STL Overview

STL Overview Prof. Brinton Gordon College

Standard Template Library (STL) • Part of ISO-OSI Standard C++ Library 1998 • Object oriented programming is about reuse • STL has many reusable components • Divided into • Containers - manage collections of objects • Iterators - step through the elements of collections • Algorithms - used to process the elements of collections

Introduction to Containers • Three types of containers • sequence containers - ordered collections vector, deque, list • associative containers - sorted collections set, multiset, map, multimap • container adapters Stacks, queues, priority queues • Near-containers - similar to containers, without all the capabilities • C-like arrays • string • bitset- for maintaining sets of 1/0 flag values • valarray - high-speed mathematical vector operations • The containers have similar functions

Introduction to Containers • vector direct access to any element • deque rapid insertion at front or back direct access to any element • list rapid insertion and deletion anywhere • set rapid lookup, no duplicates • multiset rapid lookup, duplicates • map, multimap store key/value pairs • stack last-in-first-out • queue first-in-first-out • priority_queue highest priority element is first

Introduction to Containers • Common member functions of all STL containers: constructors, destructors assignment, all comparison operators swap empty max_size size • Use if(c.empty()) not if(c.size() == 0)

Introduction to Iterators • Iterators are similar to pointers • point to element in a container • iterator operators uniform for all containers • * dereferences, ++ advances pointer • container.begin() returns iterator pointing to first element • container.end() returns iterator pointing after last element it for(it = c.begin(); it != c.end(); it++) { *it… }

Iterator Categories • Bidirectional iterators • Iterate in 2 directions: p++ or p-- • list, set, multiset, map, multimap • Use != instead of < or > in loops • Random access iterators • Have all properties of bidirectional iterators • Can also perform random access • +, -, <, > • vector, deque, strings

Constness of Iterators • Examplesvector<int>::iterator it = v.begin();vector<int>::const_iterator cit = v.begin();*cit = 24; // does not compile *it = 24; // okvoid fct(const vector<int>& v) { vector<int>::iterator it; it = v.begin(); // does not compile}

Constness of Iterators • Examples (Fixed) vector<int>::iterator it = v.begin();vector<int>::iterator cit = v.begin();*cit = 24; // ok *it = 24; // okvoid fct(const vector<int>& v) { vector<int>::const_iterator it; it = v.begin(); // ok }

Iterator Adapters • Everything that behaves like an iterator is an iterator • Insert iterator (inserters) • Stream iterator - allow you to use a stream as a source or dest of an algorithm. • Reverse iterators • Example:list<Point>::reverse_iterator r1 = L.rbegin(), r2 = L.rend();

Iterator Adapters vector<int> coll; back_insert_iterator<vector<int> > iter(coll); *iter = 1; iter++; *iter = 2; iter++; *iter = 3; PRINT_ELEMENTS(coll); back_inserter(coll) = 44; back_inserter(coll) = 55; PRINT_ELEMENTS(coll); coll.reserve(2*coll.size()); copy (coll.begin(), coll.end(), // source back_inserter(coll)); // destination PRINT_ELEMENTS(coll); Results: 1 2 3 1 2 3 44 55 1 2 3 44 55 1 2 3 44 55

Introduction to Algorithms • STL algorithms used generically across containers: • operate on elements indirectly through iterators • often operate on sequences of elements defined by pairs of iterators • algorithms often return iterators, such as find() • premade algorithms save programmers time and effort

Sequence Containers • Three sequence containers • vector - based on arrays • deque - based on arrays • list - robust linked list

vector Sequence Container • vector • #include <vector> • data structure with contiguous memory locations • use the subscript operator [] • used when data must be sorted and easily accessible • when memory exhausted • allocates a larger, contiguous area of memory • copies itself there • deallocates the old memory • has a random access iterator

vector Sequence Container • Declarations • vector <type> v; • vector <type> v(7812); • template <class It>vector<type> v(It begin, It end); • type- int, float, Point, whatsoever • Iterators: • vector<type>::const_iterator it; vector<type>::iterator it = v.begin(); *(it1 + 5) = 34;

vector Sequence Container (II) • vector functions, for vector object v v.push_back(value) - add element to end v.size() - current size of vector v.capacity() - how much vector can hold before reallocation v.reserve(n) - allow vector to avoid reallocation v.insert( pointer, value ) - inserts value before pointer.

