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libcw/cwB23Tree.h

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#ifndef cwB23Tree_h
#define cwB23Tree_h
namespace cw
{
namespace b23
{
/*
This is a binary tree implemented as a (2-3 tree)
See: docs/2-3-trees.pdf
or https://cs.wellesley.edu/~cs231/handouts/2-3-trees.pdf
*/
template< typename K, typename V, K null_key >
struct tree_str
{
typedef enum {
kInvalidNodeTId,
k1LeafTId, // leaf where kv0 is in use but kv1 is not
k2LeafTId, // leaf where kv0 and kv1 are in use
k2NodeTId, // node with a lo,hi branch but no middle branch
k3NodeTId // node with a lo,hi, and middle branch
} node_tid_t;
typedef struct value_str
{
V value;
struct value_str* link;
} value_t;
typedef struct key_value_str
{
K key; // Key for this k/v pair
value_t* valueL; // Linked list of values which share the same key.
bool is_empty() const { return key==null_key; }
bool is_not_empty() const { return !is_empty(); }
void set_empty() { key=null_key; valueL=nullptr; }
} key_value_t;
struct node_str;
typedef struct match_result_str
{
struct node_str* node;
key_value_t* kv;
unsigned kv_idx; // 0 or 1
} match_result_t;
typedef struct node_str
{
unsigned nid;
struct node_str* parent;
struct node_str* l_link; // low link
struct node_str* m_link; // middle link
struct node_str* h_link; // high link
// If kv1 is not empty then kv1.key is > kv0.key
key_value_t kv0; // kv0 always contains a valid key-value pair
key_value_t kv1; // kv1 is only valid if this is a 3 node
unsigned key_value_count() const { return kv1.is_empty() ? 1 : 2; }
const K& min_key() const { return kv0.key; }
const K& max_key() const { return kv1.is_empty() ? kv0.key : kv1.key; }
// Leaf nodes have no child pointers, but may have one or two key-value pairs.
bool is_leaf() const { return this->l_link == nullptr; }
bool is_not_leaf() const { return !is_leaf(); }
bool is_1_leaf() const { return is_leaf() && kv1.is_empty(); }
bool is_2_leaf() const { return is_leaf() && kv1.is_not_empty(); }
// 2 nodes have one key-value pair and valid l_link and h_link;
bool is_2_node() const { return !this->is_leaf() && this->m_link == nullptr; }
// 3 nodes have two key-value pairs and valid l,m,h links
bool is_3_node() const { return !this->is_leaf() && this->m_link != nullptr; }
node_tid_t type_id() const { return is_leaf() ? (is_1_leaf() ? k1LeafTId : k2LeafTId) : (is_2_node() ? k2NodeTId : k3NodeTId); }
bool is_valid()
{
// if l_link is null then h_link and m_link are also null. if l_link is not null then neither is h_link.
bool fl0 = l_link==nullptr ? (h_link==nullptr && m_link==nullptr) : h_link!=nullptr;
// kv0 is never empty
bool fl1 = kv0.is_not_empty() && kv0.valueL != nullptr;
// m_link is null if kv1 is empty
bool fl2 = kv1.is_empty() ? m_link==nullptr : m_link!=nullptr;
return fl0 && fl1 && fl2;
}
unsigned height() const
{
if( is_leaf() )
return 0;
return l_link->height() + 1;
}
match_result_t is_key_in_node( K key )
{
match_result_t r;
if( kv0.key == key )
{
r.node = this;
r.kv = &kv0;
r.kv_idx = 0;
}
else
{
if( kv1.is_not_empty() and kv1.key == key )
{
r.node = this;
r.kv = &kv1;
r.kv_idx = 1;
}
else
{
r.node = nullptr;
r.kv = nullptr;
r.kv_idx = 2;
}
}
return r;
}
// Return the next node to this node given the key.
