Create an object/Native demonstration
Create a Hash/Associative Array/Dictionary-like object that can be initialized with key/value pairs. The object should behave like a native Hash/Associative Array/Dictionary of the language, but with the following differences:
- No new keys can be added;
- Keys cannot be removed;
- Attempting to delete a key should set that keys value back to that used during initialisation.
(The value assigned to keys may be changed by normal assignment however).
If the language supports Magic Methods, then show how these work.
C++
<lang cpp>#include <iostream>
- include <map>
- include <utility>
using namespace std;
template<typename T> class FixedMap : private T {
// Two standard maps are used to implement FixedMap. One as a private // base class that will allow the values (but not the keys) to be modified. // Members of a private base class are not exposed to the derived class which will // prevent keys from being added or deleted. Another map will hold copies of // the initial values. T m_defaultValues;
public:
FixedMap(T map) : T(map), m_defaultValues(move(map)){} // Expose members of the base class that are not able to add or remove keys so // that FixedMap will behave like a standard container. using T::begin; using T::cbegin; using T::end; using T::cend; using T::at; using T::empty; using T::find; using T::size; // The [] operator will normally add a new key if the key is not already in the // map. Instead, throw an error if the key is missing. auto& operator[](typename T::key_type key) { auto iterator = this->find(key); if(iterator == this->end()) throw out_of_range("key not found"); return iterator->second; } // Reset the value of key to its initial value. Throws an error // if the key is missing. void reset(typename T::key_type key) { T::operator[](key) = m_defaultValues.at(key); }
};
// Print the contents of a map auto PrintMap = [](const auto &map) {
for(auto &[key, value] : map) { cout << "{" << key << " : " << value << "} "; } cout << "\n";
};
int main(void) {
// Create a fixed map based on the standard map FixedMap<map<const char *, int>> fixedMap ({ {"a", 1}, {"b", 2}}); PrintMap(fixedMap); // Change the values of the keys fixedMap["a"] = 55; fixedMap["b"] = 56; PrintMap(fixedMap); // Reset a key fixedMap.reset("a"); PrintMap(fixedMap); try { // Adding or retrieving a missing key is a run time error fixedMap["newKey"] = 99; } catch (exception &ex) { cout << "error: " << ex.what(); }
} </lang>
- Output:
{a : 1} {b : 2} {a : 55} {b : 56} {a : 1} {b : 56} error: key not found
D
<lang d>struct DefaultAA(TK, TV) {
TV[TK] standard, current;
this(TV[TK] default_) pure /*nothrow*/ @safe { this.standard = default_; this.current = default_.dup; }
alias current this;
void remove(in TK key) pure nothrow { current[key] = standard[key]; }
void clear() pure /*nothrow*/ @safe { current = standard.dup; }
}
void main() {
import std.stdio; auto d = ["a": 1, "b": 2].DefaultAA!(string, int);
d.writeln; // ["a":1, "b":2] d["a"] = 55; d["b"] = 66; d.writeln; // ["a":55, "b":66] d.clear; d.writeln; // ["a":1, "b":2] d["a"] = 55; d["b"] = 66; d["a"].writeln; // 55 d.remove("a"); d.writeln; // ["a":1, "b":66]
}</lang>
- Output:
["a":1, "b":2] ["a":55, "b":66] ["a":1, "b":2] 55 ["a":1, "b":66]
Go
Go's built-in map type is mutable and so, to complete this task, we need to create a read-only wrapper for it which doesn't permit further items to be added or existing items to be deleted though does allow them to be reset to their default value.
First create a sub-directory, romap, of the project directory and place the following package in it: <lang go>package romap
type Romap struct{ imap map[byte]int }
// Create new read-only wrapper for the given map. func New(m map[byte]int) *Romap {
if m == nil { return nil } return &Romap{m}
}
// Retrieve value for a given key, if it exists. func (rom *Romap) Get(key byte) (int, bool) {
i, ok := rom.imap[key] return i, ok
}
// Reset value for a given key, if it exists. func (rom *Romap) Reset(key byte) {
_, ok := rom.imap[key] if ok { rom.imap[key] = 0 // default value of int }
}</lang>
This package can now be imported and used within the main package as follows: <lang go>package main
import (
"./romap" "fmt"
)
func main() {
// create a normal map m := map[byte]int{'A': 65, 'B': 66, 'C': 67}
// place it in a read-only wrapper so no new item can be added or item deleted. rom := romap.New(m)
// retrieve value represented by 'C' say i, _ := rom.Get('C') fmt.Println("'C' maps to", i)
// reset this to default value (doesn't actually delete the key) rom.Reset('C') i, _ = rom.Get('C') fmt.Println("'C' now maps to", i)
}</lang>
- Output:
'C' maps to 67 'C' now maps to 0
J
Given a list of keys and an associated list of values, the idiomatic way of expressing this concept in J would be:
<lang j>lookup=: values {~ keys&i.</lang>
For example:
<lang j> lookup=: 10 20 30 40 50 {~ (;:'this is a test')&i.
