Difference between revisions of "FP Laboratory 11"

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== Complex data structure ==
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== Complex data structure == <!--T:6-->
 
Consider following data structure representing some kind of GUI.
 
Consider following data structure representing some kind of GUI.
 
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<!--T:7-->
 
As an example, we can use following data structure.
 
As an example, we can use following data structure.
 
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gui :: Component
 
gui :: Component
 
gui =
 
gui =
   Container
+
   Container "My App"
    "My App"
+
     [ Container "Menu"
     [ Container
 
        "Menu"
 
 
         [ Button "btn_new" (Position (Point 0 0) 100 20) "New",
 
         [ Button "btn_new" (Position (Point 0 0) 100 20) "New",
 
           Button "btn_open" (Position (Point 100 0) 100 20) "Open",
 
           Button "btn_open" (Position (Point 100 0) 100 20) "Open",
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<!--T:8-->
 
* Add the data type <code>Component</code> into the type class <code>Show</code>.  
 
* Add the data type <code>Component</code> into the type class <code>Show</code>.  
  
 +
<!--T:9-->
 
The result for our data from previous example should be something like this.
 
The result for our data from previous example should be something like this.
 
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<!--T:10-->
 
* Cerate a function <code>insertInto</code>, it will insert an element into the existing container from a GUI. The functions parameters will be:  
 
* Cerate a function <code>insertInto</code>, it will insert an element into the existing container from a GUI. The functions parameters will be:  
 
** first parameter will be the GUI, where we are inserting the new element;
 
** first parameter will be the GUI, where we are inserting the new element;
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<!--T:22-->
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* Create a function <code>deleteFrom</code>, it will delete an element from the existing container from a GUI. The functions parameters will be:
 +
** first parameter will be the GUI, where we are deleting the element;
 +
** second parameter is the name of the component, that will be removed, you can safely assume, that it will always exist;
 +
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<syntaxhighlight lang="Haskell">
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deleteFrom :: Component -> String -> Component
 +
</syntaxhighlight>
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<syntaxhighlight lang="Haskell" class="myDark">
 +
ghci> deleteFrom gui "btn_close"           
 +
Container - My App
 +
  Container - Menu
 +
    (0,0)[100,20] Button[btn_new]: New
 +
    (100,0)[100,20] Button[btn_open]: Open
 +
  Container - Body
 +
    (0,20)[300,500] TextBox[textbox_1]: Some text goes here
 +
  Container - Footer
 +
</syntaxhighlight>
 +
 +
<div class="mw-collapsible mw-collapsed" data-collapsetext="Hide solution" data-expandtext="Show solution">
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<syntaxhighlight lang="Haskell">
 +
deleteFrom :: Component -> String -> Component
 +
deleteFrom (Container x child) target = Container x [deleteFrom c target |c<-child, name c /=target ]
 +
deleteFrom c _ = c
 +
</syntaxhighlight>
 +
</div>
 +
<div style="clear:both"></div>
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 +
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<!--T:11-->
 
* Extend the definition of a button in our GUI as follows.
 
* Extend the definition of a button in our GUI as follows.
 
Our '''onClick''' is a function, that will be fired when the button clicked on. The parameter of this function is data describing the firing event.
 
 
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...
 
...
 
</syntaxhighlight>
 
</syntaxhighlight>
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<!--T:12-->
 +
Our '''onClick''' is a function, that will be fired when the button is clicked on. The parameter of this function is data describing the firing event.
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<syntaxhighlight lang="Haskell">
 
<syntaxhighlight lang="Haskell">
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</syntaxhighlight>
 
</syntaxhighlight>
 
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<!--T:13-->
 
* Create a function <code>clickOnButton</code> that will take our GUI and an event. If it is a mouse event, and the position where we have clicked is inside some of the buttons from the gui, then it evaluates the coresponding <code>onClick</code> function and the result will be produced string. In all other cases, the result will be <code>Nothing</code>.
 
* Create a function <code>clickOnButton</code> that will take our GUI and an event. If it is a mouse event, and the position where we have clicked is inside some of the buttons from the gui, then it evaluates the coresponding <code>onClick</code> function and the result will be produced string. In all other cases, the result will be <code>Nothing</code>.
 
