# Associative array/Iteration

Associative array/Iteration
You are encouraged to solve this task according to the task description, using any language you may know.
Show how to iterate over the key-value pairs of an associative array, and print each pair out.

Also show how to iterate just over the keys, or the values, if there is a separate way to do that in your language.

## 11l

```V d = [‘key1’ = ‘value1’, ‘key2’ = ‘value2’]

L(key, value) d
print(key‘ = ’value)

L(key) d.keys()
print(key)

L(value) d.values()
print(value)```
Output:
```key1 = value1
key2 = value2
key1
key2
value1
value2
```

## 8th

Iterating key,value pairs uses "m:each":

```{"one": 1, "two": "bad"}
( swap . space . cr )
m:each
```
Output:
```
one 1

```

Iterating the keys uses "m:keys":

```{"one": 1, "two": "bad"} m:keys
( . cr )
a:each
```
Output:
```
one
two

```

```with Ada.Text_IO;  use Ada.Text_IO;

procedure Test_Iteration is
package String_Maps is
use String_Maps;
A     : Map;
Index : Cursor;
begin
A.Insert ("hello", 1);
A.Insert ("world", 2);
A.Insert ("!",     3);
Index := A.First;
while Index /= No_Element loop
Put_Line (Key (Index) & Integer'Image (Element (Index)));
Index := Next (Index);
end loop;
end Test_Iteration;
```
Output:
```! 3
hello 1
world 2
```

## Aime

```record r;
text s;

r_put(r, "A", 33);              # an integer value
r_put(r, "C", 2.5);             # a real value
r_put(r, "B", "associative");   # a string value

if (r_first(r, s)) {
do {
o_form("key ~, value ~ (~)\n", s, r[s], r_type(r, s));
} while (rsk_greater(r, s, s));
}```
Output:
```key A, value 33 (integer)
key B, value associative (text)
key C, value 2.5 (real)```

## ALGOL 68

Algol 68 does not have associative arrays as standard.
This sample defines a simple hash-based implementation with operators to iterate over the array.

```# associative array handling using hashing                                   #

# the modes allowed as associative array element values - change to suit     #
MODE AAVALUE = STRING;
# the modes allowed as associative array element keys - change to suit       #
MODE AAKEY   = STRING;
# nil element value                                                          #
REF AAVALUE nil value = NIL;

# an element of an associative array                                         #
MODE AAELEMENT = STRUCT( AAKEY key, REF AAVALUE value );
# a list of associative array elements - the element values with a           #
# particular hash value are stored in an AAELEMENTLIST                       #
MODE AAELEMENTLIST = STRUCT( AAELEMENT element, REF AAELEMENTLIST next );
# nil element list reference                                                 #
REF AAELEMENTLIST nil element list = NIL;
# nil element reference                                                      #
REF AAELEMENT     nil element      = NIL;

# the hash modulus for the associative arrays                                #
INT hash modulus = 256;

# generates a hash value from an AAKEY - change to suit                      #
OP HASH = ( STRING key )INT:
BEGIN
INT result := ABS ( UPB key - LWB key ) MOD hash modulus;
FOR char pos FROM LWB key TO UPB key DO
result PLUSAB ( ABS key[ char pos ] - ABS " " );
result MODAB  hash modulus
OD;
result
END; # HASH #

# a mode representing an associative array                                    #
MODE AARRAY = STRUCT( [ 0 : hash modulus - 1 ]REF AAELEMENTLIST elements
, INT                                       curr hash
, REF AAELEMENTLIST                         curr position
);

# initialises an associative array so all the hash chains are empty           #
OP   INIT = ( REF AARRAY array )REF AARRAY:
BEGIN
FOR hash value FROM 0 TO hash modulus - 1 DO ( elements OF array )[ hash value ] := nil element list OD;
array
END; # INIT #

# gets a reference to the value corresponding to a particular key in an      #
# associative array - the element is created if it doesn't exist             #
PRIO // = 1;
OP   // = ( REF AARRAY array, AAKEY key )REF AAVALUE:
BEGIN
REF AAVALUE result;
INT         hash value = HASH key;
# get the hash chain for the key #
REF AAELEMENTLIST element := ( elements OF array )[ hash value ];
# find the element in the list, if it is there #
BOOL found element := FALSE;
WHILE ( element ISNT nil element list )
DO
found element := ( key OF element OF element = key );
IF found element
THEN
result  := value OF element OF element
ELSE
element := next OF element
FI
OD;
THEN
# the element is not in the list #
# - add it to the front of the hash chain #
( elements OF array )[ hash value ]
:= HEAP AAELEMENTLIST
:= ( HEAP AAELEMENT := ( key
, HEAP AAVALUE := ""
)
, ( elements OF array )[ hash value ]
);
result := value OF element OF ( elements OF array )[ hash value ]
FI;
result
END; # // #

# returns TRUE if array contains key, FALSE otherwise                        #
PRIO CONTAINSKEY = 1;
OP   CONTAINSKEY = ( REF AARRAY array, AAKEY key )BOOL:
BEGIN
# get the hash chain for the key #
REF AAELEMENTLIST element := ( elements OF array )[ HASH key ];
# find the element in the list, if it is there #
BOOL found element := FALSE;
WHILE ( element ISNT nil element list )
DO
found element := ( key OF element OF element = key );
THEN
element := next OF element
FI
OD;
found element
END; # CONTAINSKEY #

# gets the first element (key, value) from the array                         #
OP FIRST = ( REF AARRAY array )REF AAELEMENT:
BEGIN
curr hash     OF array := LWB ( elements OF array ) - 1;
curr position OF array := nil element list;
NEXT array
END; # FIRST #

# gets the next element (key, value) from the array                          #
OP NEXT  = ( REF AARRAY array )REF AAELEMENT:
BEGIN
WHILE ( curr position OF array IS nil element list )
AND   curr hash     OF array < UPB ( elements OF array )
DO
# reached the end of the current element list - try the next         #
curr hash     OF array +:= 1;
curr position OF array  := ( elements OF array )[ curr hash OF array ]
OD;
IF   curr hash OF array > UPB ( elements OF array )
THEN
# no more elements #
nil element
ELIF curr position OF array IS nil element list
THEN
# reached the end of the table #
nil element
ELSE
# have another element #
REF AAELEMENTLIST found element = curr position OF array;
curr position OF array := next OF curr position OF array;
element OF found element
FI
END; # NEXT #

# test the associative array #
BEGIN
# create an array and add some values  #
REF AARRAY a1 := INIT LOC AARRAY;
a1 // "k1" := "k1 value";
a1 // "z2" := "z2 value";
a1 // "k1" := "new k1 value";
a1 // "k2" := "k2 value";
a1 // "2j" := "2j value";
# iterate over the values #
REF AAELEMENT e := FIRST a1;
WHILE e ISNT nil element
DO
print( ( "  (" + key OF e + ")[" + value OF e + "]", newline ) );
e := NEXT a1
OD
END```
Output:
```  (2j)[2j value]
(k1)[new k1 value]
(k2)[k2 value]
(z2)[z2 value]
```

## App Inventor

Associative arrays in App Inventor are lists of key:value 'pairs'.
When a list is organized as pairs, the lookup in pairs block can be used to retrieve an associated value from a key name.
<VIEW BLOCKS AND ANDROID APP>

## Arturo

```; create a dictionary
d: #[
name: 		"john"
surname: 	"doe"
age: 		34
]

; Iterate over key/value pairs
loop d [key,value][
print ["key =" key ", value =" value]
]

print "----"

; Iterate over keys
loop keys d [k][
print ["key =" k]
]

print "----"

; Iterate over values
loop values d [v][
print ["value =" v]
]
```
Output:
```key = name , value = john
key = surname , value = doe
key = age , value = 34
----
key = name
key = surname
key = age
----
value = john
value = doe
value = 34```

## AutoHotkey

Works with: AutoHotkey_L
From the documentation
```; Create an associative array
obj := Object("red", 0xFF0000, "blue", 0x0000FF, "green", 0x00FF00)
enum := obj._NewEnum()
While enum[key, value]
t .= key "=" value "`n"
MsgBox % t
```

## AWK

In AWK "arrays" are always associative arrays, and the only way to iterate over them is by keys (indexes in the AWK terminology), in undefined order.

```BEGIN {
a["hello"] = 1
a["world"] = 2
a["!"] = 3

# iterate over keys, undefined order
for(key in a) {
print key, a[key]
}
}
```

As AWK was often used in (Bourne) shell scripts, sorting was done by a pipe of two awk programs and the sort command. Today, 'gawk' allows to set the order of iteration:

```BEGIN {
a["hello"] = 1
a["world"] = 2
a["!"] = 3
PROCINFO["sorted_in"] = "@ind_str_asc" # controls index order
# iterate over keys, indices as strings sorted ascending
for(key in a) {
print key, a[key]
}
}
```

## Babel

In Babel, associative arrays are referred to as maps. To create a map from a list-of-lists:

`births (('Washington' 1732) ('Lincoln' 1809) ('Roosevelt' 1882) ('Kennedy' 1917)) ls2map ! <`

To iterate over a map, in the primary sense, use the overmap utility. We will copy the map (cp operator) so as not to modify the original:

`births cp dup {1 +} overmap !`

To see the results, use the valmap operator:

`valmap ! lsnum !`
Output:
`( 1918 1733 1883 1810 )`

There are many ways to interact with a map in Babel. Most of these begin by converting the map to a list or list-of-lists. To look up a list of specific values from the map, by key, use the lumapls utility:

`births ('Roosevelt' 'Kennedy') lumapls ! lsnum !`
Output:
`( 1882 1917 )`

To convert the entire map back to a list of key-value pairs:

`births map2ls !`

To view the list:

`{give swap << " " << itod << "\n" <<} each`
Output:
```Kennedy 1917
Washington 1732
Roosevelt 1882
Lincoln 1809```

To merge two maps together, use the mapmerge utility:

```foo (("bar" 17) ("baz" 42)) ls2map ! <
births foo mergemap !```

To view the results:

`births map2ls ! {give swap << " " << itod << "\n" <<} each`
Output:
```baz 42
Kennedy 1917
bar 17
Washington 1732
Roosevelt 1882
Lincoln 1809```

For more information on maps in Babel, view std.sp (see the section titled "map utilities").

## BaCon

```DECLARE associative ASSOC STRING

associative("abc") = "first three"
associative("mn") = "middle two"
associative("xyz") = "last three"

LOOKUP associative TO keys\$ SIZE amount
FOR i = 0 TO amount - 1
PRINT keys\$[i], ":", associative(keys\$[i])
NEXT
```
Output:
```prompt\$ ./assoc
abc:first three
mn:middle two
xyz:last three```

LOOKUP creates a numerically indexed array of the keys of the associative array, with the number of elements stored in the field following the SIZE keyword.

## BASIC256

Solution is at Associative_array/Creation#BASIC256.

## BBC BASIC

```      REM Store some values with their keys:
PROCputdict(mydict\$, "FF0000", "red")
PROCputdict(mydict\$, "00FF00", "green")
PROCputdict(mydict\$, "0000FF", "blue")

REM Iterate through the dictionary:
i% = 1
REPEAT
i% = FNdict(mydict\$, i%, v\$, k\$)
PRINT v\$, k\$
UNTIL i% = 0
END

DEF PROCputdict(RETURN dict\$, value\$, key\$)
IF dict\$ = "" dict\$ = CHR\$(0)
dict\$ += key\$ + CHR\$(1) + value\$ + CHR\$(0)
ENDPROC

DEF FNdict(dict\$, I%, RETURN value\$, RETURN key\$)
LOCAL J%, K%
J% = INSTR(dict\$, CHR\$(1), I%)
K% = INSTR(dict\$, CHR\$(0), J%)
value\$ = MID\$(dict\$, I%+1, J%-I%-1)
key\$ = MID\$(dict\$, J%+1, K%-J%-1)
IF K% >= LEN(dict\$) THEN K% = 0
= K%
```

## Bracmat

```(  new\$hash:?myhash
& (myhash..insert)\$(title."Some title")
& (myhash..insert)\$(formula.a+b+x^7)
& (myhash..insert)\$(fruit.apples oranges kiwis)
& (myhash..insert)\$(meat.)
& (myhash..insert)\$(fruit.melons bananas)
& (myhash..remove)\$formula
& (myhash..insert)\$(formula.x^2+y^2)
&   (myhash..forall)
\$ (
=   key value
.     whl
' ( !arg:(?key.?value) ?arg
& put\$("key:" !key "\nvalue:" !value \n)
)
& put\$\n
)
);```
Output:
```key: meat
value:

key: title
value: Some title

key: formula
value: x^2+y^2

key: fruit
value: melons bananas
key: fruit
value: apples oranges kiwis
```

## Brat

```h = [ hello: 1 world: 2 :! : 3]

#Iterate over key, value pairs
h.each { k, v |
p "Key: #{k} Value: #{v}"
}

#Iterate over keys
h.each_key { k |
p "Key: #{k}"
}

#Iterate over values
h.each_value { v |
p "Value: #{v}"
}```

## C

Solution is at Associative arrays/Creation/C.

## C#

```using System;
using System.Collections.Generic;

namespace AssocArrays
{
class Program
{
static void Main(string[] args)
{

Dictionary<string,int> assocArray = new Dictionary<string,int>();

assocArray["Hello"] = 1;
assocArray["!"] = 3;

foreach (KeyValuePair<string, int> kvp in assocArray)
{
Console.WriteLine(kvp.Key + " : " + kvp.Value);
}

foreach (string key in assocArray.Keys)
{
Console.WriteLine(key);
}

foreach (int val in assocArray.Values)
{
Console.WriteLine(val.ToString());
}
}
}
}
```

## C++

Works with: C++11
```#include <iostream>
#include <map>
#include <string>

int main() {
std::map<std::string, int> dict {
{"One", 1},
{"Two", 2},
{"Three", 7}
};

dict["Three"] = 3;

std::cout << "One: " << dict["One"] << std::endl;
std::cout << "Key/Value pairs: " << std::endl;
for(auto& kv: dict) {
std::cout << "  " << kv.first << ": " << kv.second << std::endl;
}

return 0;
}
```

Pre C++11:

```std::map<std::string, int> myDict;
myDict["hello"] = 1;
myDict["world"] = 2;
myDict["!"] = 3;

// iterating over key-value pairs:
for (std::map<std::string, int>::iterator it = myDict.begin(); it != myDict.end(); ++it) {
// the thing pointed to by the iterator is an std::pair<const std::string, int>&
const std::string& key = it->first;
int& value = it->second;
std::cout << "key = " << key << ", value = " << value << std::endl;
}
```

## Ceylon

```shared void run() {

value myMap = map {
"foo" -> 5,
"bar" -> 10,
"baz" -> 15
};

for(key in myMap.keys) {
print(key);
}

for(item in myMap.items) {
print(item);
}

for(key->item in myMap) {
print("``key`` maps to ``item``");
}

}
```

## Chapel

```var A = [ "H2O" => "water", "NaCl" => "salt", "O2" => "oxygen" ];

for k in A.domain do
writeln("have key: ", k);

for v in A do
writeln("have value: ", v);

for (k,v) in zip(A.domain, A) do
writeln("have element: ", k, " -> ", v);
```
Output:
```have key: O2
have key: NaCl
have key: H2O
have value: oxygen
have value: salt
have value: water
have element: O2 -> oxygen
have element: NaCl -> salt
have element: H2O -> water
```

## Clojure

```(doseq [[k v] {:a 1, :b 2, :c 3}]
(println k "=" v))

(doseq [k  (keys {:a 1, :b 2, :c 3})]
(println k))

(doseq [v  (vals {:a 1, :b 2, :c 3})]
(println v))
```

## CoffeeScript

```hash =
a: 'one'
b: 'two'

for key, value of hash
console.log key, value

for key of hash
console.log key
```

## Common Lisp

Common Lisp has three common idioms for associating keys with values: association lists (alists), property lists (plists), and hash tables.

### With association lists (alists)

The association list is a list of conses, each of whose `car` is a key and whose `cdr` is a value. The standard mapping and print functions can be used to print key/value pairs, keys, and values.