lookup ;:'a test'
30 40</lang>
Notes:
1) While the result can not be modified or deleted, the name used to refer to it can be made to refer to something else, and once all references are lost it will be garbage collected.
2) In the above example, we have 5 values and 4 keys. The extra value is used when no key is found. If no extra value was provided, the "key not found" case would be an error case.
3) In J, objects are always referenced, but all data is passed by value. This means that objects can never be passed to a function -- only a reference to an object (its name) can be passed. This means that objects exist only in the way things are named, in J. So for the most part, we do not call things "objects" in J, and this task has nothing to do with what are called "objects" in J. However, this does demonstrate how things are created in J -- you write their definition, and can use them and/or assign to names or inspect them or whatever else.
Java
Java supports unmodifiable maps, sets, lists, and other more specialized unmodifiable collections. In this example, we have a unmodifiable map. We first create an ordinary map, modify as needed, then call the Collections.unmodifiableMap
. We can subsequently read the map, but modification is not permitted. The returned map will subsequently throw a UnsupportedOperationException
exception if a mutation operator is called. Several are demonstrated below.
<lang java> import java.util.Collections; import java.util.HashMap; import java.util.Map;
// Title: Create an object/Native demonstration
public class ImmutableMap {
public static void main(String[] args) { Map<String,Integer> hashMap = getImmutableMap(); try { hashMap.put("Test", 23); } catch (UnsupportedOperationException e) { System.out.println("ERROR: Unable to put new value."); } try { hashMap.clear(); } catch (UnsupportedOperationException e) { System.out.println("ERROR: Unable to clear map."); } try { hashMap.putIfAbsent("Test", 23); } catch (UnsupportedOperationException e) { System.out.println("ERROR: Unable to put if absent."); } for ( String key : hashMap.keySet() ) { System.out.printf("key = %s, value = %s%n", key, hashMap.get(key)); } } private static Map<String,Integer> getImmutableMap() { Map<String,Integer> hashMap = new HashMap<>(); hashMap.put("Key 1", 34); hashMap.put("Key 2", 105); hashMap.put("Key 3", 144);
return Collections.unmodifiableMap(hashMap); }
} </lang>
{out}}
ERROR: Unable to put new value. ERROR: Unable to clear map. ERROR: Unable to put if absent. key = Key 1, value = 34 key = Key 2, value = 105 key = Key 3, value = 144
JavaScript
This is a first demonstration of the task, but only implemented the functionality, not any native behavior, eg indexing. JavaScript experts may want to replace this one.
