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Iterators can be projected to any of the three views of the bimap. A bimap
provides three member functions to cope with projection: project_left
, project_right
and project_up
, with projects
iterators to the left map view, the right
map view and the collection of relations view.
These functions take any iterator from the bimap and retrieve an iterator
over the projected view pointing to the same element.
Here is an example that uses projection:
typedef bimap<std::string,multiset_of<int,std::greater<int> > > bm_type; bm_type bm; bm.insert( bm_type::value_type("John" ,34) ); bm.insert( bm_type::value_type("Peter",24) ); bm.insert( bm_type::value_type("Mary" ,12) ); // Find the name of the next younger person after Peter bm_type::left_const_iterator name_iter = bm.left.find("Peter"); bm_type::right_const_iterator years_iter = bm.project_right(name_iter); ++years_iter; std::cout << "The next younger person after Peter is " << years_iter->second;
These functions are members of the views of a bimap that are not founded in their standard counterparts.
The replace
family member
functions performs in-place replacement of a given element as the following
example shows:
typedef bimap< int, std::string > bm_type; bm_type bm; bm.insert( bm_type::value_type(1,"one") ); // Replace (1,"one") with (1,"1") using the right map view { bm_type::right_iterator it = bm.right.find("one"); bool successful_replace = bm.right.replace_key( it, "1" ); assert( successful_replace ); } bm.insert( bm_type::value_type(2,"two") ); // Fail to replace (1,"1") with (1,"two") using the left map view { assert( bm.size() == 2 ); bm_type::left_iterator it = bm.left.find(1); bool successful_replace = bm.left.replace_data( it, "two" ); assert( ! successful_replace ); assert( bm.size() == 2 ); }
replace
functions performs
this substitution in such a manner that:
bimap
remains unchanged if some exception (originated by the system or the
user's data types) is thrown.
replace
functions are powerful
operations not provided by standard STL containers, and one that is specially
handy when strong exception-safety is required.
The observant reader might have noticed that the convenience of replace
comes at a cost: namely the whole element has to be copied twice
to do the updating (when retrieving it and inside replace
).
If elements are expensive to copy, this may be quite a computational cost
for the modification of just a tiny part of the object. To cope with this
situation, Boost.Bimap provides an alternative updating mechanism: modify
functions.
modify
functions accepts
a functor (or pointer to function) taking a reference to the data to be
changed, thus eliminating the need for spurious copies. Like replace
functions, modify
functions does preserve the internal orderings of all the indices of the
bimap
. However, the semantics
of modify functions are not entirely equivalent to replace functions. Consider
what happens if a collision occurs as a result of modifying the element,
i.e. the modified element clashes with another with respect to some unique
view. In the case of replace
functions, the original value is kept and the method returns without altering
the container, but modify
functions cannot afford such an approach, since the modifying functor leaves
no trace of the previous value of the element. Integrity constraints thus
lead to the following policy: when a collision happens in the process of
calling a modify functions, the element is erased and the method returns
false. This difference in behavior between replace
and modify
functions has
to be considered by the programmer on a case-by-case basis.
Boost.Bimap defines new placeholders named _key
and _data
to allow a sounder
solution. You have to include <boost/bimap/support/lambda.hpp>
to use them.
typedef bimap< int, std::string > bm_type; bm_type bm; bm.insert( bm_type::value_type(1,"one") ); // Modify (1,"one") to (1,"1") using the right map view { bm_type::right_iterator it = bm.right.find("one"); bool successful_modify = bm.right.modify_key( it , _key = "1" ); assert( successful_modify ); } bm.insert( bm_type::value_type(2,"two") ); // Fail to modify (1,"1") to (1,"two") using the left map view { assert( bm.size() == 2 ); bm_type::left_iterator it = bm.left.find(1); bool successful_modify = bm.left.modify_data( it, _data = "two" ); assert( ! successful_modify ); assert( bm.size() == 1 ); }
Standard lower_bound
and
upper_bound
functions can
be used to lookup for all the elements in a given range.
Suppose we want to retrieve the elements from a bimap<int,std::string>
where the left value is in the range
[20,50]
typedef bimap<int,std::string> bm_type; bm_type bm; // ... bm_type::left_iterator iter_first = bm.left.lower_bound(20); bm_type::left_iterator iter_second = bm.left.upper_bound(50); // range [iter_first,iter_second) contains the elements in [20,50]
Subtle changes to the code are required when strict inequalities are considered. To retrieve the elements greater than 20 and less than 50, the code has to be rewritten as
bm_type::left_iterator iter_first = bm.left.upper_bound(20); bm_type::left_iterator iter_second = bm.left.lower_bound(50); // range [iter_first,iter_second) contains the elements in (20,50)
To add to this complexity, the careful programmer has to take into account
that the lower and upper bounds of the interval searched be compatible:
for instance, if the lower bound is 50 and the upper bound is 20, the iterators
iter_first
and iter_second
produced by the code above
will be in reverse order, with possibly catastrophic results if a traversal
from iter_first
to iter_second
is tried. All these details
make range searching a tedious and error prone task.
The range member function, often in combination with lambda expressions, can greatly help alleviate this situation:
typedef bimap<int,std::string> bm_type; bm_type bm; // ... bm_type::left_range_type r; r = bm.left.range( 20 <= _key, _key <= 50 ); // [20,50] r = bm.left.range( 20 < _key, _key < 50 ); // (20,50) r = bm.left.range( 20 <= _key, _key < 50 ); // [20,50)
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_key is a Boost.Lambda placeholder. To use it you have to include
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range
simply accepts predicates
specifying the lower and upper bounds of the interval searched. Please
consult the reference for a detailed explanation of the permissible predicates
passed to range.
One or both bounds can be omitted with the special unbounded marker:
r = bm.left.range( 20 <= _key, unbounded ); // [20,inf) r = bm.left.range( unbounded , _key < 50 ); // (-inf,50) r = bm.left.range( unbounded , unbounded ); // (-inf,inf)