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Nothing
 
Nothing
 
</syntaxhighlight>
 
</syntaxhighlight>
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<div class="mw-collapsible mw-collapsed" data-collapsetext="Hide solution" data-expandtext="Show solution">
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<syntaxhighlight lang="Haskell">
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isInside :: Point -> Position -> Bool
 +
isInside (Point pCol pRow) (Position (Point cornerCol cornerRow) width height) =
 +
    cornerCol <= pCol && pCol <= cornerCol + width && cornerRow <= pRow && pRow <= cornerRow + height
 +
 +
getFirstOrNothing :: [Maybe a] -> Maybe a
 +
getFirstOrNothing [] = Nothing
 +
getFirstOrNothing (Nothing:xs) = getFirstOrNothing xs
 +
getFirstOrNothing (Just x: xs) = Just x
 +
 +
clickOnButton :: Component -> Event -> Maybe String
 +
clickOnButton (Button {position = pos, onClick = (Just func)}) (MouseEvent point) | isInside point pos = Just (func (MouseEvent point))
 +
clickOnButton (Container {children=inner}) event = getFirstOrNothing [clickOnButton c event |c<-inner]
 +
clickOnButton _ _ = Nothing
 +
</syntaxhighlight>
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</div>
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<div style="clear:both"></div>
  
 
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== Additional exercises ==
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== Additional exercises == <!--T:14-->
 
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<!--T:15-->
 
* Consider the following definition and the example of the m-ary tree.
 
* Consider the following definition and the example of the m-ary tree.
 
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<!--T:16-->
 
* Create a function that sums all values stored in the m-ary tree.
 
* Create a function that sums all values stored in the m-ary tree.
 
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<!--T:17-->
 
* Create a function that extracts all values from the m-ary tree into a list.
 
* Create a function that extracts all values from the m-ary tree into a list.
 
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<!--T:18-->
 
* Create a function that counts all leaves in the m-ary tree.
 
* Create a function that counts all leaves in the m-ary tree.
 
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<!--T:19-->
 
* Create a function that finds a maximum value stored in the m-ary tree.
 
* Create a function that finds a maximum value stored in the m-ary tree.
 
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<!--T:20-->
 
* Create a function that checks whether a given element is stored in the m-ary tree.  
 
* Create a function that checks whether a given element is stored in the m-ary tree.  
 
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<!--T:21-->
 
* Create a function that returns a number of elements greater than a given value.
 
* Create a function that returns a number of elements greater than a given value.
 
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Latest revision as of 11:30, 19 November 2024

Complex data structure

Consider following data structure representing some kind of GUI.

data Point = Point {column::Int,row::Int} deriving (Show)

data Position = Position {leftTopCorner :: Point, width :: Int, height :: Int} 

data Component
  = TextBox {name :: String, position :: Position, text :: String}
  | Button {name :: String, position :: Position, text :: String}
  | Container {name :: String, children :: [Component]}

As an example, we can use following data structure.

gui :: Component
gui =
  Container "My App"
    [ Container "Menu"
        [ Button "btn_new" (Position (Point 0 0) 100 20) "New",
          Button "btn_open" (Position (Point 100 0) 100 20) "Open",
          Button "btn_close" (Position (Point 200 0) 100 20) "Close"
        ],
      Container "Body" [TextBox "textbox_1" (Position (Point 0 20) 300 500) "Some text goes here"],
      Container "Footer" []
    ]
  • Add the data type Component into the type class Show.

The result for our data from previous example should be something like this.

ghci> gui
Container - My App
        Container - Menu
                (0,0)[100,20] Button[btn_new]: New
                (100,0)[100,20] Button[btn_open]: Open
                (200,0)[100,20] Button[btn_close]: Close
        Container - Body
                (0,20)[300,500] TextBox[textbox_1]: Some text goes here
        Container - Footer
instance Show Position where
    show (Position (Point col row) width height) = "(" ++ show col ++ "," ++ show row ++ ")["++ show width++","++ show height++"]"