<lang javascript>var keyError = new Error("Invalid Key Error (FixedKeyDict)") ;
function FixedKeyDict(obj) {
var myDefault = new Object() ; var myData = new Object() ; for(k in obj) { myDefault[k] = obj[k] ; myData[k] = obj[k] ; }
var gotKey = function(k) { for(kk in myDefault) { if(kk == k) return true ; } return false ; } ;
this.hasKey = gotKey ;
var checkKey = function(k) { if(!gotKey(k)) throw keyError ; } ; this.getItem = function(k) { checkKey(k) ; return myData[k]; } ; this.setItem = function(k, v) { checkKey(k) ; myData[k] = v ; } ; this.resetItem = function(k) { checkKey(k) ; myData[k] = myDefault[k] ; } ; this.delItem = this.resetItem ; this.clear = function() { for(k in myDefault) myData[k] = myDefault[k] ; } ; this.iterator = function() { for(k in myDefault) yield (k); } ; this.clone = function() { return new FixedKeyDict(myDefault) ; } this.toStr = function() { var s = "" ; for(key in myData) s = s + key + " => " + myData[key] + ", " ; return "FixedKeyDict{" + s + "}" ; } ;
}</lang>
Test run:
<lang javascript>
const BR = "
\n"
var pl = function(s) {
document.write(s + BR) ;
} ;
pl("
") ; var o = { foo:101, bar:102 } ; var h = new FixedKeyDict(o) ; pl("Fixed Key Dict Created") ; pl("toString : " + h.toStr()) ; pl("get an item: " + h.getItem("foo")) ; pl("check a key: " + h.hasKey("boo")) ; pl("ditto : " + h.hasKey("bar")) ; h.setItem("bar", 999) ; pl("set an item: " + h.toStr()) ; pl("Test iterator (or whatever)") ; for(k in h.iterator()) pl(" " + k + " => " + h.getItem(k)) ; var g = h.clone() ; pl("Clone a dict") ; pl(" clone : " + g.toStr()) ; pl(" original : " + h.toStr()) ; h.clear() ; pl("clear or reset the dict") ; pl(" : " + h.toStr()) ; try { h.setItem("NoNewKey", 666 ) ; } catch(e) { pl("error test : " + e.message) ; } </lang> output : <pre> Fixed Key Dict Created toString : FixedKeyDict{foo => 101, bar => 102, } get an item: 101 check a key: false ditto : true set an item: FixedKeyDict{foo => 101, bar => 999, } Test iterator (or whatever) foo => 101 bar => 999 Clone a dict clone : FixedKeyDict{foo => 101, bar => 102, } original : FixedKeyDict{foo => 101, bar => 999, } clear or reset the dict : FixedKeyDict{foo => 101, bar => 102, } error test : Invalid Key Error (FixedKeyDict)
jq
jq objects are JSON objects and can be created using JSON syntax, e.g. <lang jq>{"language": "jq"}</lang> Objects can also be created programmatically, e.g. <lang jq>{"one": 1} + {"two": 2}</lang>
jq objects, however, are really just values: they are immutable, and cannot be "deleted" any more than the number 1 can be deleted.
Julia
<lang Julia> using BackedUpImmutable
function testBackedUpImmutableDict()
fibr = BackedUpImmutableDict{String,Int64}(["a" => 0, "b" => 1, "c" => 1, "d" => 2, "e" => 3, "f" => 5, "g" => 8, "h" => 13, "i" => 21, "j" => 34, "extra" => -1])
x = fibr["extra"] @test x == -1 fibr["extra"] = 0 y = fibr["extra"] @test y == 0 restore!(fibr, "extra") z = fibr["extra"] @test z == -1 @test_throws String begin fibr["k"] = 55 end fibr["a"] = 9 fibr["b"] = 7 # test restore all to default restoreall!(fibr) @test fibr["a"] == 0
end </lang> All tests pass.
Kotlin
<lang scala>// version 1.1.2
fun main(args: Array<String>) {
// This line creates a read-only map which cannot be changed in any way nor cleared val map = mapOf('A' to 65, 'B' to 66, 'C' to 67) println(map)
}</lang>
- Output:
{A=65, B=66, C=67}
M2000 Interpreter
<lang M2000 Interpreter> Module CheckIt {
