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Boost.MultiIndex Examples



Contents

Example 1: basic usage

See source code.

Basic program showing the multi-indexing capabilities of Boost.MultiIndex with an admittedly boring set of employee records.

Example 2: using functions as keys

See source code.

Usually keys assigned to an index are based on a member variable of the element, but key extractors can be defined which take their value from a member function or a global function. This has some similarity with the concept of calculated keys supported by some relational database engines. The example shows how to use the predefined const_mem_fun and global_fun key extractors to deal with this situation.

Keys based on functions usually will not be actual references, but rather the temporary values resulting from the invocation of the member function used. This implies that modify_key cannot be applied to this type of extractors, which is a perfectly logical constraint anyway.

Example 3: constructing multi_index_containers with ctor_args_list

See source code.

We show a practical example of usage of multi_index_container::ctor_arg_list, whose definition and purpose are explained in the tutorial. The program groups a sorted collection of numbers based on identification through modulo arithmetics, by which x and y are equivalent if (x%n)==(y%n), for some fixed n.

Example 4: bidirectional map

See source code.

This example shows how to construct a bidirectional map with multi_index_container. By a bidirectional map we mean a container of (const FromType,const ToType) pairs such that no two elements exists with the same first or second component (std::map only guarantees uniqueness of the first component). Fast lookup is provided for both keys. The program features a tiny Spanish-English dictionary with online query of words in both languages.

This bidirectional map can be considered as a primitive precursor to the full-fledged container provided by Boost.Bimap.

Example 5: sequenced indices

See source code.

The combination of a sequenced index with an index of type ordered_non_unique yields a list-like structure with fast lookup capabilities. The example performs some operations on a given text, like word counting and selective deletion of some words.

Example 6: complex searches and foreign keys

See source code.

This program illustrates some advanced techniques that can be applied for complex data structures using multi_index_container. Consider a car_model class for storing information about automobiles. On a first approach, car_model can be defined as:

struct car_model
{
  std::string model;
  std::string manufacturer;
  int         price;
};

This definition has a design flaw that any reader acquainted with relational databases can easily spot: The manufacturer member is duplicated among all cars having the same manufacturer. This is a waste of space and poses difficulties when, for instance, the name of a manufacturer has to be changed. Following the usual principles in relational database design, the appropriate design involves having the manufactures stored in a separate multi_index_container and store pointers to these in car_model:

struct car_manufacturer
{
  std::string name;
};

struct car_model
{
  std::string             model;
  const car_manufacturer* manufacturer;
  int                     price;
};

Although predefined Boost.MultiIndex key extractors can handle many situations involving pointers (see advanced features of Boost.MultiIndex key extractors in the tutorial), this case is complex enough that a suitable key extractor has to be defined. The following utility cascades two key extractors:

template<class KeyExtractor1,class KeyExtractor2>
struct key_from_key
{
public:
  typedef typename KeyExtractor1::result_type result_type;

  key_from_key(
    const KeyExtractor1& key1_=KeyExtractor1(),
    const KeyExtractor2& key2_=KeyExtractor2()):
    key1(key1_),key2(key2_)
  {}

  template<typename Arg>
  result_type operator()(Arg& arg)const
  {
    return key1(key2(arg));
  }

private:
  KeyExtractor1 key1;
  KeyExtractor2 key2;
};

so that access from a car_model to the name field of its associated car_manufacturer can be accomplished with

key_from_key<
  member<car_manufacturer,const std::string,&car_manufacturer::name>,
  member<car_model,const car_manufacturer *,&car_model::manufacturer>
>

The program asks the user for a car manufacturer and a range of prices and returns the car models satisfying these requirements. This is a complex search that cannot be performed on a single operation. Broadly sketched, one procedure for executing the selection is:

  1. Select the elements with the given manufacturer by means of equal_range,
  2. feed these elements into a multi_index_container sorted by price,
  3. select by price using lower_bound and upper_bound;
or alternatively:
  1. Select the elements within the price range with lower_bound and upper_bound,
  2. feed these elements into a multi_index_container sorted by manufacturer,
  3. locate the elements with given manufacturer using equal_range.
An interesting technique developed in the example lies in the construction of the intermediate multi_index_container. In order to avoid object copying, appropriate view types are defined with multi_index_containers having as elements pointers to car_models instead of actual objects. These views have to be supplemented with appropriate dereferencing key extractors.

