/*--------------------------------------------------------------------*/
/*--- An ordered set implemented using an AVL tree. m_oset.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2005-2017 Nicholas Nethercote
njn@valgrind.org
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307, USA.
The GNU General Public License is contained in the file COPYING.
*/
//----------------------------------------------------------------------
// This file is based on:
//
// ANSI C Library for maintenance of AVL Balanced Trees
// (C) 2000 Daniel Nagy, Budapest University of Technology and Economics
// Released under GNU General Public License (GPL) version 2
//----------------------------------------------------------------------
// This file implements a generic ordered set using an AVL tree.
//
// Each node in the tree has two parts.
// - First is the AVL metadata, which is three words: a left pointer, a
// right pointer, and a word containing balancing information and a
// "magic" value which provides some checking that the user has not
// corrupted the metadata. So the overhead is 12 bytes on 32-bit
// platforms and 24 bytes on 64-bit platforms.
// - Second is the user's data. This can be anything. Note that because it
// comes after the metadata, it will only be word-aligned, even if the
// user data is a struct that would normally be doubleword-aligned.
//
// AvlNode* node -> +---------------+ V
// | struct |
// | AvlNode |
// void* element -> +---------------+ ^
// | element | |
// keyOff -> | key | elemSize
// +---------------+ v
//
// Users have to allocate AvlNodes with OSetGen_AllocNode(), which allocates
// space for the metadata.
//
// The terminology used throughout this file:
// - a "node", usually called "n", is a pointer to the metadata.
// - an "element", usually called "e", is a pointer to the user data.
// - a "key", usually called "k", is a pointer to a key.
//
// The helper functions elem_of_node and node_of_elem do the pointer
// arithmetic to switch between the node and the element. The node magic is
// checked after each operation to make sure that we're really operating on
// an AvlNode.
//
// Each tree also has an iterator. Note that we cannot use the iterator
// internally within this file (eg. we could implement OSetGen_Size() by
// stepping through with the iterator and counting nodes) because it's
// non-reentrant -- the user might be using it themselves, and the
// concurrent uses would screw things up.
#include "pub_core_basics.h"
#include "pub_core_libcbase.h"
#include "pub_core_libcassert.h"
#include "pub_core_libcprint.h"
#include "pub_core_oset.h"
#include "pub_core_poolalloc.h"
/*--------------------------------------------------------------------*/
/*--- Types and constants ---*/
/*--------------------------------------------------------------------*/
typedef struct _OSetNode OSetNode;
// Internal names for the OSet types.
typedef OSet AvlTree;
typedef OSetNode AvlNode;
// The padding ensures that magic is right at the end of the node,
// regardless of the machine's word size, so that any overwrites will be
// detected earlier.
struct _OSetNode {
AvlNode* left;
AvlNode* right;
Char balance;
Char padding[sizeof(void*)-sizeof(Char)-sizeof(Short)];
Short magic;
};
#define STACK_MAX 32 // At most 2**32 entries can be iterated over
#define OSET_MAGIC 0x5b1f
// An OSet (AVL tree). If cmp is NULL, the key must be a UWord, and must
// be the first word in the element. If cmp is set, arbitrary keys in
// arbitrary positions can be used.
struct _OSet {
SizeT keyOff; // key offset
OSetCmp_t cmp; // compare a key and an element, or NULL
Alloc_Fn_t alloc_fn; // allocator
const HChar* cc; // cost centre for allocator
Free_Fn_t free_fn; // deallocator
PoolAlloc* node_pa; // (optional) pool allocator for nodes.
SizeT maxEltSize; // for node_pa, must be > 0. Otherwise unused.
