Q. What is Java Collections API?
Java Collections framework API is a unified
architecture for representing and manipulating collections. The API contains
Interfaces, Implementations & Algorithm to help java programmer in everyday
programming. In nutshell, this API does 6 things at high level
- Reduces programming efforts. - Increases program speed and quality.
- Allows interoperability among unrelated APIs.
- Reduces effort to learn and to use new APIs.
- Reduces effort to design new APIs.
- Encourages & Fosters software reuse.
To be specific, There are six collection
java interfaces. The most basic interface is Collection. Three interfaces
extend Collection: Set, List, and SortedSet. The other two collection
interfaces, Map and SortedMap, do not extend Collection, as they represent
mappings rather than true collections.
Q. What is an Iterator?
Some of the collection classes provide
traversal of their contents via a java.util.Iterator interface. This interface
allows you to walk through a collection of objects, operating on each object in
turn. Remember when using Iterators that they contain a snapshot of the
collection at the time the Iterator was obtained; generally it is not advisable
to modify the collection itself while traversing an Iterator.
Q. What is the difference between
java.util.Iterator and java.util.ListIterator?
Iterator
: Enables you to traverse through a collection in the forward direction only,
for obtaining or removing elements ListIterator : extends Iterator, and allows
bidirectional traversal of list and also allows the modification of elements.
Q. What is HashMap and Map?
Map is Interface which is part of Java
collections framework. This is to store Key Value pair, and Hashmap is class that
implements that using hashing technique.
Q. Difference between HashMap and HashTable?
Compare Hashtable vs HashMap?
Both Hashtable & HashMap provide
key-value access to data. The Hashtable is one of the original collection
classes in Java (also called as legacy classes). HashMap is part of the new
Collections Framework, added with Java 2, v1.2. There are several differences
between HashMap and Hashtable in Java as listed below
- The HashMap class is roughly equivalent to Hashtable, except that it is unsynchronized and permits nulls. (HashMap allows null values as key and value whereas Hashtable doesn’t allow nulls).
- HashMap does not guarantee that the order of the map will remain constant over time. But one of HashMap's subclasses is LinkedHashMap, so in the event that you'd want predictable iteration order (which is insertion order by default), you can easily swap out the HashMap for a LinkedHashMap. This wouldn't be as easy if you were using Hashtable.
- HashMap is non synchronized whereas Hashtable is synchronized.
- Iterator in the HashMap is fail-fast while the enumerator for the Hashtable isn't. So this could be a design consideration.
Q. What does synchronized means in Hashtable
context?
Synchronized means only one thread can
modify a hash table at one point of time. Any thread before performing an
update on a hashtable will have to acquire a lock on the object while others
will wait for lock to be released.
Q. What is fail-fast property?
At high level - Fail-fast is a property of
a system or software with respect to its response to failures. A fail-fast
system is designed to immediately report any failure or condition that is
likely to lead to failure. Fail-fast systems are usually designed to stop
normal operation rather than attempt to continue a possibly-flawed process.
When a problem occurs, a fail-fast system fails immediately and visibly.
Failing fast is a non-intuitive technique: "failing immediately and
visibly" sounds like it would make your software more fragile, but it
actually makes it more robust. Bugs are easier to find and fix, so fewer go
into production. In Java, Fail-fast term can be related to context of
iterators. If an iterator has been created on a collection object and some
other thread tries to modify the collection object "structurally", a
concurrent modification exception will be thrown. It is possible for other
threads though to invoke "set" method since it doesn't modify the
collection "structurally". However, if prior to calling
"set", the collection has been modified structurally,
"IllegalArgumentException" will be thrown.
Q. Why doesn't Collection extend Cloneable and
Serializable?
From Sun FAQ Page: Many Collection
implementations (including all of the ones provided by the JDK) will have a
public clone method, but it would be mistake to require it of all Collections.
For example, what does it mean to clone a Collection that's backed by a
terabyte SQL database? Should the method call cause the company to requisition
a new disk farm? Similar arguments hold for serializable. If the client doesn't
know the actual type of a Collection, it's much more flexible and less error
prone to have the client decide what type of Collection is desired, create an
empty Collection of this type, and use the addAll method to copy the elements
of the original collection into the new one. Note on Some Important Terms
- Synchronized means only one thread can modify a hash table at one point of time. Basically, it means that any thread before performing an update on a hashtable will have to acquire a lock on the object while others will wait for lock to be released.