```;; iterate using dolist, destructure manually
(dolist (pair alist)
(destructuring-bind (key . value) pair
(format t "~&Key: ~a, Value: ~a." key value)))

;; iterate and destructure with loop
(loop for (key . value) in alist
do (format t "~&Key: ~a, Value: ~a." key value))
```

### With property lists (plists)

Property lists are lists of alternating keys and values, where each value's key is the element of the list immediately following it. Printing could be done with standard mapping functions, but `loop`'s destructuring makes things a bit easier.

```(loop for (key value) on plist :by 'cddr
do (format t "~&Key: ~a, Value: ~a." key value))
```

### With hash tables

Lisp also has built-in hash tables, and there are several ways to map over these. The first is `maphash` which takes a function of two arguments (the key and value) and the hash table.

```(maphash (lambda (key value)
(format t "~&Key: ~a, Value: ~a." key value))
hash-table)
```

The `loop` construct also supports extracting key/value pairs from hash tables.

```(loop for key being each hash-key of hash-table using (hash-value value)
do (format t "~&Key: ~a, Value: ~a." key value))
```

There is also a macro `with-hash-table-iterator` which locally binds a name to produce associated keys and values of the hash table; while rarely used, it is the most powerful operation.

```(with-hash-table-iterator (next-entry hash-table)
(loop
(multiple-value-bind (nextp key value) (next-entry)
(if (not nextp)
(return)
(format t "~&Key: ~a, Value: ~a." key value)))))
```

### Alternate solution

I use Allegro CL 10.1

```;; Project : Associative array/Iteration

(setf x (make-array '(3 2)
:initial-contents '(("hello" 13 ) ("world" 31) ("!" 71))))
(setf xlen (array-dimensions x))
(setf len (car xlen))
(dotimes (n len)
(terpri)
(format t "~a" (aref x n 0))
(format t "~a" " : ")
(format t "~a" (aref x n 1)))
```

Output:

```hello : 13
world : 31
! : 71
```

## Crystal

```dict = {'A' => 1, 'B' => 2}

dict.each { |pair|
puts pair
}

dict.each_key { |key|
puts key
}

dict.each_value { |value|
puts value
}
```
Output:
```{'A', 1}
{'B', 2}
A
B
1
2```

## D

Works with: D version 2
```import std.stdio: writeln;

void main() {
// the associative array
auto aa = ["alice":2, "bob":97, "charlie":45];

// how to iterate key/value pairs:
foreach (key, value; aa)
writeln("1) Got key ", key, " with value ", value);
writeln();

// how to iterate the keys:
foreach (key, _; aa)
writeln("2) Got key ", key);
writeln();

// how to iterate the values:
foreach (value; aa)
writeln("3) Got value ", value);
writeln();

// how to extract the values, lazy:
foreach (value; aa.byValue())
writeln("4) Got value ", value);
writeln();

// how to extract the keys, lazy:
foreach (key; aa.byKey())
writeln("5) Got key ", key);
writeln();

// how to extract all the keys:
foreach (key; aa.keys)
writeln("6) Got key ", key);
writeln();

// how to extract all the values:
foreach (value; aa.values)
writeln("7) Got value ", value);
}
```

## Dao

```dict = { 'def' => 1, 'abc' => 2 }

for( keyvalue in dict ) io.writeln( keyvalue );
for( key in dict.keys(); value in dict.values() ) io.writeln( key, value )
dict.iterate { [key, value]
io.writeln( key, value )
}
```

## Dart

```main(){
var fruits = {
'apples':  'red',
'oranges': 'orange',
'bananas': 'yellow',
'pears':   'green',
'plums':   'purple'
};

print('Key Value pairs:');
fruits.forEach( (fruits, color) => print( '\$fruits are \$color' ) );

print('\nKeys only:');
fruits.keys.forEach( ( key ) => print( key ) );

print('\nValues only:');
fruits.values.forEach( ( value ) => print( value ) );
}
```
Output:
```Key Value pairs:
apples are red
oranges are orange
bananas are yellow
pears are green
plums are purple

Keys only:
apples
oranges
bananas
pears
plums

Values only:
red
orange
yellow
green
purple
```

## Delphi

```program AssociativeArrayIteration;

{\$APPTYPE CONSOLE}

uses SysUtils, Generics.Collections;

var
i: Integer;
s: string;
lDictionary: TDictionary<string, Integer>;
lPair: TPair<string, Integer>;
begin
lDictionary := TDictionary<string, Integer>.Create;
try

for lPair in lDictionary do
Writeln(Format('Pair: %s = %d', [lPair.Key, lPair.Value]));
for s in lDictionary.Keys do
Writeln('Key: ' + s);
for i in lDictionary.Values do
Writeln('Value: ', i);
finally
lDictionary.Free;
end;
end.
```

## Dyalect

```var t = (x: 1, y: 2, z: 3)

for x in t.Keys() {
print("\(x)=\(t[x])")
}```
Output:
```x=1
y=2
z=3```

## E

In E, the basic iteration protocol and syntax work over key-value pairs. Therefore, any iteration over a map or other collection is always key-value, though the user may choose to ignore the keys or the values.

The `for` loop takes either one pattern, for the value, or two, for the key and value; for iterating over keys alone the value may be given an ignore-pattern (`_`).

```def map := [
"a" => 1,
"b" => 2,
"c" => 3,
]

for key => value in map {
println(`\$key \$value`)
}

for value in map {     # ignore keys
println(`. \$value`)
}

for key => _ in map {  # ignore values
println(`\$key .`)
}

for key in map.domain() {     # iterate over the set whose values are the keys
println(`\$key .`)
}```

## EchoLisp

```(lib 'hash) ;; load hash.lib
(define H (make-hash))
;; fill hash table
(hash-set H 'Simon 42)
(hash-set H 'Albert 666)
(hash-set H 'Antoinette 33)

;; iterate over (key . value ) pairs
(for ([kv H]) (writeln kv))
(Simon . 42)
(Albert . 666)
(Antoinette . 33)

;; iterate over keys
(for ([k (hash-keys H)]) (writeln 'key-> k))
key->     Simon
key->     Albert
key->     Antoinette

;; iterate over values
(for ([v (hash-values H)]) (writeln 'value-> v))
value->     42
value->     666
value->     33
```

## Elena

ELENA 5.0 :

```import system'collections;
import system'routines;
import extensions;

public program()
{
// 1. Create
var map := Dictionary.new();
map["key"] := "foox";
map["key"] := "foo";
map["key2"]:= "foo2";
map["key3"]:= "foo3";
map["key4"]:= "foo4";

// Enumerate
map.forEach:
(keyValue){ console.printLine(keyValue.Key," : ",keyValue.Value) }
}```

### Strong typed dictionary

```import system'collections;
import system'routines;
import extensions;

public program()
{
// 1. Create
auto map := new Map<string,string>();
map["key"] := "foox";
map["key"] := "foo";
map["key2"]:= "foo2";
map["key3"]:= "foo3";
map["key4"]:= "foo4";

// Enumerate
map.forEach:
(tuple){ console.printLine(tuple.Item1," : ",tuple.Item2) }
}```

## Elixir

```IO.inspect d = Map.new([foo: 1, bar: 2, baz: 3])
Enum.each(d, fn kv -> IO.inspect kv end)
Enum.each(d, fn {k,v} -> IO.puts "#{inspect k} => #{v}" end)
Enum.each(Map.keys(d), fn key -> IO.inspect key end)
Enum.each(Map.values(d), fn value -> IO.inspect value end)
```
Output:
```%{bar: 2, baz: 3, foo: 1}
{:bar, 2}
{:baz, 3}
{:foo, 1}
:bar => 2
:baz => 3
:foo => 1
:bar
:baz
:foo
2
3
1
```

## Erlang

```-module(assoc).
-compile([export_all]).

test_create() ->
D = dict:new(),
D1 = dict:store(foo,1,D),
D2 = dict:store(bar,2,D1),
print_vals(D2).

print_vals(D) ->
lists:foreach(fun (K) ->
io:format("~p: ~b~n",[K,dict:fetch(K,D)])
end, dict:fetch_keys(D)).
```
Output:
```32> assoc:test_create().
bar: 2
foo: 1
ok
```

## F#

Iterating over both.

```let myMap = [ ("Hello", 1); ("World", 2); ("!", 3) ]

for k, v in myMap do
printfn "%s -> %d" k v
```

Iterating over either keys or values only can be achieved through use of the _ wildcard token.

```// Only prints the keys.
for k, _ in myMap do
printfn "%s" k

// Only prints the values.
for _, v in myMap do
printfn "%d" v
```

## Factor

```H{ { "hi" "there" } { "a" "b" } } [ ": " glue print ] assoc-each
```

`assoc-each` places both the key and the value on top of the data stack. A simple `drop` or `nip` enables iterating over only keys or values.

```H{ { "hi" "there" } { "a" "b" } } [ drop print ] assoc-each ! print keys
H{ { "hi" "there" } { "a" "b" } } [ nip print ] assoc-each ! print values
```

There's also `assoc-map`, `assoc-find`, `assoc-filter` and many more.

## Fantom

Given a map, `each` iterates over pairs of values-keys. `keys` and `vals` retrieve a list of keys or values, respectively.

```class Main
{
public static Void main ()
{
Int:Str map := [1:"alpha", 2:"beta", 3:"gamma"]