UInt nElems; // number of elements in the tree
AvlNode* root; // root node
AvlNode* nodeStack[STACK_MAX]; // Iterator node stack
Int numStack[STACK_MAX]; // Iterator num stack
Int stackTop; // Iterator stack pointer, one past end
};
/*--------------------------------------------------------------------*/
/*--- Helper operations ---*/
/*--------------------------------------------------------------------*/
// Given a pointer to the node's element, return the pointer to the AvlNode
// structure. If the node has a bad magic number, it will die with an
// assertion failure.
static inline
AvlNode* node_of_elem(const void *elem)
{
AvlNode* n = (AvlNode*)((Addr)elem - sizeof(AvlNode));
vg_assert2(n->magic == OSET_MAGIC,
"bad magic on node %p = %x (expected %x)\n"
"possible causes:\n"
" - node not allocated with VG_(OSetGen_AllocNode)()?\n"
" - node metadata corrupted by underwriting start of element?\n",
n, n->magic, OSET_MAGIC);
return n;
}
// Given an AvlNode, return the pointer to the element.
static inline
void* elem_of_node(const AvlNode *n)
{
vg_assert2(n->magic == OSET_MAGIC,
"bad magic on node %p = %x (expected %x)\n"
"possible causes:\n"
" - node metadata corrupted by overwriting end of element?\n",
n, n->magic, OSET_MAGIC);
return (void*)((Addr)n + sizeof(AvlNode));
}
// Like elem_of_node, but no magic checking.
static inline
void* elem_of_node_no_check(const AvlNode *n)
{
return (void*)((Addr)n + sizeof(AvlNode));
}
static inline
void* slow_key_of_node(const AvlTree* t, const AvlNode* n)
{
return (void*)((Addr)elem_of_node(n) + t->keyOff);
}
static inline
void* fast_key_of_node(const AvlNode* n)
{
return elem_of_node(n);
}
// Compare the first word of each element. Inlining is *crucial*.
static inline Word fast_cmp(const void* k, const AvlNode* n)
{
UWord w1 = *(const UWord*)k;
UWord w2 = *(const UWord*)elem_of_node(n);
// In previous versions, we tried to do this faster by doing
// "return w1 - w2". But it didn't work reliably, because the
// complete result of subtracting two N-bit numbers is an N+1-bit
// number, and what the caller is interested in is the sign of
// the complete N+1-bit result. The branching version is slightly
// slower, but safer and easier to understand.
if (w1 > w2) return 1;
if (w1 < w2) return -1;
return 0;
}
// Compare a key and an element. Inlining is *crucial*.
static
inline Word slow_cmp(const AvlTree* t, const void* k, const AvlNode* n)
{
return t->cmp(k, elem_of_node(n));
}
// Swing to the left. Warning: no balance maintenance.
static void avl_swl ( AvlNode** root )
{
AvlNode* a = *root;
AvlNode* b = a->right;
*root = b;
a->right = b->left;
b->left = a;
}
// Swing to the right. Warning: no balance maintenance.
static void avl_swr ( AvlNode** root )
{
AvlNode* a = *root;
AvlNode* b = a->left;
*root = b;
a->left = b->right;
b->right = a;
}
// Balance maintenance after especially nasty swings.
static void avl_nasty ( AvlNode* root )
{
switch (root->balance) {
case -1:
root->left->balance = 0;
root->right->balance = 1;
break;
case 1:
root->left->balance =-1;
root->right->balance = 0;
break;
case 0:
root->left->balance = 0;
root->right->balance = 0;
}
root->balance = 0;
}
// Clear the iterator stack.
static void stackClear(AvlTree* t)
{
Int i;
vg_assert(t);
for (i = 0; i < STACK_MAX; i++) {
t->nodeStack[i] = NULL;
t->numStack[i] = 0;
}
t->stackTop = 0;
}
// Push onto the iterator stack.
static inline void stackPush(AvlTree* t, AvlNode* n, Int i)
{
vg_assert(t->stackTop < STACK_MAX);
vg_assert(1 <= i && i <= 3);
t->nodeStack[t->stackTop] = n;
t-> numStack[t->stackTop] = i;
t->stackTop++;
}
// Pop from the iterator stack.
