Tuesday, 6 May 2014

Breaking: PTCL to Launch 36Mbps Wireless Broadband With-in Two Weeks

 


PTCL Logo Breaking: PTCL to Launch 36Mbps Wireless Broadband With in Two Weeks
If you think that 3G or even 4G was your last resort for mobile broadband needs then the time has come to think it again.
I am saying this PTCL is all set to come up with something that will blow your minds. The company has decided to shock the market again with this new device that will change the way we connect to internet, exactly like it did with EVO and Nitro devices few years ago.
We have confirmations that blazing internet speeds up to 36Mbps are going to be up for the offering to masses in Pakistan with-in next just couple of weeks, yes that’s about with-in 15 days from today.
According to the information we have received, this new technology is being pioneered in Pakistan by PTCL that is capable of offering wireless broadband speeds up to 36Mbps for download and up to 7Mbps for data uploads with-in PTCL’s existing WLL spectrum.
Our sources confirm that actual download speeds crossed 30Mbps mark on a network that PTCL is currently testing in a live environment.
Customers can expect actual download speeds of 20Mbps to 25Mbps after the launch of this new project from PTCL that is code-named as “Chaar Ji” with-in the company.
PTCL hasn’t confirmed us anything officially yet, however, we have cross checked with multiple sources to believe that this whooping wireless broadband speed – something we used to hear about from our foreign friends only – will be available on EVO-like WiFi dongle devices.
At the time of the launch, we are told, the service will be offered with a starting price of Rs. 3,000 per month. Pricing may go higher with higher data caps, but we don’t have final details yet.
Expect more details on this ridiculously fast internet in Pakistan with-in coming days on this website.
For now, just imagine a download speed of 20Mbps even when you are driving around on the roads of Karachi!
Thanks to Rana Jawad Ahmad for his contribution in preparing this post.
Update
As mentioned above, there are already tests being carried out by PTCL on this technology that offers 36Mbps download speeds.
The feedback from testers has been amazing, as apparent by below tweet shared by a fellow. It also has the image of “Chaar Ji” device that will launched later this month.

Sunday, 4 May 2014

Java - Regular Expressions

Java provides the java.util.regex package for pattern matching with regular expressions. Java regular expressions are very similar to the Perl programming language and very easy to learn.
A regular expression is a special sequence of characters that helps you match or find other strings or sets of strings, using a specialized syntax held in a pattern. They can be used to search, edit, or manipulate text and data.
The java.util.regex package primarily consists of the following three classes:
  • Pattern Class: A Pattern object is a compiled representation of a regular expression. The Pattern class provides no public constructors. To create a pattern, you must first invoke one of its public static compile methods, which will then return a Pattern object. These methods accept a regular expression as the first argument.
  • Matcher Class: A Matcher object is the engine that interprets the pattern and performs match operations against an input string. Like the Pattern class, Matcher defines no public constructors. You obtain a Matcher object by invoking the matcher method on a Pattern object.
  • PatternSyntaxException: A PatternSyntaxException object is an unchecked exception that indicates a syntax error in a regular expression pattern.

Capturing Groups:

Capturing groups are a way to treat multiple characters as a single unit. They are created by placing the characters to be grouped inside a set of parentheses. For example, the regular expression (dog) creates a single group containing the letters "d", "o", and "g".
Capturing groups are numbered by counting their opening parentheses from left to right. In the expression ((A)(B(C))), for example, there are four such groups:
  • ((A)(B(C)))
  • (A)
  • (B(C))
  • (C)
To find out how many groups are present in the expression, call the groupCount method on a matcher object. The groupCount method returns an int showing the number of capturing groups present in the matcher's pattern.
There is also a special group, group 0, which always represents the entire expression. This group is not included in the total reported by groupCount.