vector Sequence Container (III) • vector functions and operations v.erase( pointer) • remove element from container v.erase( pointer1, pointer2) • remove elements starting from pointer1 and up to (not including) pointer2. v.clear() • erases entire container. v[elementNumber] =value; • assign value to an element v.at[elementNumber] =value; • as above, with range checking • throws out_of_bounds exception

list Sequence Container • listcontainer • #include <list> • efficient insertion/deletion anywhere in container • doubly-linked list • bidirectional iterators • There exists also a non-standard slist • singly-linked list • forward iterator

list Sequence Container (II) • list functions for listObject and otherObject listObject.sort() • sorts in ascending order listObject.splice(iterator, otherObject); • inserts values from otherObject before location of iterator listObject.merge(otherObject) • removes otherObject and inserts it into listObject, sorted listObject.unique() • removes duplicate elements listObject.swap(otherObject); • exchange contents listObject.assign(iterator1, iterator2) • replaces contents with elements in range of iterators listObject.remove(value) • erases all instances ofvalue

deque Sequence Container • deque ("deek") - double-ended queue • #include <deque> • indexed access using [] • efficient insertion/deletion in front and back • non-contiguous memory: "smarter" pointers • same basic operations as vector • adds push_front / pop_front - insertion/deletion at beginning of deque

Associative Containers • Associative containers • provide direct access to store and retrieve elements via keys (search keys) • 4 types: multiset, set, multimap and map • keys in sorted order • multiset and multimap allow duplicate keys • multimap and map allow keys and associate values

Excursion: Function Objects template <class T> struct less { bool operator()(const T& lhs, const T& rhs) const { return lhs < rhs; } }; less<int> is_smaller; if(is_smaller(45, 34)){..}

multiset Associative Container • multiset - fast storage, retrieval of keys • allows duplicates • Ordering by comparator function object less<type> - sorts keys in ascending order multiset< int, less<int> > integers; • CGAL comparator function objects typedef CGAL::Cartesian<double> K; multiset< K::Point_2, K::Compare_xy_2 > points;

multiset Associative Container (II) • Functions for multiset object msObject • msObject.insert(value) - inserts value • msObject.find(value) - returns iterator to first instance of value, or msObject.end() • msObject.lower_bound(value)- returns iterator to first location ofvalue • msObject.upper_bound(value)- returns iterator to location after last occurrence of value • for a pair object p p = msObject.equal_range(value) • sets first and second to lower_bound and upper_bound for a given value

set Associative Container • set • implementation identical to multiset • unique keys - duplicates ignored and not inserted • supports bidirectional iterators (but not random access) • #include<set>

map Associative Container • map • fast storage/retrieval of unique key/value pairs • #include<map> • one-to-one mapping (duplicates ignored) • use [] to access values for map<int, double> M; M[30] = 4000.21; sets the value of key 30 to 4000.21 • if subscript not in map, creates new key/value pair • Efficiency remark: Use insert to insert, operator[] to update

Non Standard Associative Container • hash_(multi)set, hash_(multi)map • Not part of the standard, but provided by some STLs • REALLY fast storage/retrieval of unique key/value pairs • Based on hashing and not on binary trees • No order, but provide iterators

Container Adapters • container adapters: stack, queue, priority_queue • not first class containers • do not support iterators • do not provide actual data structure • programmer can select implementation of the container adapters • have member functions push() and pop()

stack Adapter • stack • insertions and deletions at one end • last-in-first-out data structure • implemented with vector, list, and deque (default) • #include<stack> • Declarations stack<type, vector<type> > myStack; stack<type, list<type> > myOtherStack; stack<type> anotherStack;

queue Adapter • queue - insertions at back, deletions at front • first-in-first-out data structure • implemented with list or deque • #include<queue> • Functions • push(element) - (push_back) add to end • pop(element) - (pop_front) remove from front • empty() - test for emptiness • size() - returns number of elements • Example: queue <double> values; //create queue values.push(1.2); // values: 1.2 values.push(3.4); // values: 1.2 3.4 values.pop(); // values: 1.2

priority_queue Adapter • insertions in sorted order, deletions from front • implemented with vector or deque • highest priority element always removed first • heapsort puts largest elements at front • less<T> by default, programmer can specify another • Functions • push - (push_back then reorder elements) • pop - (pop_back to remove highest priority element) • size • empty

Algorithms • Before STL • class libraries were incompatible among vendors • algorithms built into container classes • STL separates containers and algorithms • easier to add new algorithms • not member functions of containers, global functions that operate with iterators (reduces the amount of code) • Not necessarily intuitive…not all combinations possible. • General fundamental services on containers: • Searching • Sorting • Copying • Reordering • Modifying • Numeric processing

#include <iostream> #include <vector> #include <algorithm> using namespace std; int main() { vector<int> coll; vector<int>::iterator pos; coll.push_back(2); coll.push_back(5); coll.push_back(4); coll.push_back(1); coll.push_back(6); coll.push_back(3); pos = min_element (coll.begin(), coll.end()); cout << "min: " << *pos << endl; pos = max_element (coll.begin(), coll.end()); cout << "max: " << *pos << endl; sort (coll.begin(), coll.end()); pos = find (coll.begin(), coll.end(), 3); reverse (pos, coll.end()); } Algorithms Example 2 5 4 1 6 3 1 6 1 2 3 4 5 6 1 2 6 5 4 3