// Return nullptr if this is a leaf node.
struct node_str* next( K key )
{
node_t* n = nullptr;
assert( is_key_in_node(key) == false );
if( key < kv0.key )
{
n = l_link;
}
else
{
if( key > (kv1.is_not_empty() ? kv1.key : kv0.key) )
n = h_link;
else
n = m_link;
}
return n;
}
} node_t;
typedef struct node_block_str
{
struct node_block_str* link;
node_t* nodeA;
unsigned nodeN;
unsigned next_avail_node_idx; // index next empty slot
} node_block_t;
typedef struct value_block_str
{
struct value_block_str* link;
value_t* valueA;
unsigned valueN;
unsigned next_avail_value_idx; // index of next empty slot
} value_block_t;
node_t* _root = nullptr;
node_block_t* _beg_node_block = nullptr; // First node in node block linked list
node_block_t* _end_node_block = nullptr; // Last block in node block linked list (always partially empty)
value_block_t* _beg_value_block = nullptr; // First node in value block linked list
value_block_t* _end_value_block = nullptr; // Last block in value block linked list (always partially empty)
node_t* _free_node_list = nullptr; // Linked list, through 'parent' of avail nodes.
value_t* _free_value_list = nullptr; //
unsigned _nodes_per_block = 0;
unsigned _values_per_block = 0;
unsigned _nid = 0;
const char* node_tid_to_label( node_tid_t tid )
{
switch(tid)
{
case kInvalidNodeTId: return "<inv>";
case k1LeafTId: return "1L";
case k2LeafTId: return "2L";
case k2NodeTId: return "2N";
case k3NodeTId: return "3N";
}
return "<unk>";
}
// Return the node and kv that matches the key.
match_result_t key_to_node( K key )
{
match_result_t r;
node_t* n = _root;
while(n != nullptr)
{
r = n->is_key_in_node(key);
if( r.node != nullptr )
break;
n = n->next(key);
}
return r;
}
node_block_t* _alloc_node_block( unsigned nodes_per_block )
{
node_block_t* b = mem::allocZ<node_block_t>();
b->nodeA = mem::allocZ<node_t>( nodes_per_block );
b->nodeN = nodes_per_block;
if( _beg_node_block == nullptr )
_beg_node_block = b;
else
_end_node_block->link = b;
_end_node_block = b;
return b;
}
value_block_t* _alloc_value_block( unsigned values_per_block )
{
value_block_t* b = mem::allocZ<value_block_t>();
b->valueA = mem::allocZ<value_t>( values_per_block );
b->valueN = values_per_block;
if( _beg_value_block == nullptr )
_beg_value_block = b;
else
_end_value_block->link = b;
_end_value_block = b;
return b;
}
void _alloc_value( key_value_t& kv, V new_value )
{
value_t* v = nullptr;
if( _free_value_list != nullptr )
{
v = _free_value_list;
_free_value_list = v->link;
v->link = nullptr;
}
else
{
if( _end_value_block==nullptr || _end_value_block->next_avail_value_idx >= _end_value_block->valueN )
_alloc_value_block(_values_per_block);
assert( _end_value_block!= nullptr && _end_value_block->next_avail_value_idx < _end_value_block->valueN );
v = _end_value_block->valueA + _end_value_block->next_avail_value_idx++;
}
v->value = new_value;
v->link = kv.valueL;
kv.valueL = v;
}
// Initialize a kv with a new key, value pair
void _init_key_value( key_value_t& kv, K key, V value )
{
kv.key = key;
_alloc_value(kv,value);
}
// Initialize a kv from an existing kv pair
void _move_key_value( key_value_t& lhs_kv, key_value_t& rhs_kv )
{
lhs_kv = rhs_kv;
rhs_kv.set_empty();
}
node_t* _alloc_node( node_t* parent )
{
node_t* n = nullptr;
if( _free_node_list != nullptr )
{
n = _free_node_list;
memset(n,0,sizeof(*n));
_free_node_list = _free_node_list->parent;
}
else
{
// if the current node block has no available nodes then create a new node block
if( _end_node_block==nullptr || _end_node_block->next_avail_node_idx >= _end_node_block->nodeN )
_alloc_node_block(_nodes_per_block);
// a node block with available nodes must now exist
assert( _end_node_block!= nullptr && _end_node_block->next_avail_node_idx < _end_node_block->nodeN );
// get the next available node
n = _end_node_block->nodeA + _end_node_block->next_avail_node_idx++;
}
n->nid = _nid++;
n->parent = parent;
n->kv0.key = null_key;
n->kv1.key = null_key;
return n;
}
// allocate a new node with a new key / value pair
node_t* _alloc_node( node_t* parent, K new_key, V new_value )
{
node_t* n = _alloc_node(parent);
// all new nodes have a valid k/v pair in kv0
_init_key_value( n->kv0, new_key, new_value );
return n;
}
// allocate a new node with an existing k/v apir.