static inline Bool stackPop(AvlTree* t, AvlNode** n, Int* i)
{
vg_assert(t->stackTop <= STACK_MAX);
if (t->stackTop > 0) {
t->stackTop--;
*n = t->nodeStack[t->stackTop];
*i = t-> numStack[t->stackTop];
vg_assert(1 <= *i && *i <= 3);
t->nodeStack[t->stackTop] = NULL;
t-> numStack[t->stackTop] = 0;
return True;
} else {
return False;
}
}
/*--------------------------------------------------------------------*/
/*--- Creating and destroying AvlTrees and AvlNodes ---*/
/*--------------------------------------------------------------------*/
// The underscores avoid GCC complaints about overshadowing global names.
AvlTree* VG_(OSetGen_Create)(PtrdiffT keyOff, OSetCmp_t cmp,
Alloc_Fn_t alloc_fn, const HChar* cc,
Free_Fn_t free_fn)
{
AvlTree* t;
// Check the padding is right and the AvlNode is the expected size.
vg_assert(sizeof(AvlNode) == 3*sizeof(void*));
// Sanity check args
vg_assert(alloc_fn);
vg_assert(free_fn);
if (!cmp) vg_assert(0 == keyOff); // If no cmp, offset must be zero
t = alloc_fn(cc, sizeof(AvlTree));
t->keyOff = keyOff;
t->cmp = cmp;
t->alloc_fn = alloc_fn;
t->cc = cc;
t->free_fn = free_fn;
t->node_pa = NULL;
t->maxEltSize = 0; // Just in case it would be wrongly used.
t->nElems = 0;
t->root = NULL;
stackClear(t);
return t;
}
AvlTree* VG_(OSetGen_Create_With_Pool)(PtrdiffT keyOff, OSetCmp_t cmp,
Alloc_Fn_t alloc_fn, const HChar* cc,
Free_Fn_t free_fn,
SizeT poolSize,
SizeT maxEltSize)
{
AvlTree* t;
t = VG_(OSetGen_Create) (keyOff, cmp, alloc_fn, cc, free_fn);
vg_assert (poolSize > 0);
vg_assert (maxEltSize > 0);
t->maxEltSize = maxEltSize;
t->node_pa = VG_(newPA)(sizeof(AvlNode)
+ VG_ROUNDUP(maxEltSize, sizeof(void*)),
poolSize,
t->alloc_fn,
cc,
t->free_fn);
VG_(addRefPA) (t->node_pa);
return t;
}
AvlTree* VG_(OSetGen_EmptyClone) (const AvlTree* os)
{
AvlTree* t;
vg_assert(os);
t = os->alloc_fn(os->cc, sizeof(AvlTree));
t->keyOff = os->keyOff;
t->cmp = os->cmp;
t->alloc_fn = os->alloc_fn;
t->cc = os->cc;
t->free_fn = os->free_fn;
t->node_pa = os->node_pa;
if (t->node_pa)
VG_(addRefPA) (t->node_pa);
t->maxEltSize = os->maxEltSize;
t->nElems = 0;
t->root = NULL;
stackClear(t);
return t;
}
AvlTree* VG_(OSetWord_Create)(Alloc_Fn_t alloc_fn, const HChar* cc,
Free_Fn_t free_fn)
{
return VG_(OSetGen_Create)(/*keyOff*/0, /*cmp*/NULL, alloc_fn, cc, free_fn);
}
// Destructor, frees up all memory held by remaining nodes.
void VG_(OSetGen_Destroy)(AvlTree* t)
{
Bool has_node_pa;
vg_assert(t);
has_node_pa = t->node_pa != NULL;
/*
* If we are the only remaining user of this pool allocator, release all
* the elements by deleting the pool allocator. That's more efficient than
* deleting tree nodes one by one.