map.keys.each |Int key|
{
echo ("Key is: \$key")
}

map.vals.each |Str value|
{
echo ("Value is: \$value")
}

map.each |Str value, Int key|
{
echo ("Key \$key maps to \$value")
}
}
}```

## Forth

```include ffl/hct.fs
include ffl/hci.fs

\ Create hashtable and iterator in dictionary
10     hct-create htable
htable hci-create hiter

\ Insert entries
1 s" hello" htable hct-insert
2 s" world" htable hct-insert
3 s" !"     htable hct-insert

: iterate
hiter hci-first
BEGIN
WHILE
." key = " hiter hci-key type ." , value = " . cr
hiter hci-next
REPEAT
;

iterate
```
```\ Written in ANS-Forth; tested under VFX.
\ Requires the novice package: http://www.forth.org/novice.html
\ The following should already be done:
\ include novice.4th
\ include association.4th

\ I would define high-level languages as those that allow programs to be written without explicit iteration. Iteration is a major source of bugs.
\ The example from the FFL library doesn't hide iteration, whereas this example from the novice-package does.

marker AssociationIteration.4th

\ ******
\ ****** The following defines a node in an association (each node is derived from ELEMENT).
\ ******

element
w field .inventor
constant language           \ describes a programming language

: init-language ( inventor name node -- node )
init-element >r
hstr r@ .inventor !
r> ;

: new-language ( inventor name -- node )
language alloc
init-language ;

: show-language ( count node -- )
>r
1+                      \ -- count+1
cr  r@ .key @ count colorless type  ." invented by: "  r@ .inventor @ count type
rdrop ;

: show-languages-forward ( handle -- )
0                       \ -- handle count
swap .root @  ['] show-language  walk>
cr ." count: " .
cr ;

: show-languages-backward ( handle -- )
0                       \ -- handle count
swap .root @  ['] show-language  <walk
cr ." count: " .
cr ;

: kill-language-attachments ( node -- )
dup .inventor @  dealloc
kill-key ;

: copy-language-attachments ( src dst -- )
over .inventor @  hstr
over .inventor !
copy-key ;

\ ******
\ ****** The following defines the association itself (the handle).
\ ******

association
constant languages          \ describes a set of programming languages

: init-languages ( record -- record )
>r
['] compare  ['] kill-language-attachments  ['] copy-language-attachments
r> init-association ;

: new-languages ( -- record )
languages alloc
init-languages ;

\ ******
\ ****** The following filters one association into another, including everything that matches a particular inventor.
\ ******

: <filter-inventor> { inventor handle new-handle node -- inventor handle new-handle }
inventor count  node .inventor @ count  compare  A=B = if
node handle dup-element  new-handle insert  then
inventor handle new-handle ;

: filter-inventor ( inventor handle -- new-handle )
dup similar-association                             \ -- inventor handle new-handle
over .root @  ['] <filter-inventor>  walk>          \ -- inventor handle new-handle
nip nip ;

\ ******
\ ****** The following is a demonstration with some sample data.
\ ******

new-languages
c" Moore, Chuck"                c" Forth     "      new-language  over insert
c" Ichiah, Jean"                c" Ada       "      new-language  over insert
c" Wirth, Niklaus"              c" Pascal    "      new-language  over insert
c" Wirth, Niklaus"              c" Oberon    "      new-language  over insert
c" McCarthy, John"              c" Lisp      "      new-language  over insert
c" van Rossum, Guido"           c" Python    "      new-language  over insert
c" Gosling, Jim"                c" Java      "      new-language  over insert
c" Ierusalimschy, Roberto"      c" Lua       "      new-language  over insert
c" Matsumoto, Yukihiro"         c" Ruby      "      new-language  over insert
c" Pestov, Slava"               c" Factor    "      new-language  over insert
c" Gosling, James"              c" Java      "      new-language  over insert
c" Wirth, Niklaus"              c" Modula-2  "      new-language  over insert
c" Ritchie, Dennis"             c" C         "      new-language  over insert
c" Stroustrup, Bjarne"          c" C++       "      new-language  over insert
constant some-languages

cr .( everything in SOME-LANGUAGES ordered forward: )

some-languages show-languages-forward

cr .( everything in SOME-LANGUAGES ordered backward: )

some-languages show-languages-backward

cr .( everything in SOME-LANGUAGES invented by Wirth: )

c" Wirth, Niklaus" some-languages filter-inventor           dup show-languages-forward  kill-association

cr .( everything in SOME-LANGUAGES within 'F' and 'L': )

c" F"  c" L"  some-languages  filter within                 dup show-languages-forward  kill-association

cr .( everything in SOME-LANGUAGES not within 'F' and 'L': )

c" F"  c" L"  some-languages  filter without                dup show-languages-forward  kill-association

some-languages kill-association
```
Output:
```everything in SOME-LANGUAGES ordered forward:
C         invented by: Ritchie, Dennis
C++       invented by: Stroustrup, Bjarne
Factor    invented by: Pestov, Slava
Forth     invented by: Moore, Chuck
Java      invented by: Gosling, James
Lisp      invented by: McCarthy, John
Lua       invented by: Ierusalimschy, Roberto
Modula-2  invented by: Wirth, Niklaus
Oberon    invented by: Wirth, Niklaus
Pascal    invented by: Wirth, Niklaus
Python    invented by: van Rossum, Guido
Ruby      invented by: Matsumoto, Yukihiro
count: 13

everything in SOME-LANGUAGES ordered backward:
Ruby      invented by: Matsumoto, Yukihiro
Python    invented by: van Rossum, Guido
Pascal    invented by: Wirth, Niklaus
Oberon    invented by: Wirth, Niklaus
Modula-2  invented by: Wirth, Niklaus
Lua       invented by: Ierusalimschy, Roberto
Lisp      invented by: McCarthy, John
Java      invented by: Gosling, James
Forth     invented by: Moore, Chuck
Factor    invented by: Pestov, Slava
C++       invented by: Stroustrup, Bjarne
C         invented by: Ritchie, Dennis
count: 13

everything in SOME-LANGUAGES invented by Wirth:
Modula-2  invented by: Wirth, Niklaus
Oberon    invented by: Wirth, Niklaus
Pascal    invented by: Wirth, Niklaus
count: 3

everything in SOME-LANGUAGES within 'F' and 'L':
Factor    invented by: Pestov, Slava
Forth     invented by: Moore, Chuck
Java      invented by: Gosling, James
count: 3

everything in SOME-LANGUAGES not within 'F' and 'L':
C         invented by: Ritchie, Dennis
C++       invented by: Stroustrup, Bjarne
Lisp      invented by: McCarthy, John
Lua       invented by: Ierusalimschy, Roberto
Modula-2  invented by: Wirth, Niklaus
Oberon    invented by: Wirth, Niklaus
Pascal    invented by: Wirth, Niklaus
Python    invented by: van Rossum, Guido
Ruby      invented by: Matsumoto, Yukihiro
count: 10
```

## FreeBASIC

Use the typedefs and data from Associative Array/Creation#FreeBASIC as an include.

Since this data structure stores the keys and values together it makes little sense to iterate through the same array three times to print different parts of it, hence I will only print the key:value pairs.

```#include"assoc.bas"

function get_dict_data_string( d as dicitem ) as string
select case d.datatype
case BOOL
if d.value.bool then return "true" else return "false"
case INTEG
return str(d.value.integ)
case STRNG
return """"+d.value.strng+""""
case FLOAT
return str(d.value.float)
case BYYTE
return str(d.value.byyte)
case else
return "DATATYPE ERROR"
end select
end function

sub print_keyval_pair( d as dicentry )
print using "{&} : {&}";get_dict_data_string( d.key ); get_dict_data_string(d.value)

end sub

for i as uinteger = 0 to ubound(Dictionary)
print_keyval_pair(Dictionary(i))
next i
```
Output:
```{"Cat"} : {"Mittens"}
{32767} : {2.718281828}
```

## Free Pascal

FPC 3.2.0+. Similar to Delphi:
```program AssociativeArrayIteration;
{\$mode delphi}{\$ifdef windows}{\$apptype console}{\$endif}
uses Generics.Collections;

type
TlDictionary =  TDictionary<string, Integer>;
TlPair = TPair<string,integer>;

var
i: Integer;
s: string;
lDictionary: TlDictionary;
lPair: TlPair;
begin
lDictionary := TlDictionary.Create;
try
for lPair in lDictionary do
Writeln('Pair: ',Lpair.Key,' = ',lPair.Value);
for s in lDictionary.Keys do
Writeln('Key: ' + s);
for i in lDictionary.Values do
Writeln('Value: ', i);
finally
lDictionary.Free;
end;
end.
```
```Pair: foo = 6
Pair: bar = 10
Pair: baz = 15
Key: foo
Key: bar
Key: baz
Value: 6
Value: 10
Value: 15```

## Frink

```d = new dict[[[1, "one"], [2, "two"]]]
for [key, value] = d
println["\$key\t\$value"]

println[]
for key = keys[d]
println["\$key"]```
Output:
```2	two
1	one

2
1
```

## FutureBasic

There are many ways to iterate over an associative array (dictionary) in FutureBasic. Below are a selection.

1. for ... in ...

```void local fn DoIt
CFDictionaryRef dict = @{@"A":@"Alpha", @"B":@"Bravo", @"C":@"Charlie", @"D":@"Delta"}
CFStringRef key

for key in dict
print key, dict[key]
next
end fn

fn DoIt

HandleEvents```

2. Enumerator callback

```void local fn MyDictEnumerator( dict as CFDictionaryRef, key as CFTypeRef, obj as CFTypeRef, stp as ^BOOL, userData as ptr )
print key, obj
end fn

void local fn DoIt
CFDictionaryRef dict = @{@"A":@"Alpha", @"B":@"Bravo", @"C":@"Charlie", @"D":@"Delta"}
DictionaryEnumerateKeysAndObjects( dict, @fn MyDictEnumerator, NULL )
end fn

fn DoIt

HandleEvents```

3. Array of keys

```void local fn DoIt
CFDictionaryRef dict = @{@"A":@"Alpha", @"B":@"Bravo", @"C":@"Charlie", @"D":@"Delta"}
CFArrayRef keys = fn DictionaryAllKeys( dict )
CFStringRef key

for key in keys
print key, dict[key]
next
end fn

fn DoIt

HandleEvents```

4. Array of values

```void local fn DoIt
CFDictionaryRef dict = @{@"A":@"Alpha", @"B":@"Bravo", @"C":@"Charlie", @"D":@"Delta"}
CFArrayRef values = fn DictionaryAllValues( dict )
CFStringRef value

for value in values
print value
next
end fn

fn DoIt

HandleEvents```

5. Key/object enumerators

```void local fn DoIt
CFDictionaryRef dict = @{@"A":@"Alpha", @"B":@"Bravo", @"C":@"Charlie", @"D":@"Delta"}
CFStringRef     key
CFTypeRef       obj

EnumeratorRef keyEnumerator = fn DictionaryKeyEnumerator( dict )
key = fn EnumeratorNextObject( keyEnumerator )
while ( key )
print key,dict[key]
key = fn EnumeratorNextObject( keyEnumerator )
wend

print

EnumeratorRef objectEnumerator = fn DictionaryObjectEnumerator( dict )
obj = fn EnumeratorNextObject( objectEnumerator )
while ( obj )
print obj
obj = fn EnumeratorNextObject( objectEnumerator )
wend
end fn

fn DoIt

HandleEvents```

## Gambas

```Public Sub Main()
Dim cList As Collection = ["2": "quick", "4": "fox", "1": "The", "9": "dog", "7": "the", "5": "jumped", "3": "brown", "6": "over", "8": "lazy"]
Dim siCount As Short
Dim sTemp As String

For Each sTemp In cList
Print cList.key & "=" & sTemp;;
Next

Print

For siCount = 1 To cList.Count
Print cList[Str(siCount)];;
Next

End
```

Output:

```2=quick 4=fox 1=The 9=dog 7=the 5=jumped 3=brown 6=over 8=lazy
The quick brown fox jumped over the lazy dog
```

## Go

Language:

```myMap := map[string]int {
"hello": 13,
"world": 31,
"!"    : 71 }

// iterating over key-value pairs:
for key, value := range myMap {
fmt.Printf("key = %s, value = %d\n", key, value)
}

// iterating over keys:
for key := range myMap {
fmt.Printf("key = %s\n", key)
}

// iterating over values:
for _, value := range myMap {
fmt.Printf("value = %d\n", value)
}
```

Standard library templates:

In addition to the for/range features of the language, the text/template and html/template packages of the standard library have map iteration features. Some differences worth noting:

• A single assigned value in a template is the map value. With the language for/range it is the key.
• Templates have no equivalent of _; a dummy variable must be used.
• In a template, if map keys are a comparable basic type, then iteration proceeds in key order. With the language for/range, iteration is in non-deterministic order.
```package main

import (
"os"
"text/template"
)

func main() {
m := map[string]int{
"hello": 13,
"world": 31,
"!":     71,
}

// iterating over key-value pairs:
template.Must(template.New("").Parse(`
{{- range \$k, \$v := . -}}
key = {{\$k}}, value = {{\$v}}
{{end -}}
`)).Execute(os.Stdout, m)

// iterating over keys:
template.Must(template.New("").Parse(`
{{- range \$k, \$v := . -}}
key = {{\$k}}
{{end -}}
`)).Execute(os.Stdout, m)

// iterating over values:
template.Must(template.New("").Parse(`
{{- range . -}}
value = {{.}}
{{end -}}
`)).Execute(os.Stdout, m)
}
```
Output:

Note order by key.

```key = !, value = 71
key = hello, value = 13
key = world, value = 31
key = !
key = hello
key = world
value = 71
value = 13
value = 31
```

## Groovy

Solution:

```def map = [lastName: "Anderson", firstName: "Thomas", nickname: "Neo", age: 24, address: "everywhere"]

println "Entries:"
map.each { println it }

println()
println "Keys:"
map.keySet().each { println it }

println()
println "Values:"
map.values().each { println it }
```
Output:
```Entries:
lastName=Anderson
firstName=Thomas
nickname=Neo
age=24

Keys:
lastName
firstName
nickname
age

Values:
Anderson
Thomas
Neo
24
everywhere```

## Harbour

```LOCAL arr := { 6 => 16, "eight" => 8, "eleven" => 11 }
LOCAL x

FOR EACH x IN arr
// key, value
? x:__enumKey(), x
// or key only
? x:__enumKey()
// or value only
? x
NEXT
```

with Data.Map:

```import qualified Data.Map as M

myMap :: M.Map String Int
myMap = M.fromList [("hello", 13), ("world", 31), ("!", 71)]

main :: IO ()
main =
(putStrLn . unlines) \$
[ show . M.toList     -- Pairs
, show . M.keys       -- Keys
, show . M.elems      -- Values
] <*>
pure myMap
```
Output:
```[("!",71),("hello",13),("world",31)]
["!","hello","world"]
[71,13,31]```

## Icon and Unicon

```procedure main()
t := table()
every t[a := !"ABCDE"] := map(a)

every pair := !sort(t) do
write("\t",pair," -> ",pair)

writes("Keys:")
every writes(" ",key(t))
write()

writes("Values:")
every writes(" ",!t)
write()
end
```
Output:
```->aai
A -> a
B -> b
C -> c
D -> d
E -> e
Keys: C E B D A
Values: c e b d a```

## Io

```myDict := Map with(
"hello", 13,
"world", 31,
"!"    , 71
)

// iterating over key-value pairs:
myDict foreach( key, value,
writeln("key = ", key, ", value = ", value)
)

// iterating over keys:
myDict keys foreach( key,
writeln("key = ", key)
)

// iterating over values:
myDict foreach( value,
writeln("value = ", value)
)
// or alternatively:
myDict values foreach( value,
writeln("value = ", value)
)
```

## J

Note that all J operations either iterate over the items of an array or can be made to do so. So to iterate over some sequence you need to refer to that sequence.

Using the J example from Creating an Associative Array...

Keys
```nl__example 0
```
Values
```get__example each nl__example 0
```
Both keys and values
```(,&< get__example) each nl__example 0
```

Note that this last is not likely to be useful in any practical context outside of learning the language.

## Java

```Map<String, Integer> map = new HashMap<String, Integer>();
map.put("hello", 1);
map.put("world", 2);
map.put("!", 3);

// iterating over key-value pairs:
for (Map.Entry<String, Integer> e : map.entrySet()) {
String key = e.getKey();
Integer value = e.getValue();
System.out.println("key = " + key + ", value = " + value);
}

// iterating over keys:
for (String key : map.keySet()) {
System.out.println("key = " + key);
}

// iterating over values:
for (Integer value : map.values()) {
System.out.println("value = " + value);
}
```

Java 8 version

```Map<String, Integer> map = new HashMap<>();
map.put("hello", 1);
map.put("world", 2);
map.put("!", 3);

// iterating over key-value pairs:
map.forEach((k, v) -> {
System.out.printf("key = %s, value = %s%n", k, v);
});

// iterating over keys:
map.keySet().forEach(k -> System.out.printf("key = %s%n", k));

// iterating over values:
map.values().forEach(v -> System.out.printf("value = %s%n", v));
```
Output:
```key = !, value = 3
key = world, value = 2
key = hello, value = 1
key = !
key = world
key = hello
value = 3
value = 2
value = 1```

## JavaScript

JavaScript does not have associative arrays until ECMAScript 6 brings Maps. In versions up to ES5.1, you may add properties to an empty object to achieve the same effect.

