Iterator Concepts

An Iterator is a restricted pointer-like object pointing into a vector or matrix container.

Indexed Bidirectional Iterator

Description

An Indexed Bidirectional Iterator is an iterator of a container that can be dereferenced, incremented, decremented and carries index information.

Refinement of

Assignable, Equality Comparable, Default Constructible.

Associated types

Value type	The type of the value obtained by dereferencing a Indexed Bidirectional Iterator
Container type	The type of the container a Indexed Bidirectional Iterator points into.

Notation

`I`	A type that is a model of Indexed Bidirectional Iterator
`T`	The value type of `I`
`C`	The container type of `I`
`it`, `itt, it1`, `it2`	Objects of type `I`
`t`	Object of type `T`
`c`	Object of type `C`

Definitions

A Indexed Bidirectional Iterator may be mutable, meaning that the values referred to by objects of that type may be modified, or constant , meaning that they may not. If an iterator type is mutable, this implies that its value type is a model of Assignable; the converse, though, is not necessarily true.

A Indexed Bidirectional Iterator may have a singular value, meaning that the results of most operations, including comparison for equality, are undefined. The only operation that is guaranteed to be supported is assigning a nonsingular iterator to a singular iterator.

A Indexed Bidirectional Iterator may have a dereferenceable value, meaning that dereferencing it yields a well-defined value. Dereferenceable iterators are always nonsingular, but the converse is not true.

An Indexed Bidirectional Iterator is past-the-end if it points beyond the last element of a container. Past-the-end values are nonsingular and nondereferenceable.

Valid expressions

In addition to the expressions defined for Assignable, Equality Comparable and Default Constructible, the following expressions must be valid.

Name	Expression	Type requirements	Return type
Default constructor	`I it`
Dereference	`*it`		Convertible to `T`.
Dereference assignment	`*it = t`	`I` is mutable.
Member access	`it->m`	`T` is a type for which `t.m` is defined.
Preincrement	`++ it`		`I &`
Postincrement	`it ++`		`I`
Predecrement	`-- it`		`I &`
Postdecrement	`it --`		`I`
Index	`it.index ()`		`C::size_type`

Expression Semantics

Semantics of an expression is defined only where it differs from, or is not defined in, Assignable, Equality Comparable and Default Constructible.

Name	Expression	Precondition	Semantics	Postcondition
Default constructor	`I it`			`it` is singular.
Dereference	`*it`	`it` is dereferenceable.
Dereference assignment	`*it = t`	Same as for `*it`.		`*it` is a copy of t.
Member access	`it->m`	`it` is dereferenceable.	Equivalent to `(*it).m`
Preincrement	`++ it`	`it` is dereferenceable.	`it` is modified to point to the next element.	`it` is dereferenceable or past-the-end. `&it == &++ it`. If `it1 == it2`, then `++ it1 == ++ it2`.
Postincrement	`it ++`	Same as for `++ it`.	Equivalent to `{ I itt = it; ++ it; return itt; }`	`it` is dereferenceable or past-the-end.
Predecrement	`-- it`	`it` is dereferenceable or past-the-end. There exists a dereferenceable iterator `itt` such that `it == ++ itt`.	`it` is modified to point to the previous element.	`it` is dereferenceable. `&it = &-- it`. If `it1 == it2`, then `-- it1 == -- it2`. If `it2` is dereferenceable and `it1 == ++it2`, then `--it1 == it2`.
Postdecrement	`it --`	Same as for -- `it`.	Equivalent to `{ I itt = it; -- it; return itt; }`	`it` is dereferenceable.
Index	`it.index ()`	`it` is dereferenceable.	`it.index () >= 0` and `it.index () < it ().size ()`	If `it1 == it2`, then `it1.index () == it2.index ()`. If `it1 == it2`, then `it1.index () < (++ it2).index ()`. If `it1 == it2`, then `it1.index () > (-- it2).index ()`.

Complexity guarantees

The complexity of operations on indexed bidirectional iterators is guaranteed to be amortized constant time.

Invariants

Identity	`it1 == it2` if and only if `&it1 == &it2`.
Symmetry of increment and decrement	If `it` is dereferenceable, then `++ it; --it;` is a null operation. Similarly, `-- it; ++ it;` is a null operation.
Relation between iterator index and container element operator	If `it` is dereferenceable, `*it == it () (it.index ())`.

Models

sparse_vector::iterator

Indexed Random Access Iterator

Description

An Indexed Random Access Iterator is an iterator of a container that can be dereferenced, moved forward, moved backward and carries index information.

Refinement of

LessThanComparable, Indexed Bidirectional Iterator .

Associated types

Value type	The type of the value obtained by dereferencing a Indexed Random Access Iterator
Container type	The type of the container a Indexed Random Access Iterator points into.