- Fail-fast is relevant from the context of iterators. If an iterator has been created on a collection object and some other thread tries to modify the collection object "structurally”, a concurrent modification exception will be thrown. It is possible for other threads though to invoke "set" method since it doesn’t modify the collection "structurally”. However, if prior to calling "set", the collection has been modified structurally, "IllegalArgumentException" will be thrown.
Q. How can we make Hashmap synchronized?
HashMap can be synchronized by Map m =
Collections.synchronizedMap(hashMap);
Q. Where will you use Hashtable and where will
you use HashMap?
There are multiple aspects to this
decision: 1. The basic difference between a Hashtable and an HashMap is that,
Hashtable is synchronized while HashMap is not. Thus whenever there is a
possibility of multiple threads accessing the same instance, one should use
Hashtable. While if not multiple threads are going to access the same instance
then use HashMap. Non synchronized data structure will give better performance
than the synchronized one.
2. If there is a possibility in future that - there can be a scenario when you may require to retain the order of objects in the Collection with key-value pair then HashMap can be a good choice. As one of HashMap's subclasses is LinkedHashMap, so in the event that you'd want predictable iteration order (which is insertion order by default), you can easily swap out the HashMap for a LinkedHashMap. This wouldn't be as easy if you were using Hashtable. Also if you have multiple thread accessing you HashMap then Collections.synchronizedMap() method can be leveraged. Overall HashMap gives you more flexibility in terms of possible future changes.
2. If there is a possibility in future that - there can be a scenario when you may require to retain the order of objects in the Collection with key-value pair then HashMap can be a good choice. As one of HashMap's subclasses is LinkedHashMap, so in the event that you'd want predictable iteration order (which is insertion order by default), you can easily swap out the HashMap for a LinkedHashMap. This wouldn't be as easy if you were using Hashtable. Also if you have multiple thread accessing you HashMap then Collections.synchronizedMap() method can be leveraged. Overall HashMap gives you more flexibility in terms of possible future changes.
Q. Difference between Vector and ArrayList?
What is the Vector class?
Vector & ArrayList both classes are
implemented using dynamically resizable arrays, providing fast random access
and fast traversal. ArrayList and Vector class both implement the List
interface. Both the classes are member of Java collection framework, therefore
from an API perspective, these two classes are very similar. However, there are
still some major differences between the two. Below are some key differences
- Vector is a legacy class which has been retrofitted to implement the List interface since Java 2 platform v1.2
- Vector is synchronized whereas ArrayList is not. Even though Vector class is synchronized, still when you want programs to run in multithreading environment using ArrayList with Collections.synchronizedList() is recommended over Vector.
- ArrayList has no default size while vector has a default size of 10.
- The Enumerations returned by Vector's elements method are not fail-fast. Whereas ArraayList does not have any method returning Enumerations.
Q. What is the Difference between Enumeration
and Iterator interface?
Enumeration and Iterator are the interface
available in java.util package. The functionality of Enumeration interface is
duplicated by the Iterator interface. New implementations should consider using
Iterator in preference to Enumeration. Iterators differ from enumerations in
following ways:
- Enumeration contains 2 methods namely hasMoreElements() & nextElement() whereas Iterator contains three methods namely hasNext(), next(),remove().
- Iterator adds an optional remove operation, and has shorter method names. Using remove() we can delete the objects but Enumeration interface does not support this feature.
- Enumeration interface is used by legacy classes. Vector.elements() & Hashtable.elements() method returns Enumeration. Iterator is returned by all Java Collections Framework classes. java.util.Collection.iterator() method returns an instance of Iterator.
Q. Why Java Vector class is considered
obsolete or unofficially deprecated? or Why should I always use ArrayList over
Vector?
You should use ArrayList over Vector
because you should default to non-synchronized access. Vector synchronizes each
individual method. That's almost never what you want to do. Generally you want
to synchronize a whole sequence of operations. Synchronizing individual
operations is both less safe (if you iterate over a Vector, for instance, you
still need to take out a lock to avoid anyone else changing the collection at
the same time) but also slower (why take out a lock repeatedly when once will
be enough)? Of course, it also has the overhead of locking even when you don't
need to. It's a very flawed approach to have synchronized access as default.