```var myhash = {}; //a new, empty object
myhash["hello"] = 3;
myhash.world = 6; //obj.name is equivalent to obj["name"] for certain values of name
myhash["!"] = 9;

//iterate using for..in loop
for (var key in myhash) {
//ensure key is in object and not in prototype
if (myhash.hasOwnProperty(key)) {
console.log("Key is: " + key + '. Value is: ' + myhash[key]);
}
}

//iterate using ES5.1 Object.keys() and Array.prototype.Map()
var keys = Object.keys(); //get Array of object keys (doesn't get prototype keys)
keys.map(function (key) {
console.log("Key is: " + key + '. Value is: ' + myhash[key]);
});
```

## Jq

In jq, there are several ways to iterate over compound structures:

```- functionally, e.g. using map on an array
- by enumeration, i.e. by generating a stream
- by performing a reduction
```

For the sake of brevity, therefore, in the following we will only illustrate the enumerative approach.

With respect to associative arrays (i.e. JSON objects), the fundamental functions are:

```- keys -- for producing an array of the keys (sorted)
- .[]  -- for producing a stream of the values
```

In jq > 1.4, keys_unsorted, for producing an array of the keys (in the order of creation), is also available.

```def mydict: {"hello":13, "world": 31, "!": 71};

# Iterating over the keys
mydict | keys[]
# "!"
# "hello"
# "world"

# Iterating over the values:
mydict[]
# 13
# 31
# 71

# Generating a stream of {"key": key, "value": value} objects:
mydict | to_entries[]
# {"key":"hello","value":13}
# {"key":"world","value":31}
# {"key":"!","value":71}

# Generating a stream of [key,value] arrays:
mydict | . as \$o | keys[] | [., \$o[.]]
#["!",71]
#["hello",13]
#["world",31]

# Generating a stream of [key,value] arrays, without sorting (jq > 1.4 required)
mydict | . as \$o | keys_unsorted[] | [., \$o[.]]
# ["hello",13]
# ["world",31]
# ["!",71]```

## Julia

Works with: Julia version 0.6
```dict = Dict("hello" => 13, "world" => 31, "!" => 71)

# applying a function to key-value pairs:
foreach(println, dict)

# iterating over key-value pairs:
for (key, value) in dict
println("dict[\$key] = \$value")
end

# iterating over keys:
for key in keys(dict)
@show key
end

# iterating over values:
for value in values(dict)
@show value
end
```
Output:
```key = !, value = 71
key = hello, value = 13
key = world, value = 31
key = !
key = hello
key = world
value = 71
value = 13
value = 31
```

## K

Creating a dictionary.

`   d: .((`"hello";1); (`"world";2);(`"!";3))`

The keys are available via "!".

```   !d
`hello `world `"!"

\$!d  / convert keys (symbols) as strings
("hello"
"world"
,"!")```

Print the key value pairs.

```   `0:{,/\$x,": ",d[x]}'!d
hello: 1
world: 2
!: 3```

The values are available via "[]".

```   d[]
1 2 3

{x+1}'d[]
2 3 4```

## Kotlin

```fun main(a: Array<String>) {
val map = mapOf("hello" to 1, "world" to 2, "!" to 3)

with(map) {
entries.forEach { println("key = \${it.key}, value = \${it.value}") }
keys.forEach { println("key = \$it") }
values.forEach { println("value = \$it") }
}
}
```
Output:
```key = hello, value = 1
key = world, value = 2
key = !, value = 3
key = hello
key = world
key = !
value = 1
value = 2
value = 3```

## Lang5

```: first  0 extract nip ; : second  1 extract nip ; : nip  swap drop ;
: say(*)  dup first " => " 2 compress "" join . second . ;

[['foo 5] ['bar 10] ['baz 20]] 'say apply drop```

## Lasso

```//iterate over associative array
//Lasso maps
local('aMap' = map('weight' = 112,
'height' = 45,
'name' = 'jason'))
' Map output: \n  '
#aMap->forEachPair => {^
//display pair, then show accessing key and value individually
#1+'\n  '
#1->first+': '+#1->second+'\n  '
^}
//display keys and values separately
'\n'
' Map Keys: '+#aMap->keys->join(',')+'\n'
' Map values: '+#aMap->values->join(',')+'\n'

//display using forEach
'\n'
' Use ForEach to iterate Map keys: \n'
#aMap->keys->forEach => {^
#1+'\n'
^}
'\n'
' Use ForEach to iterate Map values: \n'
#aMap->values->forEach => {^
#1+'\n'
^}
//the {^ ^} indicates that output should be printed (AutoCollect) ,
// if output is not desired, just { } is used
```

## LFE

### Keys and Values

```(let ((data '(#(key1 "foo") #(key2 "bar")))
(hash (: dict from_list data)))
(: dict fold
(lambda (key val accum)
(: io format '"~s: ~s~n" (list key val)))
0
hash))
```

### Just Keys

```(let ((data '(#(key1 "foo") #(key2 "bar")))
(hash (: dict from_list data)))
(: lists map
(lambda (key)
(: io format '"~s~n" (list key)))
(: dict fetch_keys hash)))
```

## Liberty BASIC

Needs the sublist library from http://basic.wikispaces.com/SubList+Library since LB does not have built-in associative arrays.

```data "red",      "255 50 50",       "green", "50 255 50",     "blue", "50 50 255"
data "my fave",  "220 120 120",     "black", "0 0 0"

myAssocList\$ =""

for i =1 to 5
call sl.Set myAssocList\$, k\$, dat\$
next i

keys\$ = ""   ' List to hold the keys in myList\$.
keys  = 0

keys = sl.Keys( myAssocList\$, keys\$)
print " Number of key-data pairs ="; keys

For i = 1 To keys
keyName\$ = sl.Get\$( keys\$, Str\$( i))
Print "  Key "; i; ":", keyName\$, "Data: ", sl.Get\$( myAssocList\$, keyName\$)
Next i

end```
``` Number of key-data pairs =5
Key 1:      red           Data:         255 50 50
Key 2:      green         Data:         50 255 50
Key 3:      blue          Data:         50 50 255
Key 4:      my fave       Data:         220 120 120
Key 5:      black         Data:         0 0 0
```

## Lingo

```hash = [#key1:"value1", #key2:"value2", #key3:"value3"]

-- iterate over key-value pairs
repeat with i = 1 to hash.count
put hash.getPropAt(i) & "=" & hash[i]
end repeat

-- iterating over values only can be written shorter
repeat with val in hash
put val
end repeat```

## LiveCode

```put 3 into fruit["apples"]
put 5 into fruit["pears"]
put 6 into fruit["oranges"]
put "none" into fruit["bananas"]

put "Keys:" & cr & the keys of fruit & cr into tTmp
put "Values 1:" & tab after tTmp
repeat for each line tKey in the keys of fruit
put fruit[tkey] & comma after tTmp
end repeat

-- need to copy array as combine will change variable
put fruit into fruit2
combine fruit2 using comma
put cr & "Values2:" & tab after tTmp
repeat for each item f2val in fruit2
put f2val & comma after tTmp
end repeat

combine fruit using return and ":"
put cr & "Key:Values" & cr & fruit after tTmp
-- alternatively, use same loop as for values 1 with tkey && fruit[tKey]

put tTmp```

Output

```Keys:
apples
pears
oranges
bananas
Values 1:	3,5,6,none,
Values2:	3,none,6,5,
Key:Values
apples:3
bananas:none
oranges:6
pears:5```

## Lua

```local t = {
["foo"] = "bar",
["baz"] = 6,
fortytwo = 7
}

for key,val in pairs(t) do
print(string.format("%s: %s", key, val))
end
```
Output:
```    fortytwo: 7
foo: bar
baz: 6
```

Note: the order in which `pairs` iterates over non-integer keys is not defined, so the order of lines in the output of the above code may differ from one run to another.

## M2000 Interpreter

```Module checkit {
\\ Inventories are objects with keys and values, or keys (used as read only values)
\\ They use hash function.
\\ Function TwoKeys return Inventory object (as a pointer to object)
Function TwoKeys {
Inventory Alfa="key1":=100, "key2":=200
=Alfa
}
M=TwoKeys()
Print Type\$(M)="Inventory"
\\ Normal Use:
\\ Inventories Keys are case sensitive
\\ M2000 identifiers are not case sensitive
Print M("key1"), m("key2")
\\ numeric values can convert to strings
Print M\$("key1"), m\$("key2")
\\ Iteration
N=Each(M)
While N {
Print Eval(N)  ' prints 100, 200 as number
Print M(N^!)  ' The same using index N^
}
N=Each(M)
While N {
Print Eval\$(N)  ' prints  100, 200 as strings
Print M\$(N^!)  ' The same using index N^
}
N=Each(M)
While N {
Print Eval\$(N, N^)  ' Prints Keys
}
\\ double iteration
Append M, "key3":=500
N=Each(M, 1, -1)  ' start to end
N1=Each(M, -1, 1) ' end to start
\\ 3x3 prints
While N {
While N1 {
Print format\$("{0}*{1}={2}", Eval(N1), Eval(N), Eval(N1)*Eval(N))
}
}
\\ sort results from lower product to greater product (3+2+1, 6 prints only)
N=Each(M, 1, -1)
While N {
N1=Each(M, N^+1, -1)
While N1 {
Print format\$("{0}*{1}={2}", Eval(N1), Eval(N), Eval(N1)*Eval(N))
}
}
N=Each(M)
N1=Each(M,-2, 1)  ' from second from end to start
\\ print only 2 values. While block ends when one iterator finish
While N, N1 {
Print Eval(N1)*Eval(N)
}
}
Checkit```

## M4

```divert(-1)
define(`for',
`ifelse(\$#,0,``\$0'',
`ifelse(eval(\$2<=\$3),1,
`pushdef(`\$1',\$2)\$4`'popdef(`\$1')\$0(`\$1',incr(\$2),\$3,`\$4')')')')
define(`new',`define(`\$1[size]key',0)')
define(`asize',`defn(`\$1[size]key')')
define(`aget',`defn(`\$1[\$2]')')
define(`akget',`defn(`\$1[\$2]key')')
define(`avget',`aget(\$1,akget(\$1,\$2))')
define(`aset',
`ifdef(\$1[\$2],
`',
`define(`\$1[size]key',incr(asize(`\$1')))`'define(\$1[asize(`\$1')]key,\$2)')`'define(\$1[\$2],\$3)')
define(`dquote', ``\$@'')
define(`akeyvalue',`dquote(akget(\$1,\$2),aget(\$1,akget(\$1,\$2)))')
define(`akey',`dquote(akget(\$1,\$2))')
define(`avalue',`dquote(aget(\$1,akget(\$1,\$2)))')
divert
new(`a')
aset(`a',`wow',5)
aset(`a',`wow',flame)
aset(`a',`bow',7)
key-value pairs
for(`x',1,asize(`a'),
`akeyvalue(`a',x)
')
keys
for(`x',1,asize(`a'),
`akey(`a',x)
')
values
for(`x',1,asize(`a'),
`avalue(`a',x)
')```
Output:
```key-value pairs
`wow',`flame'
`bow',`7'

keys
`wow'
`bow'

values
`flame'
`7'
```

## Maple

Iterate through indices when indices are all simple expressions:

```> T := table( [ "A" = 1, "B" = 2, "C" = 3, "D" = 4 ] );
> for i in indices( T, nolist ) do print(i ) end:
"A"

"B"

"C"

"D"```

Iterate through indices when indices may be expression sequences:

```> T := table( [ "a" = 1, "b" = 2, ("c","d") = 3 ] ):
> for i in indices( T ) do print( i, T[ op( i ) ] ) end:
["a"], 1

["b"], 2

["c", "d"], 3```

Return all index / entry pairs as equations:

```> for i in indices( T, pairs ) do print( i) end:
"a" = 1

"b" = 2

("c", "d") = 3```
```> for i in entries( T ) do print( i) end:




```

## Mathematica / Wolfram Language

```keys=DownValues[#,Sort->False][[All,1,1,1]]&;
hashes=#/@keys[#]&;

a="string";a["sometext"]=23;
keys[a]
->{2,sometext}
hashes[a]
->{string,23}
```

## MATLAB / Octave

Associative arrays can be defined as structs in Matlab and Octave.

```   keys = fieldnames(hash);
for k=1:length(keys),
key = keys{k};
value = getfield(hash,key);        % get value of key
hash = setfield(hash,key,-value);  % set value of key
end;
```

or

```   keys = fieldnames(hash);
for k=1:length(keys),
key = keys{k};
value = hash.(key);     % get value of key
hash.(key) = -value;    % set value of key
end;
```

## Maxima

```h: 6\$
h: 2\$

/* iterate over values */
for val in listarray(h) do (
print(val))\$

/* iterate over the keys */
for key in rest(arrayinfo(h), 2) do (
val: arrayapply(h, key),
print(key, val))\$
```

## MiniScript

```d = { 3: "test", "foo": 3 }

for keyVal in d
print keyVal   // produces results like: { "key": 3, "value": "test" }
end for

for key in d.indexes
print key
end for

for  val in d.values
print val
end for
```

## NetRexx

```/* NetRexx */
options replace format comments java crossref symbols

surname = 'Unknown' -- default value
surname['Fred'] = 'Bloggs'
surname['Davy'] = 'Jones'

try = 'Fred'
say surname[try] surname['Bert']

-- extract the keys
loop fn over surname
say fn.right(10) ':' surname[fn]
end fn
```

## NewLISP

```;; using an association list:
(setq alist '(("A" "a") ("B" "b") ("C" "c")))

;; list keys
(map first alist)

;; list values
(map last alist)

;; loop over the assocation list:
(dolist (elem alist)
(println (format "%s -> %s" (first elem) (last elem))))
```

## Nim

```import tables

var t: Table[int,string]

t = "one"
t = "two"
t = "three"
t = "four"

echo "t has " & \$t.len & " elements"

echo "has t key 4? " & \$t.hasKey(4)
echo "has t key 5? " & \$t.hasKey(5)

#iterate keys
echo "key iteration:"
for k in t.keys:
echo "at[" & \$k & "]=" & t[k]

#iterate pairs
echo "pair iteration:"
for k,v in t.pairs:
echo "at[" & \$k & "]=" & v
```
Output:
```t has 4 elements
has t key 4? true
has t key 5? false
key iteration:
at=one
at=two
at=three
at=four
pair iteration:
at=one
at=two
at=three
at=four
```