Notation

`I`	A type that is a model of Indexed Random Access Iterator
`T`	The value type of `I`
`C`	The container type of `I`
`it`, `itt, it1`, `it2`	Objects of type `I`
`t`	Object of type `T`
`n`	Object of type `C::difference_type`

Definitions

An Indexed Random Access Iterator it1 is reachable from an Indexed Random Access Iterator it2 if, after applying operator ++ to it2 a finite number of times, it1 == it2.

Valid expressions

In addition to the expressions defined for Indexed Bidirectional Iterator , the following expressions must be valid.

Name	Expression	Type requirements	Return type
Forward motion	`it += n`		`I &`
Iterator addition	`it + n`		`I`
Backward motion	`i -= n`		`I &`
Iterator subtraction	`it - n`		`I`
Difference	`it1 - it2`		`C::difference_type`
Element operator	`it [n]`		Convertible to `T`.
Element assignment	`it [n] = t`	`I` is mutable	Convertible to `T`.

Expression Semantics

Semantics of an expression is defined only where it differs from, or is not defined in, Indexed Bidirectional Iterator .

Name	Expression	Precondition	Semantics	Postcondition
Forward motion	`it += n`	Including `it` itself, there must be `n` dereferenceable or past-the-end iterators following or preceding `it`, depending on whether `n` is positive or negative.	If `n > 0`, equivalent to executing `++ it` `n` times. If `n < 0`, equivalent to executing `-- it` `n` times. If `n == 0`, this is a null operation.	`it` is dereferenceable or past-the-end.
Iterator addition	`it + n`	Same as for `i += n`.	Equivalent to `{ I itt = it; return itt += n; }`	Result is dereferenceable or past-the-end.
Backward motion	`it -= n`	Including `it` itself, there must be `n` dereferenceable or past-the-end iterators preceding or following `it`, depending on whether `n` is positive or negative.	Equivalent to `it += (-n)`.	`it` is dereferenceable or past-the-end.
Iterator subtraction	`it - n`	Same as for `i -= n`.	Equivalent to `{ I itt = it; return itt -= n; }`	Result is dereferenceable or past-the-end.
Difference	`it1 - it2`	Either `it1` is reachable from `it2` or `it2` is reachable from `it1`, or both.	Returns a number `n` such that `it1 == it2 + n`
Element operator	`it [n]`	`it + n` exists and is dereferenceable.	Equivalent to `*(it + n)`
Element assignment	`i[n] = t`	Same as for `it [n]`.	Equivalent to `*(it + n) = t`

Complexity guarantees

The complexity of operations on indexed random access iterators is guaranteed to be amortized constant time.

Invariants

Symmetry of addition and subtraction	If `it + n` is well-defined, then `it += n; it -= n;` and `(it + n) - n` are null operations. Similarly, if `it - n` is well-defined, then `it -= n; it += n;` and `(it - n) + n` are null operations.
Relation between distance and addition	If `it1 - it2` is well-defined, then `it1 == it2 + (it1 - it2)`.
Reachability and distance	If `it1` is reachable from `it2`, then `it1 - it2 >= 0`.

Models

vector::iterator

Indexed Bidirectional Column/Row Iterator

Description

An Indexed Bidirectional Column/Row Iterator is an iterator of a container that can be dereferenced, incremented, decremented and carries index information.

Refinement of

Assignable, Equality Comparable, Default Constructible.

Associated types

Value type	The type of the value obtained by dereferencing a Indexed Bidirectional Column/Row Iterator
Container type	The type of the container a Indexed Bidirectional Column/Row Iterator points into.

Notation

`I1`	A type that is a model of Indexed Bidirectional Column/Row Iterator
`I2`	A type that is a model of Indexed Bidirectional Row/Column Iterator
`T`	The value type of `I1` and `I2`
`C`	The container type of `I1` and `I2`
`it1`, `it1t, it11`, `it12`	Objects of type `I1`
`it2`, `it2t`	Objects of type `I2`
`t`	Object of type `T`
`c`	Object of type `C`

Definitions

Valid expressions

In addition to the expressions defined for Assignable, Equality Comparable and Default Constructible, the following expressions must be valid.

Name	Expression	Type requirements	Return type
Default constructor	`I1 it`
Dereference	`*it`		Convertible to `T`.
Dereference assignment	`*it = t`	`I1` is mutable.
Member access	`it->m`	`T` is a type for which `t.m` is defined.
Preincrement	`++ it`		`I1 &`
Postincrement	`it ++`		`I1`
Predecrement	`-- it`		`I1 &`
Postdecrement	`it --`		`I1`
Row Index	`it.index1 ()`		`C::size_type`
Column Index	`it.index2 ()`		`C::size_type`
Row/Column Begin	`it.begin ()`		`I2`
Row/Column End	`it.end ()`		`I2`
Reverse Row/Column Begin	`it.rbegin ()`		`reverse_iterator<I2>`
Reverse Row/Column End	`it.rend ()`		`reverse_iterator<I2>`

Expression Semantics

Semantics of an expression is defined only where it differs from, or is not defined in, Assignable, Equality Comparable and Default Constructible.