Example:

Following example illustrates how to find a digit string from the given alphanumeric string:
import java.util.regex.Matcher;
import java.util.regex.Pattern;

public class RegexMatches
{
    public static void main( String args[] ){

      // String to be scanned to find the pattern.
      String line = "This order was placed for QT3000! OK?";
      String pattern = "(.*)(\\d+)(.*)";

      // Create a Pattern object
      Pattern r = Pattern.compile(pattern);

      // Now create matcher object.
      Matcher m = r.matcher(line);
      if (m.find( )) {
         System.out.println("Found value: " + m.group(0) );
         System.out.println("Found value: " + m.group(1) );
         System.out.println("Found value: " + m.group(2) );
      } else {
         System.out.println("NO MATCH");
      }
   }
}
This would produce the following result:
Found value: This order was placed for QT3000! OK?
Found value: This order was placed for QT300
Found value: 0

Regular Expression Syntax:

Here is the table listing down all the regular expression metacharacter syntax available in Java:
SubexpressionMatches
^Matches beginning of line.
$Matches end of line.
.Matches any single character except newline. Using m option allows it to match newline as well.
[...]Matches any single character in brackets.
[^...]Matches any single character not in brackets
\ABeginning of entire string
\zEnd of entire string
\ZEnd of entire string except allowable final line terminator.
re*Matches 0 or more occurrences of preceding expression.
re+Matches 1 or more of the previous thing
re?Matches 0 or 1 occurrence of preceding expression.
re{ n}Matches exactly n number of occurrences of preceding expression.
re{ n,}Matches n or more occurrences of preceding expression.
re{ n, m}Matches at least n and at most m occurrences of preceding expression.
a| bMatches either a or b.
(re)Groups regular expressions and remembers matched text.
(?: re)Groups regular expressions without remembering matched text.
(?> re)Matches independent pattern without backtracking.
\wMatches word characters.
\WMatches nonword characters.
\sMatches whitespace. Equivalent to [\t\n\r\f].
\SMatches nonwhitespace.
\dMatches digits. Equivalent to [0-9].
\DMatches nondigits.
\AMatches beginning of string.
\ZMatches end of string. If a newline exists, it matches just before newline.
\zMatches end of string.
\GMatches point where last match finished.
\nBack-reference to capture group number "n"
\bMatches word boundaries when outside brackets. Matches backspace (0x08) when inside brackets.
\BMatches nonword boundaries.
\n, \t, etc.Matches newlines, carriage returns, tabs, etc.
\QEscape (quote) all characters up to \E
\EEnds quoting begun with \Q

Methods of the Matcher Class:

Here is a list of useful instance methods:

Index Methods:

Index methods provide useful index values that show precisely where the match was found in the input string:
SNMethods with Description
1public int start() 
Returns the start index of the previous match.
2public int start(int group)
Returns the start index of the subsequence captured by the given group during the previous match operation.
3public int end()
Returns the offset after the last character matched.
4public int end(int group)
Returns the offset after the last character of the subsequence captured by the given group during the previous match operation.

Study Methods:

Study methods review the input string and return a Boolean indicating whether or not the pattern is found:
SNMethods with Description
1public boolean lookingAt() 
Attempts to match the input sequence, starting at the beginning of the region, against the pattern.
2public boolean find() 
Attempts to find the next subsequence of the input sequence that matches the pattern.
3public boolean find(int start
Resets this matcher and then attempts to find the next subsequence of the input sequence that matches the pattern, starting at the specified index.
4public boolean matches() 
Attempts to match the entire region against the pattern.

Replacement Methods:

Replacement methods are useful methods for replacing text in an input string:
SNMethods with Description
1public Matcher appendReplacement(StringBuffer sb, String replacement)
Implements a non-terminal append-and-replace step.
2public StringBuffer appendTail(StringBuffer sb)
Implements a terminal append-and-replace step.
3public String replaceAll(String replacement) 
Replaces every subsequence of the input sequence that matches the pattern with the given replacement string.
4public String replaceFirst(String replacement)
Replaces the first subsequence of the input sequence that matches the pattern with the given replacement string.
5public static String quoteReplacement(String s)
Returns a literal replacement String for the specified String. This method produces a String that will work as a literal replacement s in the appendReplacement method of the Matcher class.