## Oberon-2

Works with: oo2c Version 2
```MODULE AssociativeArray;
IMPORT
Object:Boxed,
Out;
TYPE
Key = STRING;
Value = Boxed.LongInt;

VAR
assocArray: Dictionary.Dictionary(Key,Value);
iterK: Dictionary.IterKeys(Key,Value);
iterV: Dictionary.IterValues(Key,Value);
aux: Value;
k: Key;

BEGIN
assocArray := NEW(Dictionary.Dictionary(Key,Value));
assocArray.Set("ten",NEW(Value,10));
assocArray.Set("eleven",NEW(Value,11));

aux := assocArray.Get("ten");
Out.LongInt(aux.value,0);Out.Ln;
aux := assocArray.Get("eleven");
Out.LongInt(aux.value,0);Out.Ln;Out.Ln;

(* Iterate keys *)
iterK := assocArray.IterKeys();
WHILE (iterK.Next(k)) DO
Out.Object(k);Out.Ln
END;

Out.Ln;

(* Iterate values *)
iterV := assocArray.IterValues();
WHILE (iterV.Next(aux)) DO
Out.LongInt(aux.value,0);Out.Ln
END

END AssociativeArray.
```

## Objeck

```class Iteration {
function : Main(args : String[]) ~ Nil {
assoc_array := Collection.StringMap->New();
assoc_array->Insert("Hello", IntHolder->New(1));
assoc_array->Insert("World", IntHolder->New(2));
assoc_array->Insert("!", IntHolder->New(3));

keys := assoc_array->GetKeys();
values := assoc_array->GetValues();

each(i : keys) {
key := keys->Get(i)->As(String);
value := assoc_array->Find(key)->As(IntHolder)->Get();
"key={\$key}, value={\$value}"->PrintLine();
};

"-------------"->PrintLine();

each(i : keys) {
key := keys->Get(i)->As(String);
value := values->Get(i)->As(IntHolder)->Get();
"key={\$key}, value={\$value}"->PrintLine();
};
}
}```

## Objective-C

Works with: Objective-C version 2.0+
```NSDictionary *myDict = [NSDictionary dictionaryWithObjectsAndKeys:
[NSNumber numberWithInt:13], @"hello",
[NSNumber numberWithInt:31], @"world",
[NSNumber numberWithInt:71], @"!", nil];

// iterating over keys:
for (id key in myDict) {
NSLog(@"key = %@", key);
}

// iterating over values:
for (id value in [myDict objectEnumerator]) {
NSLog(@"value = %@", value);
}
```
Works with: Objective-C version <2.0
```NSDictionary *myDict = [NSDictionary dictionaryWithObjectsAndKeys:
[NSNumber numberWithInt:13], @"hello",
[NSNumber numberWithInt:31], @"world",
[NSNumber numberWithInt:71], @"!", nil];

// iterating over keys:
NSEnumerator *enm = [myDict keyEnumerator];
id key;
while ((key = [enm nextObject])) {
NSLog(@"key = %@", key);
}

// iterating over values:
enm = [myDict objectEnumerator];
id value;
while ((value = [enm nextObject])) {
NSLog(@"value = %@", value);
}
```
Works with: Cocoa version Mac OS X 10.6+
```NSDictionary *myDict = [NSDictionary dictionaryWithObjectsAndKeys:
[NSNumber numberWithInt:13], @"hello",
[NSNumber numberWithInt:31], @"world",
[NSNumber numberWithInt:71], @"!", nil];

// iterating over keys and values:
[myDict enumerateKeysAndObjectsUsingBlock: ^(id key, id value, BOOL *stop) {
NSLog(@"key = %@, value = %@", key, value);
}];
```

## OCaml

Association array:

```#!/usr/bin/env ocaml

let map = [| ('A', 1); ('B', 2); ('C', 3) |] ;;

(* iterate over pairs *)
Array.iter (fun (k,v) -> Printf.printf "key: %c - value: %d\n" k v) map ;;

(* iterate over keys *)
Array.iter (fun (k,_) -> Printf.printf "key: %c\n" k) map ;;

(* iterate over values *)
Array.iter (fun (_,v) -> Printf.printf "value: %d\n" v) map ;;

(* in functional programming it is often more useful to fold over the elements *)
Array.fold_left (fun acc (k,v) -> acc ^ Printf.sprintf "key: %c - value: %d\n" k v) "Elements:\n" map ;;
```

Hash table:

```let map = Hashtbl.create 42;;

(* iterate over pairs *)
Hashtbl.iter (fun k v -> Printf.printf "key: %c - value: %d\n" k v) map ;;

(* in functional programming it is often more useful to fold over the elements *)
Hashtbl.fold (fun k v acc -> acc ^ Printf.sprintf "key: %c - value: %d\n" k v) map "Elements:\n" ;;
```

Functional binary search tree:

```module CharMap = Map.Make (Char);;
let map = CharMap.empty;;
let map = CharMap.add 'A' 1 map;;
let map = CharMap.add 'B' 2 map;;
let map = CharMap.add 'C' 3 map;;

(* iterate over pairs *)
CharMap.iter (fun k v -> Printf.printf "key: %c - value: %d\n" k v) map ;;

(* in functional programming it is often more useful to fold over the elements *)
CharMap.fold (fun k v acc -> acc ^ Printf.sprintf "key: %c - value: %d\n" k v) map "Elements:\n" ;;
```

## Ol

```;;; create sample associative array
(define aa (list->ff '(
(hello . 1)
(world . 2)
(! . 3))))

(print aa)
; ==> #((! . 3) (hello . 1) (world . 2))

;;; simplest iteration over all associative array (using ff-iter, lazy iterator)
(let loop ((kv (ff-iter aa)))
(cond
((null? kv) #true)
((pair? kv)
(print (car kv))
(loop (cdr kv)))
(else (loop (force kv)))))
; ==> (! . 3)
; ==> (hello . 1)
; ==> (world . 2)

;;; iteration with returning value (using ff-fold)
(print
"folding result: "
(ff-fold
(lambda (result key value)
(print "key: " key ", value: " value)
(+ result 1))
0
aa))

; ==> key: !, value: 3
; ==> key: hello, value: 1
; ==> key: world, value: 2
; ==> folding result: 3

;;; same but right fold (using ff-foldr)
(print
"rfolding result: "
(ff-foldr
(lambda (result key value)
(print "key: " key ", value: " value)
(+ result 1))
0
aa))

; ==> key: world, value: 2
; ==> key: hello, value: 1
; ==> key: !, value: 3
; ==> rfolding result: 3

;;; at least create new array from existing (let's multiply every value by value)
(define bb (ff-map aa
(lambda (key value)
(* value value))))
(print bb)

; ==> #((! . 9) (hello . 1) (world . 4))```

## ooRexx

```d = .directory~new
d["hello"] = 1
d["world"] = 2
d["!"] = 3

-- iterating over keys:
loop key over d
say "key =" key
end

-- iterating over values:
loop value over d~allitems
say "value =" value
end

-- iterating over key-value pairs:
s = d~supplier
loop while s~available
say "key =" s~index", value =" s~item
s~next
end
```
Output:
```key = !
key = world
key = hello
value = 3
value = 2
value = 1
key = !, value = 3
key = world, value = 2
key = hello, value = 1```

## Oz

```declare
MyMap = unit('hello':13 'world':31 '!':71)
in
{ForAll {Record.toListInd MyMap} Show}  %% pairs
{ForAll {Record.arity     MyMap} Show}  %% keys
{ForAll {Record.toList    MyMap} Show}  %% values```

## PARI/GP

Works with: PARI/GP version 2.8.1+

The keys can be retried from a map with Vec:

`keys = Vec(M);`

You can iterate over the values as usual:

```for(i=1,#keys,
print(keys[i]," ",mapget(M,keys[i]))
)```

## Perl

```#! /usr/bin/perl
use strict;

my %pairs = ( "hello" => 13,
"world" => 31,
"!" => 71 );

# iterate over pairs

# Be careful when using each(), however, because it uses a global iterator
# associated with the hash. If you call keys() or values() on the hash in the
# middle of the loop, the each() iterator will be reset to the beginning. If
# you call each() on the hash somewhere in the middle of the loop, it will
# skip over elements for the "outer" each(). Only use each() if you are sure
# that the code inside the loop will not call keys(), values(), or each().
while ( my (\$k, \$v) = each %pairs) {
print "(k,v) = (\$k, \$v)\n";
}

# iterate over keys
foreach my \$key ( keys %pairs ) {
print "key = \$key, value = \$pairs{\$key}\n";
}
# or (see note about each() above)
while ( my \$key = each %pairs) {
print "key = \$key, value = \$pairs{\$key}\n";
}

# iterate over values
foreach my \$val ( values %pairs ) {
print "value = \$val\n";
}
```

## Phix

The first three lines create a simple dictionary, with keys and values of several different types (string/integer/sequence):

```with javascript_semantics
setd("one",1)
setd(2,"duo")
setd({3,4},{5,"six"})

function visitor(object key, object data, object /*userdata*/)
?{key,data}
return 1    -- (continue traversal)
end function
traverse_dict(routine_id("visitor"))
```
Output:
```{2,"duo"}
{{3,4},{5,"six"}}
{"one",1}
```

You could also use some of the map.e routines:

```with javascript_semantics
setd("one",1)
setd(2,"duo")
setd({3,4},{5,"six"})

requires("1.0.2") -- (map.e incompatible with p2js before that)
include builtins\map.e
?pairs()
?keys()
?values()
```
Output:
```{{2,"duo"},{{3,4},{5,"six"}},{"one",1}}
{2,{3,4},"one"}
{"duo",{5,"six"},1}
```

## Phixmonti

```include ..\Utilitys.pmt

def getd    /# dict key -- dict data #/
swap 1 get rot find nip
dup if
swap 2 get rot get nip
else
drop "Unfound"
endif
enddef

def setd    /# dict ( key data ) -- dict #/
1 get var ikey
2 get var idata
drop
1 get ikey find var p drop
p if
2 get idata p set 2 set
else
2 get idata 0 put 2 set
1 get ikey 0 put 1 set
endif
enddef

def pair    /# dict n -- dict ( k d ) #/
1 over 2 tolist var ikey
2 swap 2 tolist var idata
ikey sget
swap idata sget rot swap
2 tolist
enddef

def scandict    /# dict n -- dict ( ) #/
var n
1 get len nip
for
pair
n if n get nip endif
print nl
endfor
enddef

def pairs   /# dict -- dict ( ) #/
0 scandict
enddef

def keys
1 scandict
enddef

def values
2 scandict
enddef

/# ---------- MAIN ---------- #/

( ( ) ( ) )

( "one" 1 ) setd
( 2 "duo" ) setd
( ( 3 4 ) ( 5 "six" ) ) setd

pairs nl
keys nl
values```

## PHP

```<?php
\$pairs = array( "hello" => 1,
"world" => 2,
"!"     => 3 );

// iterate over key-value pairs
foreach(\$pairs as \$k => \$v) {
echo "(k,v) = (\$k, \$v)\n";
}

// iterate over keys
foreach(array_keys(\$pairs) as \$key) {
echo "key = \$key, value = \$pairs[\$key]\n";
}

// iterate over values
foreach(\$pairs as \$value) {
echo "values = \$value\n";
}
?>
```

## Picat

```go =>
Map = new_map([1=one,2=two,3=three,4=four]),
foreach(K=V in Map)
println(K=V)
end,
nl,

println(keys=Map.keys),
foreach(K in Map.keys.sort)
println(K=Map.get(K))
end,
nl,

println(values=Map.values),
foreach(V in Map.values.sort)
% This works but gets a warning: nonlocal_var_in_iterator_pattern
% println(V=[K : K=V in Map])

% No warning:
println(V=[K : K=V1 in Map,V1 == V])
end,
nl.```
Output:
```1 = one
2 = two
3 = three
4 = four

keys = [1,2,3,4]
1 = one
2 = two
3 = three
4 = four

values = [one,two,three,four]
four = 
one = 
three = 
two = ```

## PicoLisp

### Using properties

```(put 'A 'foo 5)
(put 'A 'bar 10)
(put 'A 'baz 15)

: (getl 'A)                            # Get the whole property list
-> ((15 . baz) (10 . bar) (5 . foo))

: (mapcar cdr (getl 'A))               # Get all keys
-> (baz bar foo)

: (mapcar car (getl 'A))               # Get all values
-> (15 10 5)```

### Using an index tree

```(idx 'A (def "foo" 5) T)
(idx 'A (def "bar" 10) T)
(idx 'A (def "baz" 15) T)

: A                                    # Get the whole tree
-> ("foo" ("bar" NIL "baz"))

:  (idx 'A)                            # Get all keys
-> ("bar" "baz" "foo")

:  (mapcar val (idx 'A))               # Get all values
-> (10 15 5)```

## Pike

note that the order is not alphabetic but depends on the hash value of the keys. the order is deterministic however.

```mapping(string:string) m = ([ "A":"a", "B":"b", "C":"c" ]);
foreach(m; string key; string value)
{
write(key+value);
}
Result: BbAaCc

// only keys
foreach(m; string key;)
{
write(key);
}
Result: BAC

// only values
foreach(m;; string value)
{
write(value);
}
Result: bac
```

## PostScript

```% over keys and values
<</a 1 /b 2 /c 3>> {= =} forall
% just keys
<</a 1 /b 2 /c 3>> {= } forall
% just values
<</a 1 /b 2 /c 3>> {pop =} forall
```

## Potion

We can traverse tables by key or by key and val. We cannot traverse tables only by val.

```mydictionary = (red=0xff0000, green=0x00ff00, blue=0x0000ff)

mydictionary each (key, val): (key, ":", val, "\n") join print.
mydictionary each (key): (key, "\n") join print.```

## PowerShell

Using the following hash table:

```\$h = @{ 'a' = 1; 'b' = 2; 'c' = 3 }
```

Iterating over the key/value pairs is slightly cumbersome as it requires an explicit call to `GetEnumerator`:

```\$h.GetEnumerator() | ForEach-Object { Write-Host Key: \$_.Name, Value: \$_.Value }
```

A `foreach` statement can also be used:

```foreach (\$e in \$h.GetEnumerator()) {
Write-Host Key: \$e.Name, Value: \$e.Value
}
```

Iterating over the keys:

```\$h.Keys | ForEach-Object { Write-Host Key: \$_ }

foreach (\$k in \$h.Keys) {
Write-Host Key: \$k
}
```

Iterating over the values:

```\$h.Values | ForEach-Object { Write-Host Value: \$_ }

foreach (\$v in \$h.Values) {
Write-Host Value: \$v
}
```

## Prolog

Following the example at Associative Array Creation (with the understanding that using a predicate to store a hash does not prevent a "key" from having more than one value):

```assert( mymap(key1,value1) ).
assert( mymap(key2,value1) ).
```

To perform the specific task at hand:

```?- forall( mymap(Key,Value), writeln( [Key,Value]) ).