Example 7: composite keys

See source code.

Boost.MultiIndex composite_key construct provides a flexible tool for creating indices with non-trivial sorting criteria. The program features a rudimentary simulation of a file system along with an interactive Unix-like shell. A file entry is represented by the following structure:

struct file_entry
{
  std::string       name;
  unsigned          size;
  bool              is_dir; // true if the entry is a directory
  const file_entry* dir;    // directory this entry belongs in
};

Entries are kept in a multi_index_container maintaining two indices with composite keys:

The reason that the order is made firstly by the directory in which the files are located obeys to the local nature of the shell commands, like for instance ls. The shell simulation only has three commands: The program exits when the user presses the Enter key at the command prompt.

The reader is challenged to add more functionality to the program; for instance:

Example 8: hashed indices

See source code.

Hashed indices can be used as an alternative to ordered indices when fast lookup is needed and sorting information is of no interest. The example features a word counter where duplicate entries are checked by means of a hashed index. Confront the word counting algorithm with that of example 5.

Example 9: serialization and MRU lists

See source code.

A typical application of serialization capabilities allows a program to restore the user context between executions. The example program asks the user for words and keeps a record of the ten most recently entered ones, in the current or in previous sessions. The serialized data structure, sometimes called an MRU (most recently used) list, has some interest on its own: an MRU list behaves as a regular FIFO queue, with the exception that, when inserting a preexistent entry, this does not appear twice, but instead the entry is moved to the front of the list. You can observe this behavior in many programs featuring a "Recent files" menu command. This data structure is implemented with multi_index_container by combining a sequenced index and an index of type hashed_unique.

Example 10: random access indices

See source code.

The example resumes the text container introduced in example 5 and shows how substituting a random access index for a sequenced index allows for extra capabilities like efficient access by position and calculation of the offset of a given element into the container.

Example 11: index rearrangement

See source code.

There is a relatively common piece of urban lore claiming that a deck of cards must be shuffled seven times in a row to be perfectly mixed. The statement derives from the works of mathematician Persi Diaconis on riffle shuffling: this shuffling technique involves splitting the deck in two packets roughly the same size and then dropping the cards from both packets so that they become interleaved. It has been shown that when repeating this procedure seven times the statistical distribution of cards is reasonably close to that associated with a truly random permutation. A measure of "randomness" can be estimated by counting rising sequences: consider a permutation of the sequence 1,2, ... , n, a rising sequence is a maximal chain of consecutive elements m, m+1, ... , m+r such that they are arranged in ascending order. For instance, the permutation 125364789 is composed of the two rising sequences 1234 and 56789, as becomes obvious by displaying the sequence like this, 125364789. The average number of rising sequences in a random permutation of n elements is (n+1)/2: by contrast, after a single riffle shuffle of an initially sorted deck of cards, there cannot be more than two rising sequences. The average number of rising sequences approximates to (n+1)/2 as the number of consecutive riffle shuffles increases, with seven shuffles yielding a close result for a 52-card poker deck. Brad Mann's paper "How many times should you shuffle a deck of cards?" provides a rigorous yet very accessible treatment of this subject.

The example program estimates the average number of rising sequences in a 52-card deck after repeated riffle shuffling as well as applying a completely random permutation. The deck is modeled by the following container:

multi_index_container<
  int,
  indexed_by<
    random_access<>,
    random_access<> 
  >
>
where the first index stores the current arrangement of the deck, while the second index is used to remember the start position. This representation allows for an efficient implementation of a rising sequences counting algorithm in linear time. rearrange is used to apply to the deck a shuffle performed externally on an auxiliary data structure.

Example 12: using Boost.Interprocess allocators

See source code.

Boost.MultiIndex supports special allocators such as those provided by Boost.Interprocess, which allows for multi_index_containers to be placed in shared memory. The example features a front-end to a small book database implemented by means of a multi_index_container stored in a Boost.Interprocess memory mapped file. The reader can verify that several instances of the program correctly work simultaneously and immediately see the changes to the database performed by any other instance.




Revised November 18th 2019

© Copyright 2003-2019 Joaquín M López Muñoz. Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)