node_t* _alloc_node( node_t* parent, key_value_t& kv )
{
node_t* n = _alloc_node(parent);
_move_key_value( n->kv0, kv );
return n;
}
void _free_key_value( key_value_t& kv )
{
// Free values by placing the values on the _free_value_list;
value_t* v = kv.valueL;
while( v != nullptr )
{
value_t* v0 = v->link;
// TODO: figure out how to call release on v->value
// if release<T>(v->value) exists
// release<T>(v->value);
v->link = _free_value_list;
_free_value_list = v;
v = v0;
}
kv.set_empty();
}
void _free_node( node_t* node )
{
_free_key_value(node->kv0);
_free_key_value(node->kv1);
// track free nodes by forming a list using the 'parent' pointer
node->parent = _free_node_list;
_free_node_list = node;
}
rc_t create( unsigned nodes_per_block )
{
rc_t rc = kOkRC;
_nodes_per_block = nodes_per_block;
_values_per_block= nodes_per_block;
_alloc_node_block(nodes_per_block);
_alloc_value_block(nodes_per_block);
return rc;
}
void destroy()
{
value_block_t* vb = _beg_value_block;
while( vb!=nullptr )
{
value_block_t* vb0 = vb->link;
mem::release(vb->valueA);
mem::release(vb);
vb=vb0;
}
node_block_t* nb = _beg_node_block;
while( nb !=nullptr )
{
node_block_t* nb0 = nb->link;
mem::release(nb->nodeA);
mem::release(nb);
nb=nb0;
}
}
void _insert_into_1_leaf(node_t* n, K key, V value )
{
if( key > n->kv0.key )
_init_key_value(n->kv1,key,value);
else
{
_move_key_value(n->kv1,n->kv0);
_init_key_value(n->kv0,key,value);
}
}
node_t* _2_leaf_to_2_node_sub_tree( node_t* n, K key, V value )
{
assert( n->is_2_leaf() );
if( key < n->kv0.key )
{
n->l_link = _alloc_node(n,key,value);
n->h_link = _alloc_node(n,n->kv1);
}
else
{
if( key > n->kv1.key )
{
n->l_link = _alloc_node(n,n->kv0);
n->h_link = _alloc_node(n,key,value);
_move_key_value(n->kv0,n->kv1);
}
else
{
n->l_link = _alloc_node(n,n->kv0);
n->h_link = _alloc_node(n,n->kv1);
_init_key_value(n->kv0,key,value);
}
}
assert(n->is_2_node());
return n;
}
void _link_to_parent_l( node_t* parent, node_t* child )
{
parent->l_link = child;
child->parent = parent;
}
void _link_to_parent_m( node_t* parent, node_t* child )
{
parent->m_link = child;
child->parent = parent;
}
void _link_to_parent_h( node_t* parent, node_t* child )
{
parent->h_link = child;
child->parent = parent;
}
// convert 'n', a 2-node, into a 3-node by absorbing it's 2-node child
void _2_node_to_3_node( node_t* n, node_t* child )
{
assert( n->is_2_node() );
// if child is the l subtree
if( child == n->l_link )
{
_move_key_value(n->kv1,n->kv0);
_move_key_value(n->kv0,child->kv0);
_link_to_parent_l(n,child->l_link);
_link_to_parent_m(n,child->h_link);
}
else // child must be the h subtree
{
assert( child == n->h_link );
_move_key_value(n->kv1,child->kv0);
_link_to_parent_m(n,child->l_link);
_link_to_parent_h(n,child->h_link);
}
_free_node(child);
assert( n->is_3_node() );
}
node_t* _2node_from_parts( node_t* parent, key_value_t& kv, node_t* l_subtree, node_t* h_subtree )
{
node_t* h_node = _alloc_node(parent,kv);
_link_to_parent_l(h_node,l_subtree);
_link_to_parent_h(h_node,h_subtree);
return h_node;
}
// Convert a 3-node to a balanced 2-node.