You can always decorate a collection using Collections.synchronizedList - the
fact that Vector combines both the "resized array" collection
implementation with the "synchronize every operation" bit is another
example of poor design; the decoration approach gives cleaner separation of
concerns. Vector also has a few legacy methods around enumeration and element
retrieval which are different than the List interface, and developers
(especially those who learned Java before 1.2) can tend to use them if they are
in the code. Although Enumerations are faster, they don't check if the
collection was modified during iteration, which can cause issues, and given
that Vector might be chosen for its syncronization - with the attendant access
from multiple threads, this makes it a particularly pernicious problem. Usage
of these methods also couples a lot of code to Vector, such that it won't be
easy to replace it with a different List implementation. Despite all above
reasons Sun may never officially deprecate Vector class.
Q. What is an enumeration?
An enumeration is an interface containing
methods for accessing the underlying data structure from which the enumeration
is obtained. It is a construct which collection classes return when you request
a collection of all the objects stored in the collection. It allows sequential
access to all the elements stored in the collection.
Q. What is the difference between Enumeration
and Iterator?
The functionality of Enumeration interface
is duplicated by the Iterator interface. Iterator has a remove() method while
Enumeration doesn't. Enumeration acts as Read-only interface, because it has
the methods only to traverse and fetch the objects, where as using Iterator we
can manipulate the objects also like adding and removing the objects. So
Enumeration is used whenever we want to make Collection objects as Read-only.
Q. Where will you use Vector and where will
you use ArrayList?
The basic difference between a Vector and
an ArrayList is that, vector is synchronized while ArrayList is not. Thus
whenever there is a possibility of multiple threads accessing the same
instance, one should use Vector. While if not multiple threads are going to
access the same instance then use ArrayList. Non synchronized data structure
will give better performance than the synchronized one.
Q. What is the importance of hashCode() and
equals() methods? How they are used in Java?
The java.lang.Object has two methods
defined in it. They are - public boolean equals(Object obj) public int
hashCode(). These two methods are used heavily when objects are stored in
collections. There is a contract between these two methods which should be kept
in mind while overriding any of these methods. The Java API documentation
describes it in detail. The hashCode() method returns a hash code value for the
object. This method is supported for the benefit of hashtables such as those
provided by java.util.Hashtable or java.util.HashMap. The general contract of
hashCode is: Whenever it is invoked on the same object more than once during an
execution of a Java application, the hashCode method must consistently return
the same integer, provided no information used in equals comparisons on the
object is modified. This integer need not remain consistent from one execution
of an application to another execution of the same application. If two objects
are equal according to the equals(Object) method, then calling the hashCode method
on each of the two objects must produce the same integer result. It is not
required that if two objects are unequal according to the
equals(java.lang.Object) method, then calling the hashCode method on each of
the two objects must produce distinct integer results. However, the programmer
should be aware that producing distinct integer results for unequal objects may
improve the performance of hashtables. As much as is reasonably practical, the
hashCode method defined by class Object does return distinct integers for
distinct objects. The equals(Object obj) method indicates whether some other
object is "equal to" this one. The equals method implements an
equivalence relation on non-null object references: It is reflexive: for any
non-null reference value x, x.equals(x) should return true. It is symmetric:
for any non-null reference values x and y, x.equals(y) should return true if
and only if y.equals(x) returns true. It is transitive: for any non-null
reference values x, y, and z, if x.equals(y) returns true and y.equals(z)
returns true, then x.equals(z) should return true. It is consistent: for any
non-null reference values x and y, multiple invocations of x.equals(y)
consistently return true or consistently return false, provided no information
used in equals comparisons on the objects is modified. For any non-null
reference value x, x.equals(null) should return false. The equals method for
class Object implements the most discriminating possible equivalence relation
on objects; that is, for any non-null reference values x and y, this method
returns true if and only if x and y refer to the same object (x == y has the
value true). Note that it is generally necessary to override the hashCode
method whenever this method is overridden, so as to maintain the general
contract for the hashCode method, which states that equal objects must have
equal hash codes. A practical Example of hashcode() & equals(): This
can be applied to classes that need to be stored in Set collections. Sets use
equals() to enforce non-duplicates, and HashSet uses hashCode() as a first-cut
test for equality. Technically hashCode() isn't necessary then since equals()
will always be used in the end, but providing a meaningful hashCode() will
improve performance for very large sets or objects that take a long time to
compare using equals().
Q. What is the difference between Sorting
performance of Arrays.sort() vs Collections.sort() ? Which one is faster? Which
one to use and when?
