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mirror of synced 2024-12-22 17:23:07 +01:00

Added: Binary Tree implementation (serves as the basis for an upcoming hashes unit)

This commit is contained in:
Mark van Renswoude 2004-07-22 19:31:08 +00:00
parent 451903597f
commit 0e708e29d5

532
X2UtBinaryTree.pas Normal file
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{
:: X2UtBinaryTree contains an implementation of the binary tree algorithm,
:: along with various descendants which implement support for a range of value
:: types other than the default pointers (such as integers or strings). This
:: effectively makes it an associative array based on an integer key.
:: For a hash implementation based on string keys use the X2UtHashes unit.
::
:: P.S. I realise that a "B-Tree" is different from a binary tree. For
:: convenience reasons I will however ignore your ranting and call my
:: classes "TX2UtBTree". ;)
::
:: Last changed: $Date$
:: Revision: $Rev$
:: Author: $Author$
}
unit X2UtBinaryTree;
interface
uses
SysUtils;
type
//:$ Raised when the cursor is invalid.
//:: Call Reset on the binary tree to create a valid cursor.
EX2UtBTreeInvalidCursor = class(Exception);
{
:$ Internal representation of a node.
}
PX2UtBTreeNode = ^TX2UtBTreeNode;
TX2UtBTreeNode = record
Index: Cardinal;
Value: Pointer;
Parent: PX2UtBTreeNode;
Left: PX2UtBTreeNode;
Right: PX2UtBTreeNode;
end;
{
:$ Internal parent stack
}
TX2UtBTreeStack = class(TObject)
private
FItems: array of PX2UtBTreeNode;
FCount: Integer;
FPosition: Integer;
public
constructor Create();
procedure Clear();
procedure Push(const ANode: PX2UtBTreeNode);
function Pop(): PX2UtBTreeNode;
end;
{
:$ Binary tree implementation
:: This class implements a binary tree of pointer values.
}
TX2UtBTree = class(TObject)
private
FRoot: PX2UtBTreeNode;
FCursor: PX2UtBTreeNode;
FIsReset: Boolean;
FParent: TX2UtBTreeStack;
function GetItem(Index: Cardinal): Pointer;
procedure SetItem(Index: Cardinal; const Value: Pointer);
function GetCurrentIndex(): Cardinal;
function GetCurrentValue(): Pointer;
protected
function LookupNode(const AIndex: Cardinal;
const ACreate: Boolean = True): PX2UtBTreeNode; virtual;
procedure NewNode(const AParent: PX2UtBTreeNode;
var ANode: PX2UtBTreeNode;
const AAutoInit: Boolean = True); virtual;
procedure InitNode(var ANode: PX2UtBTreeNode); virtual;
procedure DeleteNode(var ANode: PX2UtBTreeNode); virtual;
procedure ClearCursor(); virtual;
property Cursor: PX2UtBTreeNode read FCursor write FCursor;
property Root: PX2UtBTreeNode read FRoot;
property IsReset: Boolean read FIsReset write FIsReset;
property Parent: TX2UtBTreeStack read FParent;
public
constructor Create();
destructor Destroy(); override;
//:$ Clears the tree
procedure Clear();
//:$ Deletes a node from the tree
procedure Delete(const AIndex: Cardinal);
//:$ Resets the node cursor
//:: The node cursor can be used to traverse through the binary tree.
//:: Call Reset first, followed by Next to get the first item. You can
//:: continue to call Next until it returns false. The CurrentIndex and
//:: CurrentValue properties will only be valid within the traversal.
//:! Adding or removing items will result in a loss of the current cursor
//:! until the next Reset call.
procedure Reset();
//:$ Moves the node cursor to the next node
//:! The order in which nodes are traversed is from top to bottom, left
//:! to right. Do not depend on the binary tree to sort the output.
function Next(): Boolean;
//:$ Gets or sets an item.
property Items[Index: Cardinal]: Pointer read GetItem
write SetItem; default;
//:$ Returns the index at the current cursor location
property CurrentIndex: Cardinal read GetCurrentIndex;
//:$ Returns the value at the current cursor location
property CurrentValue: Pointer read GetCurrentValue;
end;
{
:$ Binary tree implementation for integer values
}
TX2UtIntegerBTree = class(TX2UtBTree)
private
function GetItem(Index: Cardinal): Integer;
procedure SetItem(Index: Cardinal; const Value: Integer);
function GetCurrentValue(): Integer;
public
//:$ Gets or sets an item.