// 'child' is a balanced sub-trees of 'n'
void _3_node_to_balanced_2_node( node_t* n, node_t* child )
{
assert( n->is_3_node() );
assert( child->is_2_node() );
// if the child is on the l-subtree
if( child == n->l_link )
{
// make l-key the central node and the h-key the balanced h-subtree
n->h_link = _2node_from_parts(n,n->kv1,n->m_link,n->h_link);
}
else
{
if( child == n->h_link )
{
// make h-key the central node and l-key the balanced l-subtree
n->l_link = _2node_from_parts(n,n->kv0,n->l_link,n->m_link);
_move_key_value(n->kv0,n->kv1);
}
else
{
// make m-subtree he central node and l-key the balanced l-subtree and h-key the balanced h-subtree
assert( child == n->m_link );
n->l_link = _2node_from_parts(n,n->kv0,n->l_link,child->l_link);
n->h_link = _2node_from_parts(n,n->kv1,child->h_link,n->h_link);
_move_key_value(n->kv0,child->kv0);
}
}
// n is now a 2-node - remove the old m_link
n->m_link = nullptr;
assert( n->is_2_node() );
assert( n->l_link->is_2_node() );
assert( n->h_link->is_2_node() );
}
void _insert_up( node_t* n, node_t* sub_tree )
{
while(1)
{
// if n is null then the root was already processed and we are done
if( n == nullptr )
break;
if( n->is_2_node() )
{
// if n is a 2-node the sub-tree is absorbed ...
_2_node_to_3_node(n,sub_tree);
break; // .. and we are done
}
else // n is a 3-node
{
// only 2-nodes and 3-nodes can be accessed when going up the tree
assert( n->is_3_node() );
// create a balanced 2-node from the 3-node + sub-tree
_3_node_to_balanced_2_node(n,sub_tree);
// the tree may now be imbalanced so continue upward
sub_tree = n;
n = n->parent;
}
}
}
void _insert_down( node_t* n, K key, V value )
{
while(1)
{
// If the key already exists at node n->kv0 then insert it in the kv0 value list
if( key == n->kv0.key )
{
_alloc_value(n->kv0,value);
return;
}
// If the key already exists at node n->kv1 then inser it in the kv1 value list
if( n->kv1.is_not_empty() && key == n->kv1.key )
{
_alloc_value(n->kv1,value);
return;
}
switch( n->type_id() )
{
case k1LeafTId:
_insert_into_1_leaf(n,key,value);
return; // the new k/v was absorbed - we're done.