Class LockedHash { Private: inventory Vars ' no same keys unlock module nosuchvariable { Error "No such value:"+letter$ } module NoNewItem { Error "No new item, use unlock method before" } module NoRemoveItem { Error "Can't remove item, use unlock method before" } Public: module Unlock { .unlock<=True } module Writeln { m=each(.Vars) while m { Print Quote$(Eval$(m, m^));",";Eval(m), } Print } Value (st$){ st$=Ucase$(st$) if exist(.Vars, st$) then =Eval(.Vars) : Exit .nosuchvariable st$ } Set (st$){ st$=Ucase$(st$) Read val if exist(.Vars, st$) then Return .Vars, st$:=val : Exit If .unlock then { Append .Vars, st$:=val} Else .NoNewItem } module Remove (st$) { if not .unlock then .NoRemoveItem st$=Ucase$(st$) Try { delete .Vars, st$ } } module Clear { Clear .Vars } Class: ' this part exist only at construction module LockedHash { While match("SN") { read st$, val st$=ucase$(st$) \\ if we append key which exist we get error Append .Vars, st$:=val } } } d=LockedHash("a", 1, "b", 2) d.writeln d("a")=55 : d("b")=66 d.writeln d.clear d.writeln d.unlock d("a")=55 : d("b")=66 Print d("a")=55, d("a")/d("b")<1 d.remove "a" d.writeln
} Checkit </lang>
Mathematica / Wolfram Language
<lang Mathematica>a[1] = "Do not modify after creation"; a[2] = "Native demonstration"; Protect[a];</lang> Example usage:
a[3] = 2 ->Set::write: Tag a in a[1] is Protected. >>
Nim
We leverage native stdlib table as our own object by implementing limited actual native table functionalities. <lang nim>import tables, options
type
MyTable = object table: TableRef[string, int]
- return empty if the key is not available
proc `[]`(m: MyTable, key: string): Option[int] =
if key in m.table: result = some m.table[key] else: result = none int
- update an item, doing nothing if the key is available during first initialization
proc `[]=`(m: var MyTable, key: string, val: int) =
if key notin m.table: return m.table[key] = val
proc reset(m: var MyTable) =
for _, v in m.table.mpairs: v = 0
- sugar for defining MyTable object
proc toTable(vals: openarray[(string, int)]): MyTable =
result.table = newTable vals
proc main =
# MyTable construction var myobj = {"key1": 1, "key2": 2, "key3": 3}.toTable # test getting existing key let val1 = myobj["key1"] if val1.isSome: echo "val1: ", val1.get
# test adding new key myobj["key4"] = 4 let val4 = myobj["key4"] if val4.isSome: echo val4.get else: echo "val4 is empty"
# test reset and test whether its value is zero-ed reset myobj doAssert myobj["key3"].get == 0
main() </lang>
- Output:
val1: 1 val4 is empty
Perl
<lang perl>package LockedHash; use parent Tie::Hash; use Carp; use strict;
sub TIEHASH { my $cls = shift; my %h = @_; bless \%h, ref $cls || $cls; }
sub STORE { my ($self, $k, $v) = @_; croak "Can't add key $k" unless exists $self->{$k}; $self->{$k} = $v; }
sub FETCH { my ($self, $k) = @_; croak "No key $k" unless exists $self->{$k}; $self->{$k}; }
sub DELETE { my ($self, $k) = @_; croak "No key $k" unless exists $self->{$k}; $self->{$k} = 0; }
sub CLEAR { } # ignored sub EXISTS { exists shift->{+shift} }
sub FIRSTKEY { my $self = shift; keys %$self; each %$self; }
sub NEXTKEY { my $self = shift; each %$self; }
sub lock_hash(\%) { my $ref = shift; tie(%$ref, __PACKAGE__, %$ref); }
1;
my %h = (a => 3, b => 4, c => 5);
- lock down %h
LockedHash::lock_hash(%h);
- show hash content and iteration
for (sort keys %h) { print "$_ => $h{$_}\n"; }
- try delete b
delete $h{b}; print "\nafter deleting b: b => $h{b}\n";
- change value of a
$h{a} = 100; print "\na => $h{a}\n";
- add a new key x: will die
eval { $h{x} = 1 }; if ($@) { print "Operation error: $@" }</lang>output:<lang>a => 3 b => 4 c => 5
after deleting b: b => 0
a => 100 operation error: Can't add key x at test.pl line 14
LockedHash::STORE('LockedHash=HASH(0x8cebe14)', 'x', 1) called at test.pl line 66 eval {...} called at test.pl line 66</lang>
Phix
There is no native "read-only" setting on phix dictionaries, so the following wraps a pair of them to provide the requested functionality. <lang Phix>enum STD, CUR sequence fkds = {} -- fixed key dictionaries ;-) integer freelist = 0
procedure fkd_destroy(integer id)
integer {std,cur} = fkds[id] destroy_dict(std) destroy_dict(cur) fkds[id] = freelist freelist = id
end procedure
function fkd_new(sequence key_pairs)
