )+ ) Numeral: ( ( Digit + ) | GroupedNumeral ) Integer: ( [-+]? ( Numeral ) ) | LocalPositivePrefix Numeral LocalPositiveSuffix | LocalNegativePrefix Numeral LocalNegativeSuffix DecimalNumeral: Numeral | Numeral LocalDecimalSeparator Digit * | LocalDecimalSeparator Digit + Exponent: ( [eE] [+-]? Digit + ) Decimal: ( [-+]? DecimalNumeral Exponent ? ) | LocalPositivePrefix DecimalNumeral LocalPositiveSuffix Exponent ? | LocalNegativePrefix DecimalNumeral LocalNegativeSuffix Exponent ? HexFloat: [-+]? 0[xX][0-9a-fA-F]*\.[0-9a-fA-F]+ ([pP][-+]?9+)? NonNumber: NaN | LocalNan | Infinity | LocalInfinity SignedNonNumber: ( [-+]? NonNumber ) | LocalPositivePrefix NonNumber LocalPositiveSuffix | LocalNegativePrefix NonNumber LocalNegativeSuffix Float: Decimal | HexFloat | SignedNonNumber
Whitespace is not significant in the above regular expressions.