Name	Expression	Precondition	Semantics	Postcondition
Default constructor	`I1 it`			`it` is singular.
Dereference	`*it`	`it` is dereferenceable.
Dereference assignment	`*it = t`	Same as for `*it`.		`*it` is a copy of t.
Member access	`it->m`	`it` is dereferenceable.	Equivalent to `(*it).m`
Preincrement	`++ it`	`it` is dereferenceable.	`it` is modified to point to the next element of the column/row, i.e. for column iterators holds `it.index1 () < (++ it).index1 ()` and `it.index2 () == (++ it).index2 ()`, for row iterators holds `it.index1 () == (++ it).index1 ()` and `it.index2 () < (++ it).index2 ()`.	`it` is dereferenceable or past-the-end. `&it == &++ it`. If `it1 == it2`, then `++ it1 == ++ it2`.
Postincrement	`it ++`	Same as for `++ it`.	Equivalent to `{ I1 itt = it; ++ it; return itt; }`	`it` is dereferenceable or past-the-end.
Predecrement	`-- it`	`it` is dereferenceable or past-the-end. There exists a dereferenceable iterator `itt` such that `it == ++ itt`.	`it` is modified to point to the previous element of the column/row, i.e. for column iterators holds `it.index1 () > (-- it).index1 ()` and `it.index2 () == (-- it).index2 ()`, for row iterators holds `it.index1 () == (-- it).index1 ()` and `it.index2 () > (-- it).index2 ()`.	`it` is dereferenceable. `&it = &-- it`. If `it1 == it2`, then `-- it1 == -- it2`.
Postdecrement	`it --`	Same as for -- `it`.	Equivalent to `{ I1 itt = it; -- it; return itt; }`	`it` is dereferenceable.
Row Index	`it.index1 ()`	If `it` is a Row iterator then `it` must be dereferenceable.	`it.index1 () >= 0` and `it.index1 () < it () .size1 ()`	If `it1 == it2`, then `it1.index1 () == 12.index1 ()`. If `it1`, `it2` are Row Iterators with `it1 == it2`, then `it1.index1 () < (++ it2`).`index1 ()`. and `it1.index1 () > (-- it2`).`index1 ()`.
Column Index	`it.index2 ()`	If `it` is a Column iterator then `it` must be dereferenceable.	`it.index2 () >= 0` and `it.index2 () < it () .size2 ()`	If `it1 == it2`, then `it1.index2 () == it2`.`index2 ()` . If `it1`, `it2` are Column Iterators with `it1 == i12`, then `it1.index2 () < (++ it2`).`index2 ()`. end `it1.index2 () > (-- it2`).`index2 ()`.
Row/Column Begin	`it.begin ()`	`it` is dereferenceable.	If `it` is a Column Iterator, then `it2 = it.begin ()` is a Row Iterator with `it2.index1 () == it.index1 ()`. If `it` is a Row Iterator, then `it2 = it.begin ()` is a Column Iterator with `it2.index2 () == it.index2 ()`.
Row/Column End	`it.end ()`	`it` is dereferenceable.	If `it` is a Column Iterator, then `it2 = it.end ()` is a Row Iterator with `it2.index1 () == it.index1 ()`. If `it` is a Row Iterator, then `it2 = it.end ()` is a Column Iterator with `it2.index2 () == it.index2 ()`.
Reverse Row/Column Begin	`it.rbegin ()`	`it` is dereferenceable.	Equivalent to `reverse_iterator<I2> (it.end ())`.
Reverse Row/Column End	`it.rend ()`	`it` is dereferenceable.	Equivalent to `reverse_iterator<I2> (it.begin ())`.

Complexity guarantees

The complexity of operations on indexed bidirectional column/row iterators is guaranteed to be logarithmic depending on the size of the container. The complexity of one iterator (depending on the storage layout) can be lifted to be amortized constant time. The complexity of the other iterator (depending on the storage layout and the container) can be lifted to be amortized constant time for the first row/first column respectively.