Many developers are concerned about the
performance difference between java.util.Array.sort()
java.util.Collections.sort() methods. Both methods have same algorithm the only
difference is type of input to them. Collections.sort() has a input as List so
it does a translation of List to array and vice versa which is an additional
step while sorting. So this should be used when you are trying to sort a list.
Arrays.sort is for arrays so the sorting is done directly on the array. So
clearly it should be used when you have a array available with you and you want
to sort it.
Q. What is java.util.concurrent BlockingQueue?
How it can be used?
Java has implementation of BlockingQueue
available since Java 1.5. Blocking Queue interface extends collection
interface, which provides you power of collections inside a queue. Blocking Queue
is a type of Queue that additionally supports operations that wait for the
queue to become non-empty when retrieving an element, and wait for space to
become available in the queue when storing an element. A typical usage example
would be based on a producer-consumer scenario. Note that a BlockingQueue can
safely be used with multiple producers and multiple consumers. An
ArrayBlockingQueue is a implementation of blocking queue with an array used to
store the queued objects. The head of the queue is that element that has been
on the queue the longest time. The tail of the queue is that element that has
been on the queue the shortest time. New elements are inserted at the tail of
the queue, and the queue retrieval operations obtain elements at the head of the
queue. ArrayBlockingQueue requires you to specify the capacity of queue at the
object construction time itself. Once created, the capacity cannot be
increased. This is a classic "bounded buffer" (fixed size buffer), in
which a fixed-sized array holds elements inserted by producers and extracted by
consumers. Attempts to put an element to a full queue will result in the put
operation blocking; attempts to retrieve an element from an empty queue will be
blocked.
Q. Set & List interface extend Collection,
so Why doesn't Map interface extend Collection?
Though the Map interface is part of
collections framework, it does not extend collection interface. This is by
design, and the answer to this questions is best described in Sun's FAQ Page: This
was by design. We feel that mappings are not collections and collections are
not mappings. Thus, it makes little sense for Map to extend the Collection
interface (or vice versa). If a Map is a Collection, what are the elements? The
only reasonable answer is "Key-value pairs", but this provides a very
limited (and not particularly useful) Map abstraction. You can't ask what value
a given key maps to, nor can you delete the entry for a given key without
knowing what value it maps to. Collection could be made to extend Map, but this
raises the question: what are the keys? There's no really satisfactory answer,
and forcing one leads to an unnatural interface. Maps can be viewed as
Collections (of keys, values, or pairs), and this fact is reflected in the three
"Collection view operations" on Maps (keySet, entrySet, and values).
While it is, in principle, possible to view a List as a Map mapping indices to
elements, this has the nasty property that deleting an element from the List
changes the Key associated with every element before the deleted element.
That's why we don't have a map view operation on Lists.
Q. Which implementation of the List interface
provides for the fastest insertion of a new element into the middle of the
list?
a. Vector b. ArrayList c. LinkedList
ArrayList and Vector both use an array to store the elements of the list. When
an element is inserted into the middle of the list the elements that follow the
insertion point must be shifted to make room for the new element. The
LinkedList is implemented using a doubly linked list; an insertion requires
only the updating of the links at the point of insertion. Therefore, the
LinkedList allows for fast insertions and deletions.
Q. What is the difference between ArrayList and
LinkedList? (ArrayList vs LinkedList.)
java.util.ArrayList and
java.util.LinkedList are two Collections classes used for storing lists of
object references Here are some key differences:
- ArrayList uses primitive object array for storing objects whereas LinkedList is made up of a chain of nodes. Each node stores an element and the pointer to the next node. A singly linked list only has pointers to next. A doubly linked list has a pointer to the next and the previous element. This makes walking the list backward easier.
- ArrayList implements the RandomAccess interface, and LinkedList does not. The commonly used ArrayList implementation uses primitive Object array for internal storage. Therefore an ArrayList is much faster than a LinkedList for random access, that is, when accessing arbitrary list elements using the get method. Note that the get method is implemented for LinkedLists, but it requires a sequential scan from the front or back of the list. This scan is very slow. For a LinkedList, there's no fast way to access the Nth element of the list.
- Adding and deleting at the start and middle of the ArrayList is slow, because all the later elements have to be copied forward or backward. (Using System.arrayCopy()) Whereas Linked lists are faster for inserts and deletes anywhere in the list, since all you do is update a few next and previous pointers of a node.