property Items[Index: Cardinal]: Integer read GetItem
write SetItem; default;
//:$ Returns the value at the current cursor location
property CurrentValue: Integer read GetCurrentValue;
end;
{
:$ Binary tree implementation for string values
}
TX2UtStringBTree = class(TX2UtBTree)
private
function GetItem(Index: Cardinal): String;
procedure SetItem(Index: Cardinal; const Value: String);
function GetCurrentValue(): String;
protected
procedure InitNode(var ANode: PX2UtBTreeNode); override;
procedure DeleteNode(var ANode: PX2UtBTreeNode); override;
public
//:$ Gets or sets an item.
property Items[Index: Cardinal]: String read GetItem
write SetItem; default;
//:$ Returns the value at the current cursor location
property CurrentValue: String read GetCurrentValue;
end;
implementation
resourcestring
RSOrphanNode = 'Node does not seem to belong to it''s parent!';
RSInvalidCursor = 'Cursor is invalid!';
RSTooManyPops = 'More Pops than Pushes!';
const
CStackSize = 32;
type
PStringRecord = ^TStringRecord;
TStringRecord = record
Value: String;
end;
{======================== TX2UtBTreeStack
Item Management
========================================}
constructor TX2UtBTreeStack.Create;
begin
inherited;
FCount := CStackSize;
FPosition := -1;
SetLength(FItems, FCount);
end;
procedure TX2UtBTreeStack.Clear;
begin
FCount := CStackSize;
FPosition := -1;
SetLength(FItems, FCount);
end;
procedure TX2UtBTreeStack.Push;
begin
Inc(FPosition);
if FPosition >= FCount then
begin
Inc(FCount, FCount);
SetLength(FItems, FCount);
end;
FItems[FPosition] := ANode;
end;
function TX2UtBTreeStack.Pop;
begin
Result := nil;
if FPosition > -1 then
begin
Result := FItems[FPosition];
Dec(FPosition);
end;
end;
{============================= TX2UtBTree
Initialization
========================================}
constructor TX2UtBTree.Create;
begin
inherited;
NewNode(nil, FRoot, False);
FParent := TX2UtBTreeStack.Create();
end;
destructor TX2UtBTree.Destroy;
begin
FreeAndNil(FParent);
DeleteNode(FRoot);
inherited;
end;
{============================= TX2UtBTree
Tree Management
========================================}
function TX2UtBTree.LookupNode;
var
pNode: PX2UtBTreeNode;
begin
Result := nil;
pNode := Root;
if not Assigned(pNode^.Value) then
begin
InitNode(pNode);
pNode^.Index := AIndex;
Result := pRoot;
exit;
end;
while Assigned(pNode) do
begin
if AIndex = pNode^.Index then
begin
Result := pNode;
break;
end else if AIndex < pNode^.Index then
begin
if Assigned(pNode^.Left) then
pNode := pNode^.Left
else
begin
if ACreate then
begin
NewNode(pNode, pNode^.Left);
Result := pNode^.Left;
Result^.Index := AIndex;
end;
break;
end;
end else
begin
if Assigned(pNode^.Right) then
pNode := pNode^.Right
else
begin
if ACreate then
begin
NewNode(pNode, pNode^.Right);
Result := pNode^.Right;
Result^.Index := AIndex;
end;
break;
end;
end;
end;
end;
procedure TX2UtBTree.NewNode;
begin
New(ANode);
FillChar(ANode^, SizeOf(TX2UtBTreeNode), #0);
ANode^.Parent := AParent;
ClearCursor();
if AAutoInit then
InitNode(ANode);
end;
procedure TX2UtBTree.InitNode;
begin
// Reserved for descendants
end;
procedure TX2UtBTree.DeleteNode;
begin
if Assigned(ANode^.Left) then
DeleteNode(ANode^.Left);
if Assigned(ANode^.Right) then
DeleteNode(ANode^.Right);
if Assigned(ANode^.Parent) then
if ANode^.Parent^.Left = ANode then
ANode^.Parent^.Left := nil
else if ANode^.Parent^.Right = ANode then
ANode^.Parent^.Right := nil
else
Assert(False, RSOrphanNode);
Dispose(ANode);