*/
if (!has_node_pa || VG_(releasePA)(t->node_pa) > 0) {
AvlNode* n = NULL;
Int i = 0;
UWord sz = 0;
stackClear(t);
if (t->root)
stackPush(t, t->root, 1);
/* Free all the AvlNodes. This is a post-order traversal, because we */
/* must free all children of a node before the node itself. */
while (stackPop(t, &n, &i)) {
switch (i) {
case 1:
stackPush(t, n, 2);
if (n->left) stackPush(t, n->left, 1);
break;
case 2:
stackPush(t, n, 3);
if (n->right) stackPush(t, n->right, 1);
break;
case 3:
if (has_node_pa)
VG_(freeEltPA) (t->node_pa, n);
else
t->free_fn(n);
sz++;
break;
}
}
vg_assert(sz == t->nElems);
}
/* Free the AvlTree itself. */
t->free_fn(t);
}
void VG_(OSetWord_Destroy)(AvlTree* t)
{
VG_(OSetGen_Destroy)(t);
}
// Allocate and initialise a new node.
void* VG_(OSetGen_AllocNode)(const AvlTree* t, SizeT elemSize)
{
AvlNode* n;
Int nodeSize = sizeof(AvlNode) + elemSize;
vg_assert(elemSize > 0);
if (t->node_pa) {
vg_assert(elemSize <= t->maxEltSize);
n = VG_(allocEltPA) (t->node_pa);
} else {
n = t->alloc_fn( t->cc, nodeSize );
}
VG_(memset)(n, 0, nodeSize);
n->magic = OSET_MAGIC;
return elem_of_node(n);
}
void VG_(OSetGen_FreeNode)(const AvlTree* t, void* e)
{
if (t->node_pa)
VG_(freeEltPA) (t->node_pa, node_of_elem (e));
else
t->free_fn( node_of_elem(e) );
}
/*--------------------------------------------------------------------*/
/*--- Insertion ---*/
/*--------------------------------------------------------------------*/
static inline Word cmp_key_root(const AvlTree* t, const AvlNode* n)
{
return t->cmp
? slow_cmp(t, slow_key_of_node(t, n), t->root)
: fast_cmp( fast_key_of_node( n), t->root);
}
// Insert element e into the non-empty AVL tree t.
// Returns True if the depth of the tree has grown.
static Bool avl_insert(AvlTree* t, AvlNode* n)
{
Word cmpres = cmp_key_root(t, n);
if (cmpres < 0) {
// Insert into the left subtree.
if (t->root->left) {
// Only need to set the used fields in the subtree.
AvlTree left_subtree;
left_subtree.root = t->root->left;
left_subtree.cmp = t->cmp;
left_subtree.keyOff = t->keyOff;
if (avl_insert(&left_subtree, n)) {
switch (t->root->balance--) {
case 1: return False;
case 0: return True;
}
if (t->root->left->balance < 0) {
avl_swr(&(t->root));
t->root->balance = 0;
t->root->right->balance = 0;
} else {
avl_swl(&(t->root->left));
avl_swr(&(t->root));
avl_nasty(t->root);
}
} else {
t->root->left=left_subtree.root;
}
return False;
} else {
t->root->left = n;
if (t->root->balance--) return False;
return True;
}
} else if (cmpres > 0) {
// Insert into the right subtree
if (t->root->right) {
// Only need to set the used fields in the subtree.