integer std = new_dict(key_pairs), cur = new_dict(std), id = freelist if id=0 then fkds = append(fkds,{std,cur}) id = length(fkds) else freelist = fkds[id] fkds[id] = {std,cur} end if return id
end function
procedure fkd_clear(integer id)
integer {std,cur} = fkds[id] destroy_dict(cur) fkds[id][CUR] = new_dict(std)
end procedure
function fkd_get(integer id, object key)
return getd(key,fkds[id][CUR])
end function
procedure fkd_set(integer id, object key, data)
integer node = getd_index(key,fkds[id][CUR]) if node=NULL then throw("invalid/new key") end if setd(key,data,fkds[id][CUR])
end procedure
procedure fkd_remove(integer id, object key)
integer {std,cur} = fkds[id], node = getd_index(key,std) if node=NULL then throw("invalid key") end if setd(key,getd_by_index(node,std),cur)
end procedure
function fkd_sprint(integer id)
integer cur = fkds[id][CUR] sequence res = getd_all_keys(cur) for i=1 to length(res) do object ri = res[i] res[i] = {ri,getd(ri,cur)} end for return res
end function
procedure main()
integer id = fkd_new({{"a",1},{"b",2}}) ?fkd_sprint(id) -- {{"a",1},{"b",2}} fkd_set(id,"a",55) fkd_set(id,"b",66) ?fkd_sprint(id) -- {{"a",55},{"b",66}} fkd_clear(id) ?fkd_sprint(id) -- {{"a",1},{"b",2}} fkd_set(id,"a",55) fkd_set(id,"b",66) ?fkd_get(id,"a") -- 55 fkd_remove(id,"a") try fkd_set(id,"NoNewKey",77) catch e ?e[E_USER] -- "invalid/new key" end try ?fkd_sprint(id) -- {{"a",1},{"b",66}} fkd_destroy(id)
end procedure main()</lang>
Python
<lang python> from collections import UserDict import copy
class Dict(UserDict):
>>> d = Dict(a=1, b=2) >>> d Dict({'a': 1, 'b': 2}) >>> d['a'] = 55; d['b'] = 66 >>> d Dict({'a': 55, 'b': 66}) >>> d.clear() >>> d Dict({'a': 1, 'b': 2}) >>> d['a'] = 55; d['b'] = 66 >>> d['a'] 55 >>> del d['a'] >>> d Dict({'a': 1, 'b': 66}) def __init__(self, dict=None, **kwargs): self.__init = True super().__init__(dict, **kwargs) self.default = copy.deepcopy(self.data) self.__init = False def __delitem__(self, key): if key in self.default: self.data[key] = self.default[key] else: raise NotImplementedError
def __setitem__(self, key, item): if self.__init: super().__setitem__(key, item) elif key in self.data: self.data[key] = item else: raise KeyError
def __repr__(self): return "%s(%s)" % (type(self).__name__, super().__repr__()) def fromkeys(cls, iterable, value=None): if self.__init: super().fromkeys(cls, iterable, value) else: for key in iterable: if key in self.data: self.data[key] = value else: raise KeyError
def clear(self): self.data.update(copy.deepcopy(self.default))
def pop(self, key, default=None): raise NotImplementedError
def popitem(self): raise NotImplementedError
def update(self, E, **F): if self.__init: super().update(E, **F) else: haskeys = False try: keys = E.keys() haskeys = Ture except AttributeError: pass if haskeys: for key in keys: self[key] = E[key] else: for key, val in E: self[key] = val for key in F: self[key] = F[key]
def setdefault(self, key, default=None): if key not in self.data: raise KeyError else: return super().setdefault(key, default)</lang>
Racket
This task is implemented as a new fenced-hash time with an interface similar to the native hash. Also it can be used a native dict.
Implementation of functions that handle fenced-hash: <lang Racket>
- (struct fenced-hash (actual original) ...)
(define (fenced-hash-ref dict
key [default (lambda () (error "key not found" key))]) (hash-ref (fenced-hash-actual dict) key default))
(define (fenced-hash-set! dict key val)
(unless (hash-has-key? (fenced-hash-actual dict) key) (error "unable to add key" key)) (hash-set! (fenced-hash-actual dict) key val))
(define (fenced-hash-remove! dict key) ;reset the value!
(unless (hash-has-key? (fenced-hash-actual dict) key) (error "key not found" key)) (hash-set! (fenced-hash-actual dict) key (hash-ref (fenced-hash-original dict) key)))
(define (fenced-hash-clear! dict) ;reset all values!