[key1,value1]
[key2,value1]
```

In Prolog, however, iteration is "built-in". For example:

```?- mymap(key1, Y).
Y = value1.

?- mymap(X, value1).
X = key1 ;
X = key2.
```

To construct the list of keys:

```?- findall( X, mymap(X,value1), Xs).
Xs = [key1, key2].
```

To construct the list of distinct values:

```?- findall( Y, mymap(key1,Y), Ys).
Ys = [value1].
```

## PureBasic

Hashes are a built-in type called Map in Purebasic.

```NewMap dict.s()
dict("de") = "German"
dict("en") = "English"
dict("fr") = "French"

ForEach dict()
Debug MapKey(dict()) + ":" + dict()
Next
```

## Python

```myDict = { "hello": 13,
"world": 31,
"!"    : 71 }

# iterating over key-value pairs:
for key, value in myDict.items():
print ("key = %s, value = %s" % (key, value))

# iterating over keys:
for key in myDict:
print ("key = %s" % key)
# (is a shortcut for:)
for key in myDict.keys():
print ("key = %s" % key)

# iterating over values:
for value in myDict.values():
print ("value = %s" % value)
```

## QB64

```'dictionary is not native data type of QB64
' here a dictionary engine using a string to store data
Dim Shared Skey As String * 1, SValue As String * 1, EValue As String * 1
Skey = Chr\$(0)
SValue = Chr\$(1)
EValue = Chr\$(255)

'Demo area---------------->
Dim MyDictionary As String

If ChangeValue(MyDictionary, "a", "Ananas") Then Print "added new couple key value"
If ChangeValue(MyDictionary, "b", "Banana") Then Print "added new couple key value"
If ChangeValue(MyDictionary, "c", "cherry") Then Print "added new couple key value"
If ChangeValue(MyDictionary, "d", "Drake") Then Print "added new couple key value"
If ChangeValue(MyDictionary, "e", "Elm") Then Print "added new couple key value"
If ChangeValue(MyDictionary, "f", "Fire") Then Print "added new couple key value"
Print LenDict(MyDictionary)
Print "to key e there is  "; GetDict\$(MyDictionary, "e")
Print "to key e there is  "; GetDict\$(MyDictionary, "a")
If ChangeValue(MyDictionary, "e", "Elephant") Then Print " changed value of key passed"
Print "to key e there is  "; GetDict\$(MyDictionary, "e")
If Not (EraseKeyValue(MyDictionary, "e")) Then Print " Failed to erase key value passed" Else Print "Erased key value passed"
If GetDict\$(MyDictionary, "e") = "" Then Print " No couple key value found for key value 'e'"
If ChangeKey(MyDictionary, "e", "f") = 0 Then
Print "key -a- has value "; GetDict\$(MyDictionary, "a")
Print "we change key a to key e "
If ChangeKey(MyDictionary, "a", "e") = -1 Then
Print "key -a- has value "; GetDict\$(MyDictionary, "a")
Print "key -e- has value "; GetDict\$(MyDictionary, "e")
End If
End If
If InsertCouple(MyDictionary, "c", "m", "mellon") = -1 Then
Print " New couple inserted after key -c- "; GetDict\$(MyDictionary, "c")
Print " new couple is  key -m- "; GetDict\$(MyDictionary, "m")
End If
Print LenDict(MyDictionary)
' End demo area --------------->
End

' it returns value/s for a key
Function GetDict\$ (dict As String, Keys As String)
Dim StartK As Integer, StartV As Integer, EndV As Integer
StartK = InStr(dict, Skey + Keys + SValue)
StartV = InStr(StartK, dict, SValue)
EndV = InStr(StartV, dict, EValue)
If StartK = 0 Then GetDict\$ = "" Else GetDict = Mid\$(dict, StartV + 1, EndV - StartV)
End Function

' it changes value of a key or append the couple key, newvalue if key is new
Function ChangeValue (dict As String, Keys As String, NewValue As String)
ChangeValue = 0
Dim StartK As Integer, StartV As Integer, EndV As Integer
StartK = InStr(dict, Skey + Keys + SValue)
StartV = InStr(StartK, dict, SValue)
EndV = InStr(StartV, dict, EValue)
If StartK = 0 Then
dict = dict + Skey + Keys + SValue + NewValue + EValue
Else
dict = Left\$(dict, StartV) + NewValue + Right\$(dict, Len(dict) - EndV + 1)
End If
ChangeValue = -1
End Function

'it changes a key if it is in the dictionary
Function ChangeKey (dict As String, Keys As String, NewKey As String)
ChangeKey = 0
Dim StartK As Integer, StartV As Integer
StartK = InStr(dict, Skey + Keys + SValue)
StartV = InStr(StartK, dict, SValue)
If StartK = 0 Then
Exit Function
Else
dict = Left\$(dict, StartK) + NewKey + Right\$(dict, Len(dict) - StartV + 1)
End If
ChangeKey = -1
End Function

'it erases the couple key value
Function EraseKeyValue (dict As String, keys As String)
EraseKeyValue = 0
Dim StartK As Integer, StartV As Integer, EndV As Integer
StartK = InStr(dict, Skey + keys + SValue)
StartV = InStr(StartK, dict, SValue)
EndV = InStr(StartV, dict, EValue)
If StartK = 0 Then
Exit Function
Else
dict = Left\$(dict, StartK - 1) + Right\$(dict, Len(dict) - EndV + 1)
End If
EraseKeyValue = -1
End Function

'it inserts a couple after a defined key, if key is not in dictionary it append couple key value
Function InsertCouple (dict As String, SKeys As String, Keys As String, Value As String)
InsertCouple = 0
Dim StartK As Integer, StartV As Integer, EndV As Integer
StartK = InStr(dict, Skey + SKeys + SValue)
StartV = InStr(StartK, dict, SValue)
EndV = InStr(StartV, dict, EValue)
If StartK = 0 Then
dict = dict + Skey + Keys + SValue + Value + EValue
Else
dict = Left\$(dict, EndV) + Skey + Keys + SValue + Value + EValue + Right\$(dict, Len(dict) - EndV + 1)
End If
InsertCouple = -1
End Function

Function LenDict (dict As String)
LenDict = 0
Dim a As Integer, count As Integer
If Len(dict) <= 0 Then Exit Function
While a <= Len(dict)
a = InStr(a + 1, dict, EValue)
If a > 0 Then count = count + 1 Else Exit While
Wend
LenDict = count
End Function```

## R

R lacks a native representation of key-value pairs, but different structures allow named elements, which provide similar functionality.

### environment example

```> env <- new.env()
> env[["x"]] <- 123
> env[["x"]]
```
` 123`
```> index <- "1"
> env[[index]] <- "rainfed hay"
> for (name in ls(env)) {
+   cat(sprintf('index=%s, value=%s\n', name, env[[name]]))
+ }
```
```index=1, value=rainfed hay
index=x, value=123```

### vector example

```> x <- c(hello=1, world=2, "!"=3)
> print(x["!"])
```
```!
3```
```> print(unname(x["!"]))
```
` 3`

### list example

```> a <- list(a=1, b=2, c=3.14, d="xyz")
> print(a\$a)
```
` 1`
```> print(a\$d)
```
` "xyz"`

## Racket

Using the dictionary interface, different data structures can be treated as an associative array in Racket.

```#lang racket

(define dict1 #hash((apple . 5) (orange . 10))) ; hash table
(define dict2 '((apple . 5) (orange . 10)))     ; a-list
(define dict3 (vector "a" "b" "c"))             ; vector (integer keys)

(dict-keys dict1)                   ; => '(orange apple)
(dict-values dict2)                 ; => '(5 10)
(for/list ([(k v) (in-dict dict3)]) ; => '("0 -> a" "1 -> b" "2 -> c")
(format "~a -> ~a" k v))
```

## Raku

(formerly Perl 6)

Works with: Rakudo version 2015.12
```my %pairs = hello => 13, world => 31, '!' => 71;

for %pairs.kv -> \$k, \$v {
say "(k,v) = (\$k, \$v)";
}

# Stable order
for %pairs.sort(*.value)>>.kv -> (\$k, \$v) {
say "(k,v) = (\$k, \$v)";
}

{ say "\$^a => \$^b" } for %pairs.kv;

say "key = \$_" for %pairs.keys;

say "value = \$_" for %pairs.values;
```

## REXX

```/*REXX program demonstrates how to  set and display  values  for an  associative array. */
/*╔════════════════════════════════════════════════════════════════════════════════════╗
║ The (below) two REXX statements aren't really necessary,  but it shows how to      ║
║ define any and all entries in a associative array so that if a "key" is used that  ║
║ isn't defined, it can be displayed to indicate such,  or its value can be checked  ║
║ to determine if a particular associative array element has been set (defined).     ║
╚════════════════════════════════════════════════════════════════════════════════════╝*/
stateF.= ' [not defined yet] '                   /*sets any/all state  former  capitals.*/
stateN.= ' [not defined yet] '                   /*sets any/all state names.            */
w      = 0                                       /*the maximum  length  of a state name.*/
stateL =
/*╔════════════════════════════════════════════════════════════════════════════════════╗
║ The list of states (empty as of now).  It's convenient to have them in alphabetic  ║
║ order;  they'll be listed in the order as they are in the REXX program below).     ║
║ In REXX,  when a key is used  (for a stemmed array,  as they are called in REXX),  ║
║ and the key isn't assigned a value,  the key's  name  is stored (internally)  as   ║
║ uppercase  (Latin)  characters  (as in the examples below.   If the  key  has a    ║
║ a value, the key's value is used as is  (i.e.:  no upper translation is performed).║
║ Actually,  any characters can be used,  including blank(s)  and  non─displayable   ║
║ characters  (including   '00'x,   'ff'x,   commas,   periods,   quotes,   ···).    ║
╚════════════════════════════════════════════════════════════════════════════════════╝*/
call setSC 'al',  "Alabama"            ,  'Tuscaloosa'
call setSC 'ca',  "California"         ,  'Benicia'
call setSC 'co',  "Colorado"           ,  'Denver City'
call setSC 'ct',  "Connecticut"        ,  'Hartford and New Haven  (jointly)'
call setSC 'de',  "Delaware"           ,  'New-Castle'
call setSC 'ga',  "Georgia"            ,  'Milledgeville'
call setSC 'il',  "Illinois"           ,  'Vandalia'
call setSC 'in',  "Indiana"            ,  'Corydon'
call setSC 'ia',  "Iowa"               ,  'Iowa City'
call setSC 'la',  "Louisiana"          ,  'New Orleans'
call setSC 'me',  "Maine"              ,  'Portland'
call setSC 'mi',  "Michigan"           ,  'Detroit'
call setSC 'ms',  "Mississippi"        ,  'Natchez'
call setSC 'mo',  "Missouri"           ,  'Saint Charles'
call setSC 'mt',  "Montana"            ,  'Virginia City'
call setSC 'ne',  "Nebraska"           ,  'Lancaster'
call setSC 'nh',  "New Hampshire"      ,  'Exeter'
call setSC 'ny',  "New York"           ,  'New York'
call setSC 'nc',  "North Carolina"     ,  'Fayetteville'
call setSC 'oh',  "Ohio"               ,  'Chillicothe'
call setSC 'ok',  "Oklahoma"           ,  'Guthrie'
call setSC 'pa',  "Pennsylvania"       ,  'Lancaster'
call setSC 'sc',  "South Carolina"     ,  'Charlestown'
call setSC 'tn',  "Tennessee"          ,  'Murfreesboro'
call setSC 'vt',  "Vermont"            ,  'Windsor'

do j=1  for words(stateL)                 /*show all capitals that were defined. */
\$= word(stateL, j)                        /*get the next (USA) state in the list.*/
say 'the former capital of  ('\$") "    left(stateN.\$, w)      " was "      stateC.\$
end    /*j*/                              /* [↑]   show states that were defined.*/
exit                                             /*stick a fork in it,  we're all done. */
/*──────────────────────────────────────────────────────────────────────────────────────*/
setSC: parse arg code,name,cap;   upper code     /*get code, name & cap.; uppercase code*/
stateL= stateL code                       /*keep a list of all the US state codes*/
stateN.code= name; w= max(w,length(name)) /*define the state's name;  max width. */
stateC.code= cap                          /*   "    "     "   code to the capital*/
```
output   when using the internal default input:
```the former capital of  (AL)  Alabama         was  Tuscaloosa
the former capital of  (CA)  California      was  Benicia
the former capital of  (CO)  Colorado        was  Denver City
the former capital of  (CT)  Connecticut     was  Hartford and New Haven  (jointly)
the former capital of  (DE)  Delaware        was  New-Castle
the former capital of  (GA)  Georgia         was  Milledgeville
the former capital of  (IL)  Illinois        was  Vandalia
the former capital of  (IN)  Indiana         was  Corydon
the former capital of  (IA)  Iowa            was  Iowa City
the former capital of  (LA)  Louisiana       was  New Orleans
the former capital of  (ME)  Maine           was  Portland
the former capital of  (MI)  Michigan        was  Detroit
the former capital of  (MS)  Mississippi     was  Natchez
the former capital of  (MO)  Missouri        was  Saint Charles
the former capital of  (MT)  Montana         was  Virginia City
the former capital of  (NE)  Nebraska        was  Lancaster
the former capital of  (NH)  New Hampshire   was  Exeter
the former capital of  (NY)  New York        was  New York
the former capital of  (NC)  North Carolina  was  Fayetteville
the former capital of  (OH)  Ohio            was  Chillicothe
the former capital of  (OK)  Oklahoma        was  Guthrie
the former capital of  (PA)  Pennsylvania    was  Lancaster
the former capital of  (SC)  South Carolina  was  Charlestown
the former capital of  (TN)  Tennessee       was  Murfreesboro
the former capital of  (VT)  Vermont         was  Windsor
```

When this example was started, the intention was to list the former capitals by key.   Unfortunately, there's a duplicate capital   (Lancaster).