AvlTree right_subtree;
right_subtree.root = t->root->right;
right_subtree.cmp = t->cmp;
right_subtree.keyOff = t->keyOff;
if (avl_insert(&right_subtree, n)) {
switch (t->root->balance++) {
case -1: return False;
case 0: return True;
}
if (t->root->right->balance > 0) {
avl_swl(&(t->root));
t->root->balance = 0;
t->root->left->balance = 0;
} else {
avl_swr(&(t->root->right));
avl_swl(&(t->root));
avl_nasty(t->root);
}
} else {
t->root->right=right_subtree.root;
}
return False;
} else {
t->root->right = n;
if (t->root->balance++) return False;
return True;
}
} else {
vg_assert2(0, "OSet{Word,Gen}_Insert: duplicate element added");
}
}
// Insert element e into the AVL tree t. This is just a wrapper for
// avl_insert() which doesn't return a Bool.
void VG_(OSetGen_Insert)(AvlTree* t, void* e)
{
AvlNode* n;
vg_assert(t);
// Initialise. Even though OSetGen_AllocNode zeroes these fields,
// we should do it again in case a node is removed and then
// re-added to the tree.
n = node_of_elem(e);
n->left = 0;
n->right = 0;
n->balance = 0;
// Insert into an empty tree
if (!t->root) {
t->root = n;
} else {
avl_insert(t, n);
}
t->nElems++;
t->stackTop = 0; // So the iterator can't get out of sync
}
void VG_(OSetWord_Insert)(AvlTree* t, UWord val)
{
Word* node = VG_(OSetGen_AllocNode)(t, sizeof(UWord));
*node = val;
VG_(OSetGen_Insert)(t, node);
}
/*--------------------------------------------------------------------*/
/*--- Lookup ---*/
/*--------------------------------------------------------------------*/
// Find the *node* in t matching k, or NULL if not found.
static AvlNode* avl_lookup(const AvlTree* t, const void* k)
{
Word cmpres;
AvlNode* curr = t->root;
if (t->cmp) {
// General case
while (True) {
if (curr == NULL) return NULL;
cmpres = slow_cmp(t, k, curr);
if (cmpres < 0) curr = curr->left;
else if (cmpres > 0) curr = curr->right;
else return curr;
}
} else {
// Fast-track special case. We use the no-check version of
// elem_of_node because it saves about 10% on lookup time. This
// shouldn't be very dangerous because each node will have been
// checked on insertion.
UWord w1 = *(const UWord*)k;
UWord w2;
while (True) {
if (curr == NULL) return NULL;
w2 = *(UWord*)elem_of_node_no_check(curr);
if (w1 < w2) curr = curr->left;
else if (w1 > w2) curr = curr->right;
else return curr;
}
}
}
// Find the *element* in t matching k, or NULL if not found.
void* VG_(OSetGen_Lookup)(const AvlTree* t, const void* k)
{
AvlNode* n;
vg_assert(t);
n = avl_lookup(t, k);
return ( n ? elem_of_node(n) : NULL );
}
// Find the *element* in t matching k, or NULL if not found; use the given
// comparison function rather than the standard one.
void* VG_(OSetGen_LookupWithCmp)(AvlTree* t, const void* k, OSetCmp_t cmp)
{
// Save the normal one to the side, then restore once we're done.
void* e;
OSetCmp_t tmpcmp;
vg_assert(t);
tmpcmp = t->cmp;
t->cmp = cmp;
e = VG_(OSetGen_Lookup)(t, k);
t->cmp = tmpcmp;
return e;
}
// Is there an element matching k?
Bool VG_(OSetGen_Contains)(const AvlTree* t, const void* k)
{
return (NULL != VG_(OSetGen_Lookup)(t, k));
}
Bool VG_(OSetWord_Contains)(const AvlTree* t, UWord val)
{
return (NULL != VG_(OSetGen_Lookup)(t, &val));
}
/*--------------------------------------------------------------------*/
/*--- Deletion ---*/
/*--------------------------------------------------------------------*/
static Bool avl_removeroot(AvlTree* t);
// Remove an already-selected node n from the AVL tree t.