Algorithms • Ranges pos = min_element (coll.begin(), coll.end()); • Multiple Ranges if (equal (coll1.begin(), coll1.end(), coll2.begin()) { … } Algorithm Categories: • Nonmodifying - count, for_each, min_element… • Modifying - copy, transform, merge, replace, fill… • Removing - remove, unique… • Mutating - reverse, rotate, random_shuffle… • Sorting - sort_heap, make_heap, sort, … • Algorithms for Sorted Ranges - binary_search, merge, … • Numeric - accumulate, inner_product, …

Non-Modifying Algorithm: for_each void print (int elem) { cout << elem << ' '; } int main() { vector<int> coll; INSERT_ELEMENTS(coll,1,9); // call print() for each element for_each (coll.begin(), coll.end(), print); cout << endl; }

Modifying Algorithm: copy { vector<int> coll1; list<int> coll2; INSERT_ELEMENTS(coll1,1,9); copy (coll1.begin(), coll1.end(), back_inserter(coll2)); copy (coll2.begin(), coll2.end(), ostream_iterator<int>(cout," ")); cout << endl; copy (coll1.rbegin(), coll1.rend(), coll2.begin()); }

Modifying Algorithm: unique int source[] = { 1, 4, 4, 6, 1, 2, 2, 3, 1, 6, 6, 6, 5, 7, 5, 4, 4 }; int sourceNum = sizeof(source)/sizeof(source[0]); list<int> coll; copy (source, source+sourceNum, back_inserter(coll)); list<int>::iterator pos; pos = unique (coll.begin(), coll.end()); copy (coll.begin(), pos, ostream_iterator<int>(cout," " // source)); cout << "\n\n"; copy (source, source+sourceNum, coll.begin()); coll.erase (unique (coll.begin(), coll.end(), greater<int>()), coll.end());

accumulate, transform • list<int> L(..);int sum = accumulate(L.begin(), L.end(), 0, plus<int>()); • transform(istream_iterator<Point>(cin), istream_iterator<Point>(), ostream_iterator<double>(cout), mem_fun_ref(Point::x));

Basic Searching Algorithms • find(iterator1, iterator2, value) • returns iterator pointing to first instance of value • find_if(iterator1, iterator2, function) • like find, but returns an iterator whenfunction returns true. • binary_search(iterator1, iterator2, value) • searches an ascending sorted list for value using a binary search

Sorting Algorithms • sort(begin, end) • partial_sort(begin, begin+N, end) • finds first N and sorts them • nth_element(begin, begin+N, end) • finds first N, not sorted • partition(begin, end, function) • splits in two intervals • stable_sort, stable_partition • Remarks • All take optionaly a comparison function • std::sort is faster than clib sort

equal, mismatch,lexicographical_compare • Functions to compare sequences of values • equal • returns true if sequences are equal (uses ==) • returns false if of unequal length equal(iterator1, iterator2, iterator3); • compares sequence from iterator1 up toiterator2with the sequence beginning at iterator3 • Containers can be of different types

fill, fill_n, generate, generate_n • STL functions, change containers. • fill - changes a range of elements (from iterator1 to iterator2) tovalue • fill(iterator1, iterator2, value); • fill_n - changes specified number of elements, starting at iterator1 • fill_n(iterator1, quantity, value); • generate - like fill, but calls a function for value • generate(iterator1, iterator2, function); • generate_n - like fill_n, but calls function for value • generate(iterator1, quantity, value)

swap, iter_swap and swap_ranges • swap(element1, element2) - exchanges two values swap( a[ 0 ], a[ 1 ] ); • iter_swap(iterator1, iterator2) - exchanges the values to which the iterators refer • swap_ranges(iterator1, iterator2, iterator3) - swap the elements from iterator1 to iterator2 with the elements beginning at iterator3

copy_backward, merge, unique, reverse • copy_backward(iterator1, iterator2, iterator3) • copy the range of elements fromiterator1 to iterator2 into iterator3, but in reverse order. • merge(iter1, iter2, iter3, iter4, iter5) • ranges iter1-iter2 and iter3-iter4 must be sorted in ascending order. • merge copies both lists into iter5, in ascending order. • unique(iter1, iter2) - removes duplicate elements from a sorted list, returns iterator to new end of sequence. • reverse(iter1, iter2)- reverses elements in the range of iter1 to iter2.

Remove does (not) Remove • Member function:L.remove(Point(0,0)); • Algorithm moves at end:list<Point> L(istream_iterator<Point>(cin), istream_iterator<Point>());list<Point>::iterator eit;eit = remove(L.begin(), L.end(), Point(0,0));L.erase(eit, L.end());

Other Features of the STL • Streams • strings, wide strings • locales (for internationalization) • numerical • valarray

References • N.M. Josuttis, The C++ Standard Library, Addison-Wesley 2001

STL Overview

STL Overview

Presentation Transcript

STL Algorithms

STL concepts

Overview of STL Function Objects

Advanced STL

Basic STL

STL

STL Library - Overview

C++ STL

Quick Overview of STL

The STL

STL Overview

STL Overview

STL Algorithms