## Ring

```# Project : Associative array/Iteration

lst = [["hello", 13], ["world", 31], ["!", 71]]
for n = 1 to len(lst)
see lst[n] + " : " + lst[n] + nl
next```

Output:

```hello : 13
world : 31
! : 71
```

## RLaB

Associative arrays are called lists in RLaB.

```x = <<>>;  // create an empty list
x.hello = 1;
x.world = 2;
x.["!"] = 3;

// to iterate over identifiers of a list one needs to use the function ''members''
// the identifiers are returned as a lexicographically ordered string row-vector
// here    ["!", "hello", "world"]
for(i in members(x))
{ printf("%s %g\n", i,  x.[i]); }

// occasionally one needs to check if there exists member of a list
y = members(x);  // y contains ["!", "hello", "world"]
clear(x.["!"]);  // remove member with identifier "!" from the list "x"
for(i in y)
{ printf("%s %g\n", i,  x.[i]); }  // this produces error because x.["!"] does not exist

for(i in y)
{
if (exist(x.[i]))
{ printf("%s %g\n", i,  x.[i]); }  // we print a member of the list "x" only if it exists
}```

## Ruby

```my_dict = { "hello" => 13,
"world" => 31,
"!"     => 71 }

# iterating over key-value pairs:
my_dict.each {|key, value| puts "key = #{key}, value = #{value}"}
# or
my_dict.each_pair {|key, value| puts "key = #{key}, value = #{value}"}

# iterating over keys:
my_dict.each_key {|key| puts "key = #{key}"}

# iterating over values:
my_dict.each_value {|value| puts "value =#{value}"}
```

another way:

```for key, value in my_dict
puts "key = #{key}, value = #{value}"
end

for key in my_dict.keys
puts "key = #{key}"
end

for value in my_dict.values
puts "value = #{value}"
end
```
Output:
```key = hello, value = 13
key = world, value = 31
key = !, value = 71
key = hello
key = world
key = !
value = 13
value = 31
value = 71
```

## Rust

```use std::collections::HashMap;
fn main() {
let mut olympic_medals = HashMap::new();
olympic_medals.insert("United States", (1072, 859, 749));
olympic_medals.insert("Soviet Union", (473, 376, 355));
olympic_medals.insert("Great Britain", (246, 276, 284));
olympic_medals.insert("Germany", (252, 260, 270));
for (country, medals) in olympic_medals {
println!("{} has had {} gold medals, {} silver medals, and {} bronze medals",
country, medals.0, medals.1, medals.2);

}
}
```
Output:

Note that `HashMap` does not preserve order (if this is important, `std::collections::BTreeMap` is what you want.)

```Germany has had 252 gold medals, 260 silver medals, and 270 bronze medals
United States has had 1072 gold medals, 859 silver medals, and 749 bronze medals
Soviet Union has had 473 gold medals, 376 silver medals, and 355 bronze medals
Great Britain has had 246 gold medals, 276 silver medals, and 284 bronze medals
```

## Scala

```val m = Map("Amsterdam" -> "Netherlands", "New York" -> "USA", "Heemstede" -> "Netherlands")

println(f"Key->Value: \${m.mkString(", ")}%s")
println(f"Pairs: \${m.toList.mkString(", ")}%s")
println(f"Keys: \${m.keys.mkString(", ")}%s")
println(f"Values: \${m.values.mkString(", ")}%s")
println(f"Unique values: \${m.values.toSet.mkString(", ")}%s")
```
Output:
```
Key->Value: Amsterdam -> Netherlands, New York -> USA, Heemstede -> Netherlands
Pairs: (Amsterdam,Netherlands), (New York,USA), (Heemstede,Netherlands)
Keys: Amsterdam, New York, Heemstede
Values: Netherlands, USA, Netherlands
Unique values: Netherlands, USA

```

## Scheme

Works with: Gauche Scheme
```;; Create an associative array (hash-table) whose keys are strings:
(define table (hash-table 'string=?
'("hello" . 0) '("world" . 22) '("!" . 999)))

;; Iterate over the table, passing the key and the value of each entry
;; as arguments to a function:
(hash-table-for-each
table
;; Create by "partial application" a function that accepts 2 arguments,
;; the key and the value:
(pa\$ format #t "Key = ~a, Value = ~a\n"))
```

Output:

```Key = !, Value = 999
Key = world, Value = 22
Key = hello, Value = 0
```
```;; Iterate over the table and create a list of the keys and the
;; altered values:
(hash-table-map
table
(lambda (key val) (list key (+ val 5000))))

;; Create a new table that has the same keys but altered values.
(use gauche.collection)
(map-to <hash-table>
(lambda (k-v) (cons (car k-v) (+ (cdr k-v) 5000)))
table)
```

To get a list of the keys or of the values of the table, use one of the following:

```(hash-table-keys table)
(hash-table-values table)
```

### For persistent associative arrays

Works with: CHICKEN version 5.3.0
Library: r7rs
Library: srfi-1

Here is a variant of persistent associative arrays that includes generators. Such generators are functionally equivalent to iterators; the only important difference is they are executable procedures rather than passive objects. Note also that, because these associative arrays are persistent, iterating through their structure is much safer than it would be in a conventional hash table, which might change or even disappear while you were doing the iteration.

What I present here is a trimmed-down version of what you might find in a prefabricated library, such as an implementation of SRFI-125. I suppose part of my point in presenting this is that ‘associative arrays’ are not actually part of the Scheme language (even in R6RS), but rather are library add-ons. Someone else has done the sort of thing I am demonstrating here. This is in contrast to, say, Awk, or Icon, where associative ‘arrays’ really are built into the language.

(To save space, I have removed comments you can read at the section for persistent associative arrays.)

```(cond-expand
(r7rs)
(chicken (import r7rs)))

(define-library (suspendable-procedures)

(export &fail failure? success? suspend fail-forever
make-generator-procedure)

(import (scheme base))

(begin

(define-record-type <&fail>
(make-the-one-unique-&fail-that-you-must-not-make-twice)
do-not-use-this:&fail?)

(define &fail
(make-the-one-unique-&fail-that-you-must-not-make-twice))

(define (failure? f) (eq? f &fail))
(define (success? f) (not (failure? f)))
(define *suspend* (make-parameter (lambda (x) x)))
(define (suspend v) ((*suspend*) v))
(define (fail-forever)
(let loop ()
(suspend &fail)
(loop)))

(define (make-generator-procedure thunk)
;; This is for making a suspendable procedure that takes no
;; arguments when resumed. The result is a simple generator of
;; values.
(define (next-run return)
(define (my-suspend v)
(set! return (call/cc (lambda (resumption-point)
(set! next-run resumption-point)
(return v)))))
(parameterize ((*suspend* my-suspend))
(suspend (thunk))
(fail-forever)))
(lambda () (call/cc next-run)))

)) ;; end library (suspendable-procedures)

(define-library (avl-trees)
;;
;; Persistent (that is, ‘immutable’) AVL trees for R7RS Scheme.
;;
;; References:
;;
;;   * Niklaus Wirth, 1976. Algorithms + Data Structures =
;;     Programs. Prentice-Hall, Englewood Cliffs, New Jersey.
;;
;;   * Niklaus Wirth, 2004. Algorithms and Data Structures. Updated
;;     by Fyodor Tkachov, 2014.
;;

(export avl-make-generator)
(export avl avl? avl-empty? avl-insert avl-search-values)
(export avl-check-usage)

(import (scheme base))
(import (scheme case-lambda))
(import (scheme process-context))
(import (scheme write))
(import (suspendable-procedures))

(begin

(define-syntax avl-check-usage
(syntax-rules ()
((_ pred msg)
(or pred (usage-error msg)))))

(define-record-type <avl>
(%avl key data bal left right)
avl?
(key %key)
(data %data)
(bal %bal)
(left %left)
(right %right))

(define avl-make-generator
(case-lambda
((tree) (avl-make-generator tree 1))
((tree direction)
(if (negative? direction)
(make-generator-procedure
(lambda ()
(define (traverse p)
(unless (or (not p) (avl-empty? p))
(traverse (%right p))
(suspend (cons (%key p) (%data p)))
(traverse (%left p)))
&fail)
(traverse tree)))
(make-generator-procedure
(lambda ()
(define (traverse p)
(unless (or (not p) (avl-empty? p))
(traverse (%left p))
(suspend (cons (%key p) (%data p)))
(traverse (%right p)))
&fail)
(traverse tree)))))))

(define (avl) (%avl #f #f #f #f #f))

(define (avl-empty? tree)
(avl-check-usage
(avl? tree)
"avl-empty? expects an AVL tree as argument")
(not (%bal tree)))

(define (avl-search-values pred<? tree key)
(define (search p)
(if (not p)
(values #f #f)
(let ((k (%key p)))
(cond ((pred<? key k) (search (%left p)))
((pred<? k key) (search (%right p)))
(else (values (%data p) #t))))))
(avl-check-usage
(procedure? pred<?)
"avl-search-values expects a procedure as first argument")
(if (avl-empty? tree)
(values #f #f)
(search tree)))

(define (avl-insert pred<? tree key data)
(define (search p fix-balance?)
(cond
((not p)
(values (%avl key data 0 #f #f) #t))
((pred<? key (%key p))
(let-values (((p1 fix-balance?)
(search (%left p) fix-balance?)))
(cond
((not fix-balance?)
(let ((p^ (%avl (%key p) (%data p) (%bal p)
p1 (%right p))))
(values p^ #f)))
(else
(case (%bal p)
((1)
(let ((p^ (%avl (%key p) (%data p) 0
p1 (%right p))))
(values p^ #f)))
((0)
(let ((p^ (%avl (%key p) (%data p) -1
p1 (%right p))))
(values p^ fix-balance?)))
((-1)
(case (%bal p1)
((-1)
(let* ((p^ (%avl (%key p) (%data p) 0
(%right p1) (%right p)))
(p1^ (%avl (%key p1) (%data p1) 0
(%left p1) p^)))
(values p1^ #f)))
((0 1)
(let* ((p2 (%right p1))
(bal2 (%bal p2))
(p^ (%avl (%key p) (%data p)
(- (min bal2 0))
(%right p2) (%right p)))
(p1^ (%avl (%key p1) (%data p1)
(- (max bal2 0))
(%left p1) (%left p2)))
(p2^ (%avl (%key p2) (%data p2) 0
p1^ p^)))
(values p2^ #f)))
(else (internal-error))))
(else (internal-error)))))))

((pred<? (%key p) key)
(let-values (((p1 fix-balance?)
(search (%right p) fix-balance?)))
(cond
((not fix-balance?)
(let ((p^ (%avl (%key p) (%data p) (%bal p)
(%left p) p1)))
(values p^ #f)))
(else
(case (%bal p)
((-1)
(let ((p^ (%avl (%key p) (%data p) 0
(%left p) p1)))
(values p^ #f)))
((0)
(let ((p^ (%avl (%key p) (%data p) 1
(%left p) p1)))
(values p^ fix-balance?)))
((1)
(case (%bal p1)
((1)
(let* ((p^ (%avl (%key p) (%data p) 0
(%left p) (%left p1)))
(p1^ (%avl (%key p1) (%data p1) 0
p^ (%right p1))))
(values p1^ #f)))
((-1 0)
(let* ((p2 (%left p1))
(bal2 (%bal p2))
(p^ (%avl (%key p) (%data p)
(- (max bal2 0))
(%left p) (%left p2)))
(p1^ (%avl (%key p1) (%data p1)
(- (min bal2 0))
(%right p2) (%right p1)))
(p2^ (%avl (%key p2) (%data p2) 0
p^ p1^)))
(values p2^ #f)))
(else (internal-error))))
(else (internal-error)))))))
(else
(values (%avl key data (%bal p) (%left p) (%right p))
#f))))
(avl-check-usage
(procedure? pred<?)
"avl-insert expects a procedure as first argument")
(if (avl-empty? tree)
(%avl key data 0 #f #f)
(let-values (((p fix-balance?) (search tree #f)))
p)))

(define (internal-error)
(display "internal error\n" (current-error-port))
(emergency-exit 123))

(define (usage-error msg)
(display "Procedure usage error:\n" (current-error-port))
(display "  " (current-error-port))
(display msg (current-error-port))
(newline (current-error-port))
(exit 1))

)) ;; end library (avl-trees)

(define-library (associative-arrays)
;;
;; Persistent associative ‘arrays’ for R7RS Scheme.
;;
;; The structure is not actually an array, but is made of AVL trees
;; and association lists. Given a good hash function, it should
;; average logarithmic performance.
;;

(export assoc-array-make-pair-generator
assoc-array-make-key-generator
assoc-array-make-data-generator)
(export assoc-array assoc-array? assoc-array-set assoc-array-ref)

(import (scheme base))
(import (scheme case-lambda))
(import (scheme write))
(import (suspendable-procedures))
(import (avl-trees))

(cond-expand
(chicken (import (only (srfi 1) alist-delete)))
;; Insert whatever you need here for your Scheme.
(else))

(begin

(define-record-type <assoc-array>
(%assoc-array hashfunc pred=? default table)
assoc-array?
(hashfunc %hashfunc)
(pred=? %pred=?)
(default %default)
(table %table))

(define (assoc-array-make-generator array kind)
(define tree-traverser (avl-make-generator (%table array)))
(define get-desired-part
(cond ((eq? kind 'key) (lambda (pair) (car pair)))
((eq? kind 'data) (lambda (pair) (cdr pair)))
(else (lambda (pair) pair))))
(make-generator-procedure
(lambda ()
(let traverse ()
(let ((tree-entry (tree-traverser)))
(when (success? tree-entry)
(let scan-lst ((lst (cdr tree-entry)))
(when (pair? lst)
(suspend (get-desired-part (car lst)))
(scan-lst (cdr lst))))
(traverse))))
&fail)))

(define (assoc-array-make-pair-generator array)
(assoc-array-make-generator array 'pair))

(define (assoc-array-make-key-generator array)
(assoc-array-make-generator array 'key))

(define (assoc-array-make-data-generator array)
(assoc-array-make-generator array 'data))

(define assoc-array
(case-lambda
((hashfunc)
(let ((pred=? equal?)
(default #f))
(assoc-array hashfunc pred=? default)))
((hashfunc pred=?)
(let ((default #f))
(assoc-array hashfunc pred=? default)))
((hashfunc pred=? default)
(%assoc-array hashfunc pred=? default (avl)))))

(define (assoc-array-set array key data)
(let ((hashfunc (%hashfunc array))
(pred=? (%pred=? array))
(default (%default array))
(table (%table array)))
(let ((hash-value (hashfunc key)))
(let*-values
(((alst found?) (avl-search-values < table hash-value)))
(cond
(found?
(let* ((alst (alist-delete key alst pred=?))
(alst `((,key . ,data) . ,alst))
(table (avl-insert < table hash-value alst)))
(%assoc-array hashfunc pred=? default table)))
(else
(let* ((alst `((,key . ,data)))
(table (avl-insert < table hash-value alst)))
(%assoc-array hashfunc pred=? default table))))))))

(define (assoc-array-ref array key)
(let* ((hashfunc (%hashfunc array))
(hash-value (hashfunc key)))
(let*-values
(((alst found?)
(avl-search-values < (%table array) hash-value)))
(if found?
(let ((pair (assoc key alst (%pred=? array))))
(if pair
(cdr pair)
(%default array)))
(%default array)))))

)) ;; end library (associative-arrays)

(cond-expand
(DEMONSTRATION
(begin
(import (scheme base))
(import (scheme write))
(import (suspendable-procedures))
(import (associative-arrays))

(define (hashfunc s)
;; Using Knuth’s random number generator to concoct a quick and
;; dirty and probably very bad hash function. It should be much
;; better to use something like SpookyHash, but this is a demo.
(define a 6364136223846793005)
(define c 1442695040888963407)
(define M (expt 2 64))
(let ((n (string-length s))
(h 123))
(do ((i 0 (+ i 1)))
((= i n))
(let* ((x (char->integer (string-ref s i)))
(x (+ (* a (+ h x)) c)))
(set! h (truncate-remainder x M))))
h))

(define a (assoc-array hashfunc))

;; Fill the associative array ‘a’ with (string . number)
;; associations.
(do ((i 1 (+ i 1)))
((= i 11))
(set! a (assoc-array-set a (number->string i) i)))

;; Go through the association pairs (in arbitrary order) with a
;; generator.
(let ((gen (assoc-array-make-pair-generator a)))
(do ((pair (gen) (gen)))
((failure? pair))
(write pair) (display " "))
(newline))

;; Go through the keys (in arbitrary order) with a generator.
(let ((gen (assoc-array-make-key-generator a)))
(do ((key (gen) (gen)))
((failure? key))
(write key) (display " "))
(newline))

;; Go through the values (in arbitrary order) with a generator.
(let ((gen (assoc-array-make-data-generator a)))
(do ((value (gen) (gen)))
((failure? value))
(write value) (display " "))
(newline))

))
(else))
```
Output:
```\$ csc -DDEMONSTRATION -R r7rs -X r7rs associative_array_with_generators.scm && ./associative_array_with_generators
("3" . 3) ("6" . 6) ("9" . 9) ("1" . 1) ("4" . 4) ("7" . 7) ("2" . 2) ("10" . 10) ("5" . 5) ("8" . 8)
"3" "6" "9" "1" "4" "7" "2" "10" "5" "8"
3 6 9 1 4 7 2 10 5 8```

## Seed7