The start and end Methods:

Following is the example that counts the number of times the word "cats" appears in the input string:
import java.util.regex.Matcher;
import java.util.regex.Pattern;

public class RegexMatches
{
    private static final String REGEX = "\\bcat\\b";
    private static final String INPUT =
                                    "cat cat cat cattie cat";

    public static void main( String args[] ){
       Pattern p = Pattern.compile(REGEX);
       Matcher m = p.matcher(INPUT); // get a matcher object
       int count = 0;

       while(m.find()) {
         count++;
         System.out.println("Match number "+count);
         System.out.println("start(): "+m.start());
         System.out.println("end(): "+m.end());
      }
   }
}
This would produce the following result:
Match number 1
start(): 0
end(): 3
Match number 2
start(): 4
end(): 7
Match number 3
start(): 8
end(): 11
Match number 4
start(): 19
end(): 22
You can see that this example uses word boundaries to ensure that the letters "c" "a" "t" are not merely a substring in a longer word. It also gives some useful information about where in the input string the match has occurred.
The start method returns the start index of the subsequence captured by the given group during the previous match operation, and end returns the index of the last character matched, plus one.

The matches and lookingAt Methods:

The matches and lookingAt methods both attempt to match an input sequence against a pattern. The difference, however, is that matches requires the entire input sequence to be matched, while lookingAt does not.
Both methods always start at the beginning of the input string. Here is the example explaining the functionality:
import java.util.regex.Matcher;
import java.util.regex.Pattern;

public class RegexMatches
{
    private static final String REGEX = "foo";
    private static final String INPUT = "fooooooooooooooooo";
    private static Pattern pattern;
    private static Matcher matcher;

    public static void main( String args[] ){
       pattern = Pattern.compile(REGEX);
       matcher = pattern.matcher(INPUT);

       System.out.println("Current REGEX is: "+REGEX);
       System.out.println("Current INPUT is: "+INPUT);

       System.out.println("lookingAt(): "+matcher.lookingAt());
       System.out.println("matches(): "+matcher.matches());
   }
}
This would produce the following result:
Current REGEX is: foo
Current INPUT is: fooooooooooooooooo
lookingAt(): true
matches(): false

The replaceFirst and replaceAll Methods:

The replaceFirst and replaceAll methods replace text that matches a given regular expression. As their names indicate, replaceFirst replaces the first occurrence, and replaceAll replaces all occurrences.
Here is the example explaining the functionality:
import java.util.regex.Matcher;
import java.util.regex.Pattern;

public class RegexMatches
{
    private static String REGEX = "dog";
    private static String INPUT = "The dog says meow. " +
                                    "All dogs say meow.";
    private static String REPLACE = "cat";

    public static void main(String[] args) {
       Pattern p = Pattern.compile(REGEX);
       // get a matcher object
       Matcher m = p.matcher(INPUT); 
       INPUT = m.replaceAll(REPLACE);
       System.out.println(INPUT);
   }
}
This would produce the following result:
The cat says meow. All cats say meow.

The appendReplacement and appendTail Methods:

The Matcher class also provides appendReplacement and appendTail methods for text replacement.
Here is the example explaining the functionality:
import java.util.regex.Matcher;
import java.util.regex.Pattern;

public class RegexMatches
{
   private static String REGEX = "a*b";
   private static String INPUT = "aabfooaabfooabfoob";
   private static String REPLACE = "-";
   public static void main(String[] args) {
      Pattern p = Pattern.compile(REGEX);
      // get a matcher object
      Matcher m = p.matcher(INPUT);
      StringBuffer sb = new StringBuffer();
      while(m.find()){
         m.appendReplacement(sb,REPLACE);
      }
      m.appendTail(sb);
      System.out.println(sb.toString());
   }
}
This would produce the following result:
-foo-foo-foo-

PatternSyntaxException Class Methods:

A PatternSyntaxException is an unchecked exception that indicates a syntax error in a regular expression pattern. The PatternSyntaxException class provides the following methods to help you determine what went wrong:
SNMethods with Description
1public String getDescription()
Retrieves the description of the error.
2public int getIndex() 
Retrieves the error index.
3public String getPattern() 
Retrieves the erroneous regular expression pattern.
4public String getMessage() 
Returns a multi-line string containing the description of the syntax error and its index, the erroneous regular expression pattern, and a visual indication of the error index within the pattern.

 

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