how to use C Vectors ? - CGDTech - CSDNBlog

  #include   container();  container( const container& c );  container( size_type num, const TYPE& val = TYPE() );  container( input_iterator start, input_iterator end );  ~container();

The default vector constructor takes no arguments, creates a new instance of that vector.

The second constructor is a default copy constructor that can be used to create a new vector that is a copy of the given vector c.

The third constructor creates a vector with space for num objects. If val is specified, each of those objects will be given that value. For example, the following code creates a vector consisting of five copies of the integer 42:

 vector v1( 5, 42 );

The last constructor creates a vector that is initialized to contain the elements between start and end. For example:

 // create a vector of random integers cout << "original vector: "; vector v; for( int i = 0; i < 10; i++ ) {   int num = (int) rand() % 10;   cout << num << " ";   v.push_back( num ); } cout << endl; // find the first element of v that is even vector::iterator iter1 = v.begin(); while( iter1 != v.end() && *iter1 % 2 != 0 ) {   iter1++; } // find the last element of v that is even vector::iterator iter2 = v.end(); do {   iter2--; } while( iter2 != v.begin() && *iter2 % 2 != 0 ); cout << "first even number: " << *iter1 << ", last even number: " << *iter2 << endl; cout << "new vector: "; vector v2( iter1, iter2 ); for( int i = 0; i < v2.size(); i++ ) {   cout << v2[i] << " "; } cout << endl;

When run, this code displays the following output:

 original vector: 1 9 7 9 2 7 2 1 9 8 first even number: 2, last even number: 8 new vector: 2 7 2 1 9

All of these constructors run in linear time except the first, which runs in constant time.

The default destructor is called when the vector should be destroyed.

  #include   TYPE& operator[]( size_type index );  const TYPE& operator[]( size_type index ) const;  container operator=(const container& c2);  bool operator==(const container& c1, const container& c2);  bool operator!=(const container& c1, const container& c2);  bool operator<(const container& c1, const container& c2);  bool operator>(const container& c1, const container& c2);  bool operator<=(const container& c1, const container& c2);  bool operator>=(const container& c1, const container& c2);

All of the C++ containers can be compared and assigned with the standard comparison operators: ==, !=, <=, >=, <, >, and =. Individual elements of a vector can be examined with the [] operator.

Performing a comparison or assigning one vector to another takes linear time. The [] operator runs in constant time.

Two `containers` are equal if:

1. Their size is the same, and
2. Each member in location i in one vector is equal to the the member in location i in the other vector.

Comparisons among vectors are done lexicographically.

For example, the following code uses the [] operator to access all of the elements of a vector:

 vector v( 5, 1 ); for( int i = 0; i < v.size(); i++ ) {   cout << "Element " << i << " is " << v[i] << endl; }

  #include   void assign( size_type num, const TYPE& val );  void assign( input_iterator start, input_iterator end );

The assign() function either gives the current vector the values from start to end, or gives it num copies of val.

This function will destroy the previous contents of the vector.

For example, the following code uses assign() to put 10 copies of the integer 42 into a vector:

 vector v; v.assign( 10, 42 ); for( int i = 0; i < v.size(); i++ ) {   cout << v[i] << " "; } cout << endl;

The above code displays the following output:

 42 42 42 42 42 42 42 42 42 42

The next example shows how assign() can be used to copy one vector to another:

 vector v1; for( int i = 0; i < 10; i++ ) {   v1.push_back( i ); } vector v2; v2.assign( v1.begin(), v1.end() ); for( int i = 0; i < v2.size(); i++ ) {   cout << v2[i] << " "; } cout << endl;

When run, the above code displays the following output:

 0 1 2 3 4 5 6 7 8 9

  #include   TYPE& at( size_type loc );  const TYPE& at( size_type loc ) const;

The at() function returns a reference to the element in the vector at index loc. The at() function is safer than the [] operator, because it won‘t let you reference items outside the bounds of the vector.