(hash-for-each (fenced-hash-original dict) (lambda (key val) (hash-set! (fenced-hash-actual dict) key val))))
(define (fenced-hash-has-key? dict key)
(hash-has-key? (fenced-hash-actual dict) key))
(define (fenced-hash-count dict)
(hash-count (fenced-hash-actual dict)))
(define (fenced-hash-iterate-first dict)
(hash-iterate-first (fenced-hash-actual dict)))
(define (fenced-hash-iterate-next dict pos)
(hash-iterate-next (fenced-hash-actual dict) pos))
(define (fenced-hash-iterate-key dict pos)
(hash-iterate-key (fenced-hash-actual dict) pos))
(define (fenced-hash-iterate-value dict pos)
(hash-iterate-value (fenced-hash-actual dict) pos))
(define (*fenced-hash-print dict port mode)
;private custom-write ;mode is ignored (write-string "#fenced-hash" port) (write (hash->list (fenced-hash-actual dict)) port))</lang>
Definition of the actual structure and a “public” creator: <lang Racket>(struct fenced-hash (actual original)
#:extra-constructor-name *fenced-hash ;private constructor #:omit-define-syntaxes ;not sure this is a good idea #:methods gen:custom-write [(define write-proc *fenced-hash-print)]
#:methods gen:dict [(define dict-ref fenced-hash-ref) (define dict-set! fenced-hash-set!) (define dict-remove! fenced-hash-remove!) (define dict-has-key? fenced-hash-has-key?) ;unused in 5.6.3 (define dict-count fenced-hash-count) (define dict-iterate-first fenced-hash-iterate-first) (define dict-iterate-next fenced-hash-iterate-next) (define dict-iterate-key fenced-hash-iterate-key) (define dict-iterate-value fenced-hash-iterate-value)])
(define (fenced-hash . args) ; public constructor
(define original (apply hash args)) (*fenced-hash (hash-copy original) original))</lang>
Example: Use the fenced-hash functions: <lang Racket>(define d (fenced-hash "a" 1 "b" 2))
(displayln d) (fenced-hash-set! d "a" 55) (fenced-hash-set! d "b" 66) (displayln d) (fenced-hash-clear! d) (displayln d) (fenced-hash-set! d "a" 55) (fenced-hash-set! d "b" 66) (displayln d) (fenced-hash-remove! d "a") (displayln d)</lang>
- Output:
#fenced-hash(("b" . 2) ("a" . 1)) #fenced-hash(("b" . 66) ("a" . 55)) #fenced-hash(("b" . 2) ("a" . 1)) #fenced-hash(("b" . 66) ("a" . 55)) #fenced-hash(("b" . 66) ("a" . 1))
Example (continued): Use the same object as a dict. The dict-clear! method is not defined, so we must call fenced-hash-clear! instead. <lang Racket>(fenced-hash-clear! d) (displayln d) (dict-set! d "a" 55) (dict-set! d "b" 66) (displayln d) (fenced-hash-clear! d) ;dict-clear is not defined (displayln d) (dict-set! d "a" 55) (dict-set! d "b" 66) (displayln d) (dict-remove! d "a") (displayln d)</lang>
- Output:
#fenced-hash(("b" . 2) ("a" . 1)) #fenced-hash(("b" . 66) ("a" . 55)) #fenced-hash(("b" . 2) ("a" . 1)) #fenced-hash(("b" . 66) ("a" . 55)) #fenced-hash(("b" . 66) ("a" . 1))
Raku
(formerly Perl 6)
Here we use delegation to handle all the normal hash methods that we don't need to override to define our new class. <lang perl6>class FixedHash {
has $.hash handles *; method new(*@args) { self.bless: hash => Hash.new: @args } method AT-KEY(FixedHash:D: $key is copy) is rw { $!hash.EXISTS-KEY($key) ?? $!hash.AT-KEY($key) !! Failure.new(q{can't store value for unknown key}); } method DELETE-KEY($key) { $!hash.{$key} = Nil }
}
- Testing
my $fh = FixedHash.new: "a" => 1, "b" => 2; say $fh<a b>; # 1 2 $fh:delete; say $fh<a b>; # 1 Nil $fh = 42; say $fh<a b>; # 1 42 say $fh<c>; # Nil $fh<c> = 43; # error </lang>
- Output:
(1 2) (1 (Any)) (1 42) can't store value for unknown key in block <unit> at native-demonstration.p6:17 Actually thrown at: in block <unit> at native-demonstration.p6:17
By defining FALLBACK any class can handle undefined method calls. Since any class inherits plenty of methods from Any our magic object will be more of a novice conjurer then a master wizard proper.
<lang perl6>class Magic {
has %.hash; multi method FALLBACK($name, |c) is rw { # this will eat any extra parameters %.hash{$name} }
multi method FALLBACK($name) is rw { %.hash{$name} }
}
my $magic = Magic.new; $magic.foo = 10; say $magic.foo; $magic.defined = False; # error</lang>
- Output:
10 Cannot modify an immutable Bool in block <unit> at native-demonstration.p6:15
Ring
<lang ring>
- Project : Create an object/Native demonstration
map = [] map["A"] = 65 map["B"] = 66 map["C"] = 67 see map + nl </lang> Output:
A 65 B 66 C 67
Ruby
<lang ruby># A FencedHash acts like a Hash, but with a fence around its keys.