Invariants

Identity	`it1 == it2` if and only if `&it1 == &it2`.
Symmetry of increment and decrement	If `it` is dereferenceable, then `++ it; --it;` is a null operation. Similarly, `-- it; ++ it;` is a null operation.
Relation between iterator index and container element operator	If `it` is dereferenceable, `*it == it () (it.index1 (), it.index2 ())`
Relation between iterator column/row begin and iterator index	If `it` is a Column Iterator and `it2 = it.begin ()` then `it2.index2 () < it2t.index2 ()` for all `it2t` with `it2t () == it2 ()` and `it2t ().index1 () == it2 ().index1 ()`. If `it` is a Row Iterator and `it2 = it.begin ()` then `it2.index1 () < it2t.index1 ()` for all `it2t` with `it2t () == it2 ()` and `it2t ().index2 () == it2 ().index2 ()`.
Relation between iterator column/row end and iterator index	If `it` is a Column Iterator and `it2 = it.end ()` then `it2.index2 () > it2t.index2 ()` for all `it2t` with `it2t () == it2 ()` and `it2t ().index1 () == it2 ().index1 ()`. If `it` is a Row Iterator and `it2 = it.end ()` then `it2.index1 () > it2t.index1 ()` for all `it2t` with `it2t () == it2 ()` and `it2t ().index2 () == it2 ().index2 ()`.

Models

sparse_matrix::iterator1
sparse_matrix::iterator2

Indexed Random Access Column/Row Iterator

Description

An Indexed Random Access Column/Row Iterator is an iterator of a container that can be dereferenced, incremented, decremented and carries index information.

Refinement of

Indexed Bidirectional Column/Row Iterator .

Associated types

Value type	The type of the value obtained by dereferencing a Indexed Random Access Column/Row Iterator
Container type	The type of the container a Indexed Random Access Column/Row Iterator points into.

Notation

`I`	A type that is a model of Indexed Random Access Column/Row Iterator
`T`	The value type of `I`
`C`	The container type of `I`
`it`, `itt, it1`, `it2`	Objects of type `I`
`t`	Object of type `T`
`c`	Object of type `C`

Definitions

Valid expressions

In addition to the expressions defined for Indexed Bidirectional Column/Row Iterator , the following expressions must be valid.

Name	Expression	Type requirements	Return type
Forward motion	`it += n`		`I &`
Iterator addition	`it + n`		`I`
Backward motion	`i -= n`		`I &`
Iterator subtraction	`it - n`		`I`
Difference	`it1 - it2`		`C::difference_type`
Element operator	`it [n]`		Convertible to `T`.
Element assignment	`it [n] = t`	`I` is mutable	Convertible to `T`.

Expression Semantics

Semantics of an expression is defined only where it differs from, or is not defined in, Indexed Bidirectional Column/Row Iterator .

Name	Expression	Precondition	Semantics	Postcondition
Forward motion	`it += n`	Including `it` itself, there must be `n` dereferenceable or past-the-end iterators following or preceding `it`, depending on whether `n` is positive or negative.	If `n > 0`, equivalent to executing `++ it` `n` times. If `n < 0`, equivalent to executing `-- it` `n` times. If `n == 0`, this is a null operation.	`it` is dereferenceable or past-the-end.
Iterator addition	`it + n`	Same as for `i += n`.	Equivalent to `{ I itt = it; return itt += n; }`	Result is dereferenceable or past-the-end.
Backward motion	`it -= n`	Including `it` itself, there must be `n` dereferenceable or past-the-end iterators preceding or following `it`, depending on whether `n` is positive or negative.	Equivalent to `it += (-n)`.	`it` is dereferenceable or past-the-end.
Iterator subtraction	`it - n`	Same as for `i -= n`.	Equivalent to `{ I itt = it; return itt -= n; }`	Result is dereferenceable or past-the-end.
Difference	`it1 - it2`	Either `it1` is reachable from `it2` or `it2` is reachable from `it1`, or both.	Returns a number `n` such that `it1 == it2 + n`
Element operator	`it [n]`	`it + n` exists and is dereferenceable.	Equivalent to `*(it + n)`
Element assignment	`i[n] = t`	Same as for `it [n]`.	Equivalent to `*(it + n) = t`

Complexity guarantees

The complexity of operations on indexed random access Column/Row iterators is guaranteed to be amortized constant time.

Invariants

Symmetry of addition and subtraction	If `it + n` is well-defined, then `it += n; it -= n;` and `(it + n) - n` are null operations. Similarly, if `it - n` is well-defined, then `it -= n; it += n;` and `(it - n) + n` are null operations.
Relation between distance and addition	If `it1 - it2` is well-defined, then `it1 == it2 + (it1 - it2)`.
Reachability and distance	If `it1` is reachable from `it2`, then `it1 - it2 >= 0`.

Models

matrix::iterator1
matrix::iterator2

Copyright (©) 2000-2002 Joerg Walter, Mathias Koch
Use, modification and distribution are subject to 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 ).