For example, consider the following code:

 vector v( 5, 1 ); for( int i = 0; i < 10; i++ ) {   cout << "Element " << i << " is " << v[i] << endl; }

This code overrunns the end of the vector, producing potentially dangerous results. The following code would be much safer:

 vector v( 5, 1 ); for( int i = 0; i < 10; i++ ) {   cout << "Element " << i << " is " << v.at(i) << endl; }

Instead of attempting to read garbage values from memory, the at() function will realize that it is about to overrun the vector and will throw an exception.

  #include   TYPE& back();  const TYPE& back() const;

The back() function returns a reference to the last element in the vector.

For example:

 vector v; for( int i = 0; i < 5; i++ ) {   v.push_back(i); } cout << "The first element is " << v.front()      << " and the last element is " << v.back() << endl;

This code produces the following output:

 The first element is 0 and the last element is 4

The back() function runs in constant time.

  #include   iterator begin();  const_iterator begin() const;

The function begin() returns an iterator to the first element of the vector. begin() should run in constant time.

For example, the following code uses begin() to initialize an iterator that is used to traverse a list:

   // Create a list of characters   list charList;   for( int i=0; i < 10; i++ ) {     charList.push_front( i + 65 );   }   // Display the list   list::iterator theIterator;   for( theIterator = charList.begin(); theIterator != charList.end(); theIterator++ ) {     cout << *theIterator;   }

  #include   size_type capacity() const;

The capacity() function returns the number of elements that the vector can hold before it will need to allocate more space.

For example, the following code uses two different methods to set the capacity of two vectors. One method passes an argument to the constructor that suggests an initial size, the other method calls the reserve function to achieve a similar goal:

 vector v1(10); cout << "The capacity of v1 is " << v1.capacity() << endl; vector v2; v2.reserve(20); cout << "The capacity of v2 is " << v2.capacity() << endl;

When run, the above code produces the following output:

 The capacity of v1 is 10 The capacity of v2 is 20

C++ containers are designed to grow in size dynamically. This frees the programmer from having to worry about storing an arbitrary number of elements in a container. However, sometimes the programmer can improve the performance of her program by giving hints to the compiler about the size of the containers that the program will use. These hints come in the form of the reserve() function and the constructor used in the above example, which tell the compiler how large the container is expected to get.

The capacity() function runs in constant time.

  #include   void clear();

The function clear() deletes all of the elements in the vector. clear() runs in linear time.

  #include   bool empty() const;

The empty() function returns true if the vector has no elements, false otherwise.

For example, the following code uses empty() as the stopping condition on a (C/C++ Keywords) while loop to clear a vector and display its contents in reverse order:

 vector v; for( int i = 0; i < 5; i++ ) {   v.push_back(i); } while( !v.empty() ) {   cout << v.back() << endl;   v.pop_back(); }

  #include   iterator end();  const_iterator end() const;

The end() function returns an iterator just past the end of the vector.

Note that before you can access the last element of the vector using an iterator that you get from a call to end(), you‘ll have to decrement the iterator first.

For example, the following code uses begin() and end() to iterate through all of the members of a vector:

 vector v1( 5, 789 ); vector::iterator it; for( it = v1.begin(); it != v1.end(); it++ ) {   cout << *it << endl; }

The iterator is initialized with a call to begin(). After the body of the loop has been executed, the iterator is incremented and tested to see if it is equal to the result of calling end(). Since end() returns an iterator pointing to an element just after the last element of the vector, the loop will only stop once all of the elements of the vector have been displayed.

end() runs in constant time.

  #include   iterator erase( iterator loc );  iterator erase( iterator start, iterator end );

The erase() function either deletes the element at location loc, or deletes the elements between start and end. The return value is the element after the last element erased.

The first version of erase (the version that deletes a single element at location loc) runs in constant time for lists and linear time for vectors, dequeues, and strings. The multiple-element version of erase always takes linear time.