// Returns True if the depth of the tree has shrunk.
static Bool avl_remove(AvlTree* t, const AvlNode* n)
{
Bool ch;
Word cmpres = cmp_key_root(t, n);
if (cmpres < 0) {
AvlTree left_subtree;
// Remove from the left subtree
vg_assert(t->root->left);
// Only need to set the used fields in the subtree.
left_subtree.root = t->root->left;
left_subtree.cmp = t->cmp;
left_subtree.keyOff = t->keyOff;
ch = avl_remove(&left_subtree, n);
t->root->left = left_subtree.root;
if (ch) {
switch (t->root->balance++) {
case -1: return True;
case 0: return False;
}
switch (t->root->right->balance) {
case 0:
avl_swl(&(t->root));
t->root->balance = -1;
t->root->left->balance = 1;
return False;
case 1:
avl_swl(&(t->root));
t->root->balance = 0;
t->root->left->balance = 0;
return True;
}
avl_swr(&(t->root->right));
avl_swl(&(t->root));
avl_nasty(t->root);
return True;
} else {
return False;
}
} else if (cmpres > 0) {
// Remove from the right subtree
AvlTree right_subtree;
vg_assert(t->root->right);
// Only need to set the used fields in the subtree.
right_subtree.root = t->root->right;
right_subtree.cmp = t->cmp;
right_subtree.keyOff = t->keyOff;
ch = avl_remove(&right_subtree, n);
t->root->right = right_subtree.root;
if (ch) {
switch (t->root->balance--) {
case 1: return True;
case 0: return False;
}
switch (t->root->left->balance) {
case 0:
avl_swr(&(t->root));
t->root->balance = 1;
t->root->right->balance = -1;
return False;
case -1:
avl_swr(&(t->root));
t->root->balance = 0;
t->root->right->balance = 0;
return True;
}
avl_swl(&(t->root->left));
avl_swr(&(t->root));
avl_nasty(t->root);
return True;
} else {
return False;
}
} else {
// Found the node to be removed.
vg_assert(t->root == n);
return avl_removeroot(t);
}
}
// Remove the root of the AVL tree t.
// Returns True if the depth of the tree has shrunk.
static Bool avl_removeroot(AvlTree* t)
{
Bool ch;
AvlNode* n;
if (!t->root->left) {
if (!t->root->right) {
t->root = NULL;
return True;
}
t->root = t->root->right;
return True;
}
if (!t->root->right) {
t->root = t->root->left;
return True;
}
if (t->root->balance < 0) {
// Remove from the left subtree
n = t->root->left;
while (n->right) n = n->right;
} else {
// Remove from the right subtree
n = t->root->right;
while (n->left) n = n->left;
}
ch = avl_remove(t, n);
n->left = t->root->left;
n->right = t->root->right;
n->balance = t->root->balance;
t->root = n;
if (n->balance == 0) return ch;
return False;
}
// Remove and return the element matching the key 'k', or NULL
// if not present.
void* VG_(OSetGen_Remove)(AvlTree* t, const void* k)
{
// Have to find the node first, then remove it.
AvlNode* n = avl_lookup(t, k);
if (n) {
avl_remove(t, n);
t->nElems--;
t->stackTop = 0; // So the iterator can't get out of sync
return elem_of_node(n);
} else {
return NULL;
}
}
Bool VG_(OSetWord_Remove)(AvlTree* t, UWord val)
{
void* n = VG_(OSetGen_Remove)(t, &val);
if (n) {
VG_(OSetGen_FreeNode)(t, n);
return True;
} else {
return False;
}
}
/*--------------------------------------------------------------------*/
/*--- Iterator ---*/
/*--------------------------------------------------------------------*/
// The iterator is implemented using in-order traversal with an explicit
// stack, which lets us do the traversal one step at a time and remember
// where we are between each call to OSetGen_Next().
