Difference between revisions of "References and Data Structures"
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* '''\e''' is the '''''reference operation'''''. It creates a reference to the value of expression <code>e</code>. | * '''\e''' is the '''''reference operation'''''. It creates a reference to the value of expression <code>e</code>. | ||
| − | * '''#e''' is the '''''dereference operation'''''. It obtains the value referred to by e. If e is not a reference, it issues a warning and returns Null. | + | * '''#e''' is the '''''dereference operation'''''. It obtains the value referred to by e. If e is not a reference, it issues a warning and returns <code>Null</code>. |
__TOC__ | __TOC__ | ||
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See '''Linked List Library.ana''' in the '''Libraries''' folder for these and other functions for working with linked lists. | See '''Linked List Library.ana''' in the '''Libraries''' folder for these and other functions for working with linked lists. | ||
| + | |||
| + | == See Also == | ||
| + | [http://wiki.analytica.com/index.php?title=Analytica_Libraries_and_Templates#Linked_Lists Linked Lists] | ||
| + | |||
| + | [http://wiki.analytica.com/index.php?title=Using_References Using References] | ||
<footer>Ensuring Array Abstraction / {{PAGENAME}} / Handles to Objects</footer> | <footer>Ensuring Array Abstraction / {{PAGENAME}} / Handles to Objects</footer> | ||
__FORCETOC__ | __FORCETOC__ | ||
Revision as of 07:14, 27 December 2015
A reference is an indirect link to a value, an atom or an array. A variable can contain a single reference to a value, or it can contain an array of references. Variables and arrays can themselves contain references, nested to any depth. This lets you create complex data structures, such as linked lists, trees, and non-rectangular structures. Use of references is provided by two operators:
- \e is the reference operation. It creates a reference to the value of expression
e. - #e is the dereference operation. It obtains the value referred to by e. If e is not a reference, it issues a warning and returns
Null.
An example:
Variable MDefinition: 100
Variable Ref_to_M
Definition: \ M
The result of Ref_to_M looks like this:
You can double-click the cell containing «ref» to view the value referenced, in this case:
You can also create an array of references. Suppose:
Index KDefinition: 1..5
Variable KsquareDefinition: K^2
Ksquare →
Variable Ref_to_KsquareDefinition: \ Ksquare
Ref_to_Ksquare →
If you click the «ref» cell, it opens:
You can also create an array of references from an array, for example:
Variable Ref_Ksquare_arrayDefinition: \ [] KsquareKsquare →
The empty square brackets [ ] specify that the values referred to have no indexes, i.e., they are atoms. You can now click any of these cells to see what it refers to.
Clicking the third cell, for example, gives:
Managing indexes of referenced subarrays: \[i, j,...] e
More generally, you can list in the square brackets any indexes of e that you want to be indexes of each subarray referenced by the result. The other indexes of e (if any) are used as indexes for the referencing array. Thus, in the example above, since there were no indexes in square brackets, the index K was used as an index of the reference array. If instead we write:
\ [K] Ksquare →
It creates a similar result to \ Ksquare, since K is the only index of Ksquare.
To summarize:
\ eCreates a reference to the value of expression e, whether it is an atom or an array.\ [] eCreates an array indexed by all indexes of econtaining references to all atoms frome.\ [i] eCreates an array indexed by any indexes of eother thaniof references to subarrays ofeeach indexed byi.\ [i, j…] eCreates an array indexed by any indexes of eother thani, j …of references to subarrays ofeeach indexed byi, j ….
In general, it is better to include the square brackets after the reference operator, and avoid the unadorned reference operator, as in the first row of the table. Being explicit about which indexes to include generally leads to expressions that array abstract as intended.
IsReference(x)
This Is a test to see whether its parameter x is a reference. It returns True (1) if x is a reference, False (0) otherwise.
Using references for linked lists: Example functions
Linked lists are a common way for programmers to represent an ordered set of items. They are more efficient than arrays when you want often to add or remove items, thereby changing the length of the list (which is more time consuming for arrays). In Analytica, we can represent a linked list as an element with two elements, the item — that is, a reference to the value of the item — and a link — that is, a reference, to the next item:
Index Linked_listDefinition: ['Item', 'Link']
Function LL_Put(x, LL)Description: Puts item x onto linked list LL.Definition: \Array(Linked_List, [\x, LL])
Function LL_Get_Item(LL)Description: Gets the value of the first item from linked list LL.Definition: # Subscript(#LL, Linked_list, 'Item')
Function LL_length(LL)Parameters: (LL: Atom)Description: Returns the number of items in linked list LLDefinition: VAR len := 0;- WHILE (IsReference(LL)) BEGIN
LL := subscript(#LL, Linked_List, "Next");len := len + 1
END;len
- WHILE (IsReference(LL)) BEGIN
Function LL_from_array(a, i)Parameters: (a; i: Index)Description: Creates a linked list from the elements of array a over index iDefinition:VAR LL := NULL;Index iRev := Size(i) .. 1;FOR j := iRevDO LL := LL_Push(LL, Slice(a, i, j));
LL
See Linked List Library.ana in the Libraries folder for these and other functions for working with linked lists.
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