instance Show Component where
    show :: Component -> String
    show gui = showIndent "" gui where
        showIndent ind (TextBox name position text) = ind ++ show position ++ " TextBox[" ++ name ++ "]: " ++ text ++"\n" 
        showIndent ind (Button name position text) = ind ++ show position ++ " Button[" ++ name ++ "]: " ++ text ++"\n"
        showIndent ind (Container name children) = let 
            inner = concat[showIndent (ind++"\t") c |c<-children]
            in ind ++ "Container - " ++ name ++ "\n" ++ inner
  • Cerate a function insertInto, it will insert an element into the existing container from a GUI. The functions parameters will be:
    • first parameter will be the GUI, where we are inserting the new element;
    • second parameter is the name of the container, where we insert the new element, you can safely assume, that it will always exist. The element will be placed as last in the container;
    • last parameter is the inserted element.
insertInto :: Component -> String -> Component -> Component
ghci> insertInto gui "Footer" (TextBox "Done" (Position (Point 0 500) 300 10) "We are done!")
Container - My App
        Container - Menu
                (0,0)[100,20] Button[btn_new]: New
                (100,0)[100,20] Button[btn_open]: Open
                (200,0)[100,20] Button[btn_close]: Close
        Container - Body
                (0,20)[300,500] TextBox[textbox_1]: Some text goes here
        Container - Footer
                (0,500)[300,10] TextBox[Done]: We are done!
insertInto :: Component -> String -> Component -> Component
insertInto (Container cName children ) toName element 
    | cName == toName = Container cName (children++[element]) 
    | otherwise = Container cName [insertInto c toName element  |c<-children]
insertInto x toName element = x
  • Create a function deleteFrom, it will delete an element from the existing container from a GUI. The functions parameters will be:
    • first parameter will be the GUI, where we are deleting the element;
    • second parameter is the name of the component, that will be removed, you can safely assume, that it will always exist;
deleteFrom :: Component -> String -> Component
ghci> deleteFrom gui "btn_close"            
Container - My App
  Container - Menu
    (0,0)[100,20] Button[btn_new]: New
    (100,0)[100,20] Button[btn_open]: Open
  Container - Body
    (0,20)[300,500] TextBox[textbox_1]: Some text goes here
  Container - Footer
deleteFrom :: Component -> String -> Component
deleteFrom (Container x child) target = Container x [deleteFrom c target |c<-child, name c /=target ]
deleteFrom c _ = c
  • Extend the definition of a button in our GUI as follows.
data Event = MouseEvent Point
           | KeyEvent {keyPressed::Char} deriving (Show)
...
  | Button {name :: String, position :: Position, text :: String, onClick :: Maybe (Event -> String)}
...

Our onClick is a function, that will be fired when the button is clicked on. The parameter of this function is data describing the firing event.

...
[ Button "btn_new" (Position (Point 0 0) 100 20) "New" (Just (\event -> "Clicked on new button.")),
  Button "btn_open" (Position (Point 100 0) 100 20) "Open" Nothing,
  Button "btn_close" (Position (Point 200 0) 100 20) "Close" (Just (\event -> "Clicked on close button.")) ]
...
  • Create a function clickOnButton that will take our GUI and an event. If it is a mouse event, and the position where we have clicked is inside some of the buttons from the gui, then it evaluates the coresponding onClick function and the result will be produced string. In all other cases, the result will be Nothing.
clickOnButton :: Component -> Event -> Maybe String
ghci> clickOnButton gui (MouseEvent (Point 5 5))
Just "Clicked on new button."
ghci> clickOnButton gui (MouseEvent (Point 205 5))
Just "Clicked on close button."
ghci> clickOnButton gui (MouseEvent (Point 205 50))
Nothing
isInside :: Point -> Position -> Bool
isInside (Point pCol pRow) (Position (Point cornerCol cornerRow) width height) =
     cornerCol <= pCol && pCol <= cornerCol + width && cornerRow <= pRow && pRow <= cornerRow + height

getFirstOrNothing :: [Maybe a] -> Maybe a
getFirstOrNothing [] = Nothing
getFirstOrNothing (Nothing:xs) = getFirstOrNothing xs
getFirstOrNothing (Just x: xs) = Just x

clickOnButton :: Component -> Event -> Maybe String
clickOnButton (Button {position = pos, onClick = (Just func)}) (MouseEvent point) | isInside point pos = Just (func (MouseEvent point))
clickOnButton (Container {children=inner}) event = getFirstOrNothing [clickOnButton c event |c<-inner]
clickOnButton _ _ = Nothing

Additional exercises

  • Consider the following definition and the example of the m-ary tree.
data MTree a = MTree a [MTree a]
testTree1 :: MTree Int            
testTree1 = MTree 1 [(MTree 2 [(MTree 3 []),(MTree 4 [(MTree 5 []),(MTree 6 [])]), (MTree 7 []),(MTree 8 [])]), (MTree 9 [])]
  • Create a function that sums all values stored in the m-ary tree.
msum :: MTree Int -> Int
  • Create a function that extracts all values from the m-ary tree into a list.
mToList :: MTree a -> [a]
  • Create a function that counts all leaves in the m-ary tree.
mLeafCount :: MTree a -> Int
  • Create a function that finds a maximum value stored in the m-ary tree.
mMaxTree :: Ord a => MTree a -> a
  • Create a function that checks whether a given element is stored in the m-ary tree.
mContains :: Eq a => MTree a -> a -> Bool
  • Create a function that returns a number of elements greater than a given value.
mGreaterThan :: Ord a => MTree a -> a -> Int