- One may change its values, but not its keys. Any attempt to insert
- a new key raises KeyError. One may delete a key, but this only
- restores its original value.
- FencedHash reimplements these Hash methods: #[] #[]= #clear #delete
- #delete_if #default #default= #each_key #each_pair #each_value
- #fetch #has_key? #keep_if #keys #length #values #values_at
class FencedHash
# call-seq: # FencedHash.new(hash, obj=nil) -> fh # # Creates a FencedHash that takes its keys and original values from # a source _hash_. The source _hash_ can be any object that # responds to each_pair. Sets the default value for missing keys to # _obj_, so FencedHash#[] returns _obj_ when a key is not in fence. def initialize(hash, obj=nil) @default = obj @hash = {} hash.each_pair do |key, value| # @hash[key][0] = current value # @hash[key][1] = original value @hash[key] = [value, value] end end
def initialize_clone(orig) # Object#clone calls here in Ruby 2.0. If _orig_ was frozen, then # each array of _values_ is frozen, so make frozen clones. super copy = {} @hash.each_pair {|key, values| copy[key] = values.clone } @hash = copy end
def initialize_dup(orig) # Object#dup calls here in Ruby 2.0. If _orig_ was frozen, then # make duplicates that are not frozen. super copy = {} @hash.each_pair {|key, values| copy[key] = values.dup } @hash = copy end
# Retrieves current value for _key_, like Hash#[]. If _key_ is not # in fence, returns default object. def [](key) values = @hash[key] if values values[0] else @default end end
# call-seq: # fh[key] = value -> value # fh.store(key, value) -> value # # Sets _value_ for a _key_. Returns _value. If _key_ is not in # fence, raises KeyError. def []=(key, value) values = @hash[key] if values values[0] = value else raise KeyError, "fence prevents adding new key: #{key.inspect}" end end alias store []=
# Resets all keys to their original values. Returns self. def clear @hash.each_value {|values| values[0] = values[1]} self end
# Resets _key_ to its original value. Returns old value before # reset. If _key_ is not in fence, returns +nil+. def delete(key) values = @hash[key] if values old = values[0] values[0] = values[1] old # return old end # else return nil end
# call-seq: # fh.delete_if {|key, value| block } -> fh # fh.delete_if -> enumerator # # Yields each _key_ with current _value_ to _block_. Resets _key_ # to its original value when block evaluates to true. def delete_if if block_given? @hash.each_pair do |key, values| yield(key, values[0]) and values[0] = values[1] end self else enum_for(:delete_if) { @hash.size } end end
# The default value for keys not in fence. attr_accessor :default
# call-seq: # fh.each_key {|key| block} -> fh # fh.each_key -> enumerator # # Yields each key in fence to the block. def each_key(&block) if block @hash.each_key(&block) self else enum_for(:each_key) { @hash.size } end end
# call-seq: # fh.each_pair {|key, value| block} -> fh # fh.each_pair -> enumerator # # Yields each key-value pair to the block, like Hash#each_pair. # This yields each [key, value] as an array of 2 elements. def each_pair if block_given? @hash.each_pair {|key, values| yield [key, values[0]] } self else enum_for(:each_pair) { @hash.size } end end
# call-seq # fh.each_value {|value| block} -> fh # fh.each_value -> enumerator # # Yields current value of each key-value pair to the block. def each_value if block_given? @hash.each_value {|values| yield values[0] } else enum_for(:each_value) { @hash.size } end end
# call-seq: # fenhsh.fetch(key [,default]) # fenhsh.fetch(key) {|key| block } # # Fetches value for _key_. Takes same arguments as Hash#fetch. def fetch(*argv) argc = argv.length unless argc.between?(1, 2) raise(ArgumentError, "wrong number of arguments (#{argc} for 1..2)") end if argc == 2 and block_given? warn("#{caller[0]}: warning: " + "block supersedes default value argument") end
key, default = argv values = @hash[key] if values values[0] elsif block_given? yield key elsif argc == 2 default else raise KeyError, "key not found: #{key.inspect}" end end
# Freezes this FencedHash. def freeze @hash.each_value {|values| values.freeze } super end
# Returns true if _key_ is in fence. def has_key?(key) @hash.has_key?(key) end alias include? has_key? alias member? has_key?