void VG_(OSetGen_ResetIter)(AvlTree* t)
{
vg_assert(t);
stackClear(t);
if (t->root)
stackPush(t, t->root, 1);
}
void VG_(OSetWord_ResetIter)(AvlTree* t)
{
VG_(OSetGen_ResetIter)(t);
}
void* VG_(OSetGen_Next)(AvlTree* t)
{
Int i = 0;
OSetNode* n = NULL;
vg_assert(t);
// This in-order traversal requires each node to be pushed and popped
// three times. These could be avoided by updating nodes in-situ on the
// top of the stack, but the push/pop cost is so small that it's worth
// keeping this loop in this simpler form.
while (stackPop(t, &n, &i)) {
switch (i) {
case 1: case_1:
stackPush(t, n, 2);
/* if (n->left) stackPush(t, n->left, 1); */
if (n->left) { n = n->left; goto case_1; }
break;
case 2:
stackPush(t, n, 3);
return elem_of_node(n);
case 3:
/* if (n->right) stackPush(t, n->right, 1); */
if (n->right) { n = n->right; goto case_1; }
break;
}
}
// Stack empty, iterator is exhausted, return NULL
return NULL;
}
Bool VG_(OSetWord_Next)(AvlTree* t, UWord* val)
{
UWord* n = VG_(OSetGen_Next)(t);
if (n) {
*val = *n;
return True;
} else {
return False;
}
}
// set up 'oset' for iteration so that the first key subsequently
// produced VG_(OSetGen_Next) is the smallest key in the map
// >= start_at. Naturally ">=" is defined by the comparison
// function supplied to VG_(OSetGen_Create).
void VG_(OSetGen_ResetIterAt)(AvlTree* oset, const void* k)
{
AvlNode *t;
Word cmpresS; /* signed */
UWord cmpresU; /* unsigned */
vg_assert(oset);
stackClear(oset);
if (!oset->root)
return;
// We need to do regular search and fill in the stack.
t = oset->root;
while (True) {
if (t == NULL) return;
if (oset->cmp) {
cmpresS = (Word)slow_cmp(oset, k, t);
} else {
cmpresS = fast_cmp(k, t);
}
/* Switch the sense of the comparison, since the comparison
order of args (k vs t) above is opposite to that of the
corresponding code in hg_wordfm.c. */
if (cmpresS < 0) { cmpresS = 1; }
else if (cmpresS > 0) { cmpresS = -1; }
if (cmpresS == 0) {
// We found the exact key -- we are done.
// The iteration should start with this node.
stackPush(oset, t, 2);
// The stack now looks like {2, 2, ... ,2, 2}
return;
}
cmpresU = (UWord)cmpresS;
cmpresU >>=/*unsigned*/ (8 * sizeof(cmpresU) - 1);
vg_assert(cmpresU == 0 || cmpresU == 1);
if (!cmpresU) {
// Push this node only if we go to the left child.
stackPush(oset, t, 2);
}
t = cmpresU==0 ? t->left : t->right;
}
}
/*--------------------------------------------------------------------*/
/*--- Miscellaneous operations ---*/
/*--------------------------------------------------------------------*/
UInt VG_(OSetGen_Size)(const AvlTree* t)
{
vg_assert(t);
return t->nElems;
}
Word VG_(OSetWord_Size)(const AvlTree* t)
{
return VG_(OSetGen_Size)(t);
}
static void OSet_Print2( const AvlTree* t, const AvlNode* n,
const HChar*(*strElem)(const void *), Int p )
{
// This is a recursive in-order traversal.
Int q = p;
if (NULL == n) return;
if (n->right) OSet_Print2(t, n->right, strElem, p+1);
while (q--) VG_(printf)(".. ");
VG_(printf)("%s\n", strElem(elem_of_node(n)));
if (n->left) OSet_Print2(t, n->left, strElem, p+1);
}
__attribute__((unused))
static void OSet_Print( const AvlTree* t, const HChar *where,
const HChar*(*strElem)(const void *) )
{
VG_(printf)("-- start %s ----------------\n", where);
OSet_Print2(t, t->root, strElem, 0);
VG_(printf)("-- end %s ----------------\n", where);
}
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/