For example:

 // Create a vector, load it with the first ten characters of the alphabet vector alphaVector; for( int i=0; i < 10; i++ ) {   alphaVector.push_back( i + 65 ); } int size = alphaVector.size(); vector::iterator startIterator; vector::iterator tempIterator; for( int i=0; i < size; i++ ) {   startIterator = alphaVector.begin();   alphaVector.erase( startIterator );   // Display the vector   for( tempIterator = alphaVector.begin(); tempIterator != alphaVector.end(); tempIterator++ ) {     cout << *tempIterator;   }   cout << endl; }

That code would display the following output:

 BCDEFGHIJ CDEFGHIJ DEFGHIJ EFGHIJ FGHIJ GHIJ HIJ IJ J

In the next example, erase() is called with two iterators to delete a range of elements from a vector:

 // create a vector, load it with the first ten characters of the alphabet vector alphaVector; for( int i=0; i < 10; i++ ) {   alphaVector.push_back( i + 65 ); } // display the complete vector for( int i = 0; i < alphaVector.size(); i++ ) {   cout << alphaVector[i]; } cout << endl; // use erase to remove all but the first two and last three elements // of the vector alphaVector.erase( alphaVector.begin()+2, alphaVector.end()-3 ); // display the modified vector for( int i = 0; i < alphaVector.size(); i++ ) {   cout << alphaVector[i]; } cout << endl;

When run, the above code displays:

 ABCDEFGHIJ ABHIJ

  #include   TYPE& front();  const TYPE& front() const;

The front() function returns a reference to the first element of the vector, and runs in constant time.

  #include   iterator insert( iterator loc, const TYPE& val );  void insert( iterator loc, size_type num, const TYPE& val );  template void insert( iterator loc, input_iterator start, input_iterator end );

The insert() function either:

• inserts val before loc, returning an iterator to the element inserted,
• inserts num copies of val before loc, or
• inserts the elements from start to end before loc.

For example:

 // Create a vector, load it with the first 10 characters of the alphabet vector alphaVector; for( int i=0; i < 10; i++ ) {   alphaVector.push_back( i + 65 ); } // Insert four C‘s into the vector vector::iterator theIterator = alphaVector.begin(); alphaVector.insert( theIterator, 4, ‘C‘ ); // Display the vector for( theIterator = alphaVector.begin(); theIterator != alphaVector.end(); theIterator++ )    {   cout << *theIterator; }

This code would display:

 CCCCABCDEFGHIJ

  #include   size_type max_size() const;

The max_size() function returns the maximum number of elements that the vector can hold.

  #include   void pop_back();

The pop_back() function removes the last element of the vector.

pop_back() runs in constant time.

  #include   void push_back( const TYPE& val );

The push_back() function appends val to the end of the vector.

For example, the following code puts 10 integers into a list:

   list the_list;   for( int i = 0; i < 10; i++ )     the_list.push_back( i );

When displayed, the resulting list would look like this:

 0 1 2 3 4 5 6 7 8 9

push_back() runs in constant time.

  #include   reverse_iterator rbegin();  const_reverse_iterator rbegin() const;

The rbegin() function returns a reverse_iterator to the end of the current vector.

rbegin() runs in constant time.

  #include   reverse_iterator rend();  const_reverse_iterator rend() const;

The function rend() returns a reverse_iterator to the beginning of the current vector.

rend() runs in constant time.

  #include   void reserve( size_type size );

The reserve() function sets the capacity of the vector to at least size.

reserve() runs in linear time.

  #include   void resize( size_type num, const TYPE& val = TYPE() );

The function resize() changes the size of the vector to size. If val is specified then any newly-created elements will be initialized to have a value of val.

This function runs in linear time.

  #include   size_type size() const;

The size() function returns the number of elements in the current vector.

  #include   void swap( const container& from );

The swap() function exchanges the elements of the current vector with those of from. This function operates in constant time.

For example, the following code uses the swap() function to exchange the values of two strings:

   string first( "This comes first" );   string second( "And this is second" );   first.swap( second );   cout << first << endl;   cout << second << endl;

The above code displays:

   And this is second   This comes first

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