# call-seq: # fh.keep_if {|key, value| block } -> fh # fh.keep_if -> enumerator # # Yields each _key_ with current _value_ to _block_. Resets _key_ # to its original value when block evaluates to false. def keep_if if block_given? @hash.each_pair do |key, values| yield(key, values[0]) or values[0] = values[1] end self else enum_for(:keep_if) { @hash.size } end end
# Returns array of keys in fence. def keys @hash.keys end
# Returns number of key-value pairs. def length @hash.length end alias size length
# Converts self to a regular Hash. def to_h result = Hash.new(@default) @hash.each_pair {|key, values| result[key] = values[0]} result end
# Converts self to a String. def to_s "#<#{self.class}: #{to_h}>" end alias inspect to_s
# Returns array of current values. def values @hash.each_value.map {|values| values[0]} end
# Returns array of current values for keys, like Hash#values_at. def values_at(*keys) keys.map {|key| self[key]} end
end</lang>
Scala
- Output:
Best seen running in your browser either by ScalaFiddle (ES aka JavaScript, non JVM) or Scastie (remote JVM).
<lang Scala>object CreateMapObject extends App {
val map = Map('A' -> 65, 'B' -> 66, 'C' -> 67)
println(map)
}</lang>
Tcl
This solution uses a dict(ionary), so requires Tcl 8.5 or better. Variable traces are used to detect write or unset access to such a protected variable, restore it to the backup value at protection time, and throw an exception
<lang Tcl>proc protect _var {
upvar 1 $_var var trace add variable var {write unset} [list protect0 $var]
} proc protect0 {backup name1 name2 op} {
upvar 1 $name1 var trace remove variable var {write unset} [list protect 0 $backup] set var $backup trace add variable var {write unset} [list protect0 $backup] return -code error "$name1 is protected"
} proc trying cmd { #-- convenience function for demo
puts "trying: $cmd" if [catch {uplevel 1 $cmd} msg] {puts $msg}
}</lang> Testing:
dict set dic 1 one dict set dic 2 two puts dic:$dic protect dic trying "dict set dic 3 three" puts dic:$dic trying "dict unset dic 1" trying "unset dic" puts dic:$dic
displays on stdout:
dic:1 one 2 two trying: dict set dic 3 three can't set "dic": dic is protected dic:1 one 2 two trying: dict unset dic 1 can't set "dic": dic is protected trying: unset dic dic:1 one 2 two
Wren
<lang ecmascript>class FixedSizeMap {
construct new(map) { // copy the map so it cannot be mutated from the original reference _map = {} for (me in map.toList) _map[me.key] = me.value }
containsKey(key) { _map[key] != null }
count { _map.count }
keys { _map.keys }
values { _map.values }
[key] { _map[key] } [key] =(value) { // do nothing if key doesn't already exist if (_map[key] != null) _map[key] = value }
reset(key) { var t = _map[key].type // leave unaltered if no suitable default value _map[key] = (t == Num) ? 0 : (t == String) ? "": (t == Bool) ? false : (t == List) ? [] : (t == Map) ? {} : _map[key] }
iterate(iterator) { _map.iterate(iterator) } iteratorValue(iterator) { _map.iteratorValue(iterator) }
toString { _map.toString }
}
var map = { "a": 1, "b": 2 } var fsm = FixedSizeMap.new(map) System.print(fsm) System.print(fsm.count) fsm["a"] = 3 fsm["b"] = 4 System.print(fsm) System.print(fsm.containsKey("c")) fsm["c"] = 5 // attempt to add a new key/value pair System.print(fsm) // ignored fsm.reset("a") System.print(fsm) System.print(fsm.keys.toList) System.print(fsm.values.toList) for (me in fsm) System.print([me.key, me.value]) </lang>
- Output:
{b: 2, a: 1} 2 {b: 4, a: 3} false {b: 4, a: 3} {b: 4, a: 0} [b, a] [4, 0] [b, 4] [a, 0]
zkl
zkl has two dictionary objects: SD, a small dictionary that is created immutable and the "regular" dictionary has has a makeReadOnly method. They both behave the same when locked down. <lang zkl">d:=SD("one",1,"two",2); d.keys; //-->L("one","two") d["one"]; //-->1 d.add("three",3); // error thrown d.pop("one") // error thrown</lang>