case k2LeafTId:
if( key == 10 )
{
printf("break\n");
}
_insert_up( n->parent, _2_leaf_to_2_node_sub_tree(n, key, value ));
return; // the new k/v inserted on the upward path
case k2NodeTId:
n = key < n->kv0.key ? n->l_link : n->h_link;
break;
case k3NodeTId:
n = key < n->kv0.key ? n->l_link : (key < n->kv1.key ? n->m_link : n->h_link);
break;
default:
assert(0);
}
}
}
void insert( K key, V value )
{
if( _root == nullptr )
_root = _alloc_node(nullptr,key,value);
else
_insert_down(_root,key,value);
}
match_result_t _in_order_successor( const match_result_t& mr0 )
{
assert( mr0.node != nullptr && mr0.node->is_not_leaf() );
match_result_t r;
node_t* n;
// if mr0 is a 2 node or the high value of a 3 node
if( mr0.node->is_2_node() || (mr0.node->is_3_node() && mr0.kv_idx == 1) )
n = mr0.node->h_link; // get right subtree
else
{
assert( mr0.node->is_3_node() && mr0.kv_idx == 0 );
n = mr0.node->m_link;
}
// go to left most leaf
while( n->is_not_leaf() )
n = n->l_link;
r.node = n;
r.kv = &n->kv0;
r.kv_idx = 0;
return r;
}
void remove_key_value( K key, const V& value )
{
}
rc_t remove_key( K key )
{
rc_t rc = kOkRC;
match_result_t mr0 = key_to_node(key);
match_result_t mr1;
// the key does not exist in the tree.
if( mr0.node == nullptr )
{
rc = cwLogError(kEleNotFoundRC,"The element to remove was not found.");
goto errLabel;
}
// if the target node is a leaf
if( mr0.node->is_leaf() )
{
if( mr0.node->is_2_leaf() )
{
if( mr0.kv_idx == 0 )
_move_key_value(*mr0.kv0,*mr0.kv1);
//done: no hole exists in the leaf node
goto errLabel;
}
mr1 = mr0;
}
else // the target node is a 2 or 3 node
{
// locate the in-order sucessor
mr1 = _in_order_successor(mr0);
// the in-order successor must exist if n is a 2 or 3 node
assert( mr0->kv!= nullptr && mr1.kv != nullptr );
// move the in order successor value to the target node
_move_key_value(*mr0.kv,*mr1.kv);
// mr1.kv is now empty
// if mr1.node->kv0 is now empty
if(mr1.node->is_2_leaf() && mr1.kv_idx == 0 )
{
_move_key_value(*mr1.kv0,*mr1.kv1);
// done: mr1.node is now a 1 leaf - we're done
assert( mr1.node->is_1_leaf() );
goto errLabel;
}
}
assert( mr1.node != nullptr && mr1.node->is_leaf() );
if( mr1->is_2_leaf() )
{
}
else
{
}
// if key is found on internal node - replace with in-order successor.
// if in-order successor is on a non-leaf node continue replacing
// with in-order successor until the replacement leaves a hole
// in a leaf node.
// If the terminal node with the hole is a 2-leaf then change it to a 1-leaf : DONE
// if the terminal node is a 3-leaf then
errLabel:
return rc;
}
void _print( const node_t* n, unsigned level )
{
if( n->l_link != nullptr )
_print(n->l_link,level + 1);
unsigned pnid = n->parent==nullptr ? 666 : n->parent->nid;
printf("%i h:%i k0:%i %s id:%i par:%i\n",level,n->height(),n->kv0.key,node_tid_to_label(n->type_id()),n->nid,pnid);
if( n->m_link != nullptr )
_print(n->m_link,level+1);
if( n->kv1.is_not_empty() )
printf("%i h:%i k1:%i %s id:%i par:%i\n",level,n->height(),n->kv1.key,node_tid_to_label(n->type_id()),n->nid,pnid);
if( n->h_link != nullptr )
_print(n->h_link,level+1);
}
void print(const node_t* n = nullptr)
{
unsigned level = 0;
if( n == nullptr )
n = _root;
_print(n,level);
printf("done\n");
}
};
rc_t test( const object_t* cfg );
}
}
#endif
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