- Each element of a linked list (especially a doubly linked list) uses a bit more memory than its equivalent in array list, due to the need for next and previous pointers.
- ArrayList may also have a performance issue when the internal array fills up. The arrayList has to create a new array and copy all the elements there. The ArrayList has a growth algorithm of (n*3)/2+1, meaning that each time the buffer is too small it will create a new one of size (n*3)/2+1 where n is the number of elements of the current buffer. Hence if we can guess the number of elements that we are going to have, then it makes sense to create a arraylist with that capacity during object creation (using construtor new ArrayList(capacity)). Whereas LinkedLists should not have such capacity issues.
Q. Where will you use ArrayList and Where will
you use LinkedList? Or Which one to use when (ArrayList / LinkedList).
Below is a snippet from SUN's site. The
Java SDK contains 2 implementations of the List interface - ArrayList and
LinkedList. If you frequently add elements to the beginning of the List or
iterate over the List to delete elements from its interior, you should consider
using LinkedList. These operations require constant-time in a LinkedList and
linear-time in an ArrayList. But you pay a big price in performance. Positional
access requires linear-time in a LinkedList and constant-time in an ArrayList.
Q. What is performance of various Java
collection implementations/algorithms? What is Big 'O' notation for each of
them ?
Each java collection implementation class
have different performance for different methods, which makes them suitable for
different programming needs.
Performance of Map interface
implementations
Hashtable:
An instance of Hashtable has two parameters
that affect its performance: initial capacity and load factor. The capacity is
the number of buckets in the hash table, and the initial capacity is simply the
capacity at the time the hash table is created. Note that the hash table is
open: in the case of a "hash collision", a single bucket stores
multiple entries, which must be searched sequentially. The load factor is a
measure of how full the hash table is allowed to get before its capacity is
automatically increased. The initial capacity and load factor parameters are
merely hints to the implementation. The exact details as to when and whether
the rehash method is invoked are implementation-dependent.
HashMap:
This implementation provides constant-time
[ Big O Notation is O(1) ] performance for the basic operations (get and put),
assuming the hash function disperses the elements properly among the buckets.
Iteration over collection views requires time proportional to the
"capacity" of the HashMap instance (the number of buckets) plus its
size (the number of key-value mappings). Thus, it's very important not to set
the initial capacity too high (or the load factor too low) if iteration
performance is important.
TreeMap:
The TreeMap implementation provides
guaranteed log(n) [ Big O Notation is O(log N) ] time cost for the containsKey,
get, put and remove operations.
LinkedHashMap
A linked hash map has two parameters that
affect its performance: initial capacity and load factor. They are defined
precisely as for HashMap. Note, however, that the penalty for choosing an
excessively high value for initial capacity is less severe for this class than
for HashMap, as iteration times for this class are unaffected by capacity.
Performance of Set interface
implementations
HashSet
The HashSet class offers constant-time [
Big O Notation is O(1) ] performance for the basic operations (add, remove,
contains and size), assuming the hash function disperses the elements properly
among the buckets. Iterating over this set requires time proportional to the
sum of the HashSet instance's size (the number of elements) plus the
"capacity" of the backing HashMap instance (the number of buckets).
Thus, it's very important not to set the initial capacity too high (or the load
factor too low) if iteration performance is important.
TreeSet
The TreeSet implementation provides
guaranteed log(n) time cost for the basic operations (add, remove and
contains).
LinkedHashSet
A linked hash set has two parameters that
affect its performance: initial capacity and load factor. They are defined
precisely as for HashSet. Note, however, that the penalty for choosing an
excessively high value for initial capacity is less severe for this class than
for HashSet, as iteration times for this class are unaffected by capacity.
Performance of List interface
implementations
LinkedList
- Performance of get and remove methods is
linear time [ Big O Notation is O(n) ] - Performance of add and Iterator.remove
methods is constant-time [ Big O Notation is O(1) ]
ArrayList
- The size, isEmpty, get, set, iterator,
and listIterator operations run in constant time. [ Big O Notation is O(1) ] -
The add operation runs in amortized constant time [ Big O Notation is O(1) ] ,
but in worst case (since the array must be resized and copied) adding n
elements requires linear time [ Big O Notation is O(n) ] - Performance of
remove method is linear time [ Big O Notation is O(n) ] - All of the other
operations run in linear time [ Big O Notation is O(n) ]. The constant factor
is low compared to that for the LinkedList implementation.
No comments:
Post a Comment