ClearCursor();
end;
procedure TX2UtBTree.Clear;
begin
DeleteNode(FRoot);
NewNode(nil, FRoot, False);
end;
procedure TX2UtBTree.Delete;
var
pItem: PX2UtBTreeNode;
begin
pItem := LookupNode(AIndex, False);
if Assigned(pItem) then
DeleteNode(pItem);
end;
{============================= TX2UtBTree
Tree Traversing
========================================}
procedure TX2UtBTree.ClearCursor;
begin
Cursor := nil;
end;
procedure TX2UtBTree.Reset;
begin
Cursor := Root;
IsReset := True;
end;
function TX2UtBTree.Next;
var
pParent: PX2UtBTreeNode;
pCurrent: PX2UtBTreeNode;
begin
if not Assigned(Cursor) then
raise EX2UtBTreeInvalidCursor.Create(RSInvalidCursor);
Result := False;
if not IsReset then
begin
if Assigned(Cursor^.Left) then
begin
// Valid left path, follow it
Parent.Push(Cursor);
Cursor := Cursor^.Left;
Result := True;
end else if Assigned(Cursor^.Right) then
begin
// Valid right path, follow it
Parent.Push(Cursor);
Cursor := Cursor^.Right;
Result := True;
end else
begin
// Neither is valid, traverse back up the parent stack until
// a node if found with a sibling
pCurrent := Cursor;
pParent := Parent.Pop();
ClearCursor();
while Assigned(pParent) do
begin
if Assigned(pParent^.Right) and (pParent^.Right <> pCurrent) then
begin
// Parent has a sibling, follow it
Parent.Push(pParent);
Cursor := pParent^.Right;
Result := True;
break;
end;
pCurrent := pParent;
pParent := Parent.Pop();
end;
end;
end else
begin
IsReset := False;
Result := True;
end;
end;
function TX2UtBTree.GetCurrentIndex;
begin
if Assigned(Cursor) and (not IsReset) then
Result := Cursor^.Index
else
raise EX2UtBTreeInvalidCursor.Create(RSInvalidCursor);
end;
function TX2UtBTree.GetCurrentValue;
begin
if Assigned(Cursor) and (not IsReset) then
Result := Cursor^.Value
else
raise EX2UtBTreeInvalidCursor.Create(RSInvalidCursor);
end;
{============================= TX2UtBTree
Items
========================================}
function TX2UtBTree.GetItem;
var
pItem: PX2UtBTreeNode;
begin
Result := nil;
pItem := LookupNode(Index, False);
if Assigned(pItem) then
Result := pItem^.Value;
end;
procedure TX2UtBTree.SetItem;
var
pItem: PX2UtBTreeNode;
begin
pItem := LookupNode(Index);
if Assigned(pItem) then
pItem^.Value := Value;
end;
{====================== TX2UtIntegerBTree
Item Management
========================================}
function TX2UtIntegerBTree.GetItem;
begin
Result := Integer(inherited GetItem(Index));
end;
procedure TX2UtIntegerBTree.SetItem;
begin
inherited SetItem(Index, Pointer(Value));
end;
function TX2UtIntegerBTree.GetCurrentValue;
begin
Result := Integer(inherited GetCurrentValue());
end;
{======================= TX2UtStringBTree
Item Management
========================================}
function TX2UtStringBTree.GetItem;
var
pItem: PX2UtBTreeNode;
begin
Result := '';
pItem := LookupNode(Index, False);
if Assigned(pItem) then
Result := PStringRecord(pItem^.Value)^.Value;
end;
procedure TX2UtStringBTree.SetItem;
var
pItem: PX2UtBTreeNode;
begin
pItem := LookupNode(Index);
if Assigned(pItem) then
PStringRecord(pItem^.Value)^.Value := Value;
end;
function TX2UtStringBTree.GetCurrentValue;
var
pValue: PStringRecord;
begin
Result := '';
pValue := inherited GetCurrentValue();
if Assigned(pValue) then
Result := pValue^.Value;
end;
procedure TX2UtStringBTree.DeleteNode;
begin
Dispose(PStringRecord(ANode^.Value));
inherited;
end;
procedure TX2UtStringBTree.InitNode;
begin
inherited;
New(PStringRecord(ANode^.Value));
end;
end.