```\$ include "seed7_05.s7i";

const type: dictType is hash [string] integer;
var dictType: myDict is dictType.value;

const proc: main is func
local
var string: stri is "";
var integer: number is 0;
begin
myDict @:= ["hello"] 1;
myDict @:= ["world"] 2;
myDict @:= ["!"] 3;

# iterating over key-value pairs:
for number key stri range myDict do
writeln("key = " <& number <& ", value = " <& stri);
end for;

# iterating over keys:
for key stri range myDict do
writeln("key = " <& stri);
end for;

# iterating over values:
for number range myDict do
writeln("value = " <& number);
end for;
end func;```
Output:
```key = 3, value = !
key = 1, value = hello
key = 2, value = world
key = !
key = hello
key = world
value = 3
value = 1
value = 2
```

## SenseTalk

```put {name:"Fluffy", type:"Rabbit", color:"White"} into animal
put "Carries a watch" into animal's habits

put "The animal: " & animal
put "The keys: " & keys of animal
put "The values: " & animal's values
// Keys and Values
put ,"All Properties:"
repeat with each [key,value] in animal
put !"Key: [[key]]  Value: [[value]]"
end repeat

// Keys only
put ,"Keys:"
repeat with each [key] in animal
put key
end repeat

// Values only
put ,"Values:"
repeat with each [,value] in animal
put value
end repeat

// Using an iterator
put ,"Treating the property list as an iterator:"
put animal's nextValue -- calling any of the "next" functions begins iteration
put animal's nextKeyValue
put animal's nextKey
put animal's nextKeyValue
put animal's nextValue -- walking off the end returns a unique endValue```
Output:
```The animal: {color:"White", habits:"Carries a watch", name:"Fluffy", type:"Rabbit"}
The keys: ["color","habits","name","type"]
The values: ["White","Carries a watch","Fluffy","Rabbit"]

All Properties:
Key: color  Value: White
Key: habits  Value: Carries a watch
Key: name  Value: Fluffy
Key: type  Value: Rabbit

Keys:
color
habits
name
type

Values:
White
Carries a watch
Fluffy
Rabbit

Treating the property list as an iterator:
White
["habits","Carries a watch"]
name
["type","Rabbit"]
ⓔ ⓝ ⓓ
```

## Sidef

```var hash = Hash.new(
key1 => 'value1',
key2 => 'value2',
)

# Iterate over key-value pairs
hash.each { |key, value|
say "#{key}: #{value}";
}

# Iterate only over keys
hash.keys.each { |key|
say key;
}

# Iterate only over values
hash.values.each { |value|
say value;
}
```
Output:
```key1: value1
key2: value2
key1
key2
value1
value2
```

## Slate

In Slate, all associative mappings inherit from Mapping, so they all have the same protocol. Even Sequences obey it, in addition to their own protocol for collections with ordered integer-range keys.

```define: #pairs -> ({'hello' -> 1. 'world' -> 2. '!' -> 3. 'another!' -> 3} as: Dictionary).
pairs keysAndValuesDo: [| :key :value |
inform: '(k, v) = (' ; key printString ; ', ' ; value printString ; ')'
].

pairs keysDo: [| :key |
inform: '(k, v) = (' ; key printString ; ', ' ; (pairs at: key) printString ; ')'
].

pairs do: [| :value |
inform: 'value = ' ; value printString
].```

## Smalltalk

Works with: GNU Smalltalk
```|pairs|
pairs := Dictionary
from: { 'hello' -> 1. 'world' -> 2. '!' -> 3. 'another!' -> 3 }.

"iterate over keys and values"
pairs keysAndValuesDo: [ :k :v |
('(k, v) = (%1, %2)' % { k. v }) displayNl
].

"iterate over keys"
pairs keysDo: [ :key |
('key = %1, value = %2' % { key. pairs at: key }) displayNl
].

"iterate over values"
pairs do: [ :value |
('value = %1' % { value }) displayNl
].
```

We could also obtain a set of keys or a collection of values and iterate over them with "do:":

```(pairs keys) do: [ :k | "..." ].
(pairs values) do: [ :v | "..." ].
```

## SNOBOL4

Works with: Macro Spitbol
Works with: Snobol4+
Works with: CSnobol
```*       # Create sample table
t = table()
t<'cat'> = 'meow'
t<'dog'> = 'woof'
t<'pig'> = 'oink'

*       # Convert table to key/value array
a = convert(t,'array')

*       # Iterate pairs
ploop   i = i + 1; output = a<i,1> ' -> ' a<i,2> :s(ploop)
*       # Iterate keys
kloop   j = j + 1; output = a<j,1> :s(kloop)
*       # Iterate vals
vloop   k = k + 1; output = a<k,2> :s(vloop)
end```

## Stata

```mata
// Create an associative array
a=asarray_create()
asarray(a,"one",1)
asarray(a,"two",2)

// Loop over entries
loc=asarray_first(a)
do {
printf("%s %f\n",asarray_key(a,loc),asarray_contents(a,loc))
loc=asarray_next(a,loc)
} while(loc!=NULL)
end
```

## Swift

```let myMap = [
"hello": 13,
"world": 31,
"!"    : 71 ]

// iterating over key-value pairs:
for (key, value) in myMap {
println("key = \(key), value = \(value)")
}
```

## Tcl

### With Arrays

```array set myAry {
# list items here...
}

# Iterate over keys and values
foreach {key value} [array get myAry] {
puts "\$key -> \$value"
}

# Iterate over just keys
foreach key [array names myAry] {
puts "key = \$key"
}

# There is nothing for directly iterating over just the values
# Use the keys+values version and ignore the keys
```

### With Dictionaries

Works with: Tcl version 8.5
```set myDict [dict create ...]; # Make the dictionary

# Iterate over keys and values
dict for {key value} \$myDict {
puts "\$key -> \$value"
}

# Iterate over keys
foreach key [dict keys \$myDict] {
puts "key = \$key"
}

# Iterate over values
foreach value [dict values \$myDict] {
puts "value = \$value"
}
```

## TXR

```(defvarl h (hash))

(each ((k '(a b c))
(v '(1 2 3)))
(set [h k] v))

(dohash (k v h)
(put-line `@k -> @v`))```
Run:
```\$ txr hash.tl
c -> 3
b -> 2
a -> 1```

## UNIX Shell

Two shells have associative arrays, but they use different syntax to access their keys.

Works with: ksh93
```typeset -A a=([key1]=value1 [key2]=value2)

# just keys
printf '%s\n' "\${!a[@]}"

# just values
printf '%s\n' "\${a[@]}"

# keys and values
for key in "\${!a[@]}"; do
printf '%s => %s\n' "\$key" "\${a[\$key]}"
done
```
Works with: zsh
```typeset -A a
a=(key1 value1 key2 value2)

# just keys
print -l -- \${(k)a}

# just values
print -l -- \${(v)a}

# keys and values
printf '%s => %s\n' \${(kv)a}
```

## Vala

Library: Gee
```using Gee;

void main(){
// declare HashMap
var map = new HashMap<string, double?>();

// set 3 entries
map["pi"] = 3.14;
map["e"] = 2.72;
map["golden"] = 1.62;

// iterate over (key,value) pair
foreach (var elem in map.entries){
string name = elem.key;
double num = elem.value;

stdout.printf("%s,%f\n", name, num);
}

// iterate over keys
foreach (string key in map.keys){
stdout.printf("%s\n", key);
}

// iterate over values
foreach (double num in map.values){
stdout.printf("%f\n", num);
}
}
```

Compile with flag:

```--pkg gee-1.0
```
Output:
```e,2.720000
golden,1.620000
pi,3.140000
e
golden
pi
2.720000
1.620000
3.140000
```

## VBA

Dictionaries are similar in VBA and VBScript. Here is how to iterate.

```Option Explicit
Sub Test()
Dim h As Object, i As Long, u, v, s
Set h = CreateObject("Scripting.Dictionary")

'Iterate on keys
For Each s In h.Keys
Debug.Print s
Next

'Iterate on values
For Each s In h.Items
Debug.Print s
Next

'Iterate on both keys and values by creating two arrays
u = h.Keys
v = h.Items
For i = 0 To h.Count - 1
Debug.Print u(i), v(i)
Next
End Sub
```

## VBScript

```'instantiate the dictionary object
Set dict = CreateObject("Scripting.Dictionary")

'populate the dictionary or hash table

'iterate key and value pairs
For Each key In dict.Keys
WScript.StdOut.WriteLine key & " - " & dict.Item(key)
Next
```
Output:
```1 - larry
2 - curly
3 - moe
```

## Vim Script

```let dict = {"apples": 11, "oranges": 25, "pears": 4}

echo "Iterating over key-value pairs"
for [key, value] in items(dict)
echo key " => " value
endfor
echo "\n"

echo "Iterating over keys"
for key in keys(dict)
echo key
endfor
echo "\n"

echo "Iterating over values"
for value in values(dict)
echo value
endfor
```
Output:
```Iterating over key-value pairs
oranges  =>  25
pears  =>  4
apples  =>  11

Iterating over keys
oranges
pears
apples

Iterating over values
25
4
11```

## V (Vlang)

```fn main() {
my_map := {
"hello": 13,
"world": 31,
"!"    : 71 }

// iterating over key-value pairs:
for key, value in my_map {
println("key = \$key, value = \$value")
}

// iterating over keys:
for key,_ in my_map {
println("key = \$key")
}

// iterating over values:
for _, value in my_map {
println("value = \$value")
}
}```
Output:
```key = hello, value = 13
key = world, value = 31
key = !, value = 71
key = hello
key = world
key = !
value = 13
value = 31
value = 71
```

## Wart

```h <- (table 'a 1 'b 2)
each (key val) table
prn key " " val```
Output:
```a 1
b 2```

## Wren

Note that Wren makes no guarantee about iteration order which is not necessarily the same order in which the entries were added.

```// create a new map with four entries
var capitals = {
"France": "Paris",
"Germany": "Berlin",
"Russia": "Moscow",
}

// iterate through the map and print out the key/value pairs
for (c in capitals) System.print([c.key, c.value])
System.print()

// iterate though the map and print out just the keys
for (k in capitals.keys) System.print(k)
System.print()

// iterate though the map and print out just the values
for (v in capitals.values) System.print(v)
```
Output:
```[France, Paris]
[Russia, Moscow]
[Germany, Berlin]

France
Russia
Germany
Spain

Paris
Moscow
Berlin
```

## XPL0

```include c:\cxpl\stdlib;
char Dict(10,10);
int  Entries;

proc AddEntry(Letter, Greek);   \Insert entry into associative array
char Letter, Greek;
[Dict(Entries,0):= Letter;
StrCopy(Greek, @Dict(Entries,1));
Entries:= Entries+1;            \(limit checks ignored for simplicity)
];

int I;
[Entries:= 0;
for I:= 0 to Entries-1 do
[ChOut(0, Dict(I,0));  ChOut(0, ^ );  Text(0, @Dict(I,1));  CrLf(0)];
]```
Output:
```A alpha
D delta
B beta
C gamma
```

## zkl

```var d=Dictionary("A","alpha","D","delta", "B","beta", "C", "gamma");
d.keys.pump(Console.print,fcn(k){String(k,",")})
d.values.apply("toUpper").println();
```A,B,C,D,