Source code of Windows XP (NT5)
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/*
** lzcommon.c - Routines common to LZ compression / expansion.
**
** Author: DavidDi
*/
// Headers
///////////
#include "lz_common.h"
#include "lz_buffers.h"
#include "lzcommon.h"
/*
** bool LZInitTree(void);
**
** Initializes trees used in LZ compression.
**
** Arguments: none
**
** Returns: true/false
**
** Globals: RightChild[] and Parent[] arrays reset to NIL to begin
** encoding.
*/
BOOL LZInitTree(PLZINFO pLZI)
{
INT i;
/*
** For i = 0 to RING_BUF_LEN - 1, rightChild[i] and leftChild[i] will be the
** right and left children of node i. These nodes need not be initialized.
** Also, parent[i] is the parent of node i. These are initialized to
** NIL (= N), which stands for 'not used.'
** For i = 0 to 255, rightChild[RING_BUF_LEN + i + 1] is the root of the tree
** for strings that begin with character i. These are initialized to NIL.
** n.b., there are 256 trees.
*/
if (!pLZI->rightChild) {
if (!(pLZI->rightChild = (INT*)LocalAlloc(LPTR, (RING_BUF_LEN + 257) * sizeof(INT)))) {
return(FALSE);
}
}
if (!pLZI->leftChild) {
if (!(pLZI->leftChild = (INT*)LocalAlloc(LPTR, (RING_BUF_LEN + 1) * sizeof(INT)))) {
return(FALSE);
}
}
if (!pLZI->parent) {
if (!(pLZI->parent = (INT*)LocalAlloc(LPTR, (RING_BUF_LEN + 1) * sizeof(INT)))) {
return(FALSE);
}
}
for (i = RING_BUF_LEN + 1; i <= RING_BUF_LEN + 256; i++)
pLZI->rightChild[i] = NIL;
for (i = 0; i < RING_BUF_LEN; i++)
pLZI->parent[i] = NIL;
return(TRUE);
}
VOID
LZFreeTree(PLZINFO pLZI)
{
// Sanity check
if (!pLZI) {
return;
}
if (pLZI->rightChild) {
LocalFree((HLOCAL)pLZI->rightChild);
pLZI->rightChild = NULL;
}
if (pLZI->leftChild) {
LocalFree((HLOCAL)pLZI->leftChild);
pLZI->leftChild = NULL;
}
if (pLZI->parent) {
LocalFree((HLOCAL)pLZI->parent);
pLZI->parent = NULL;
}
}
/*
** void LZInsertNode(int nodeToInsert, BOOL bDoArithmeticInsert);
**
** Inserts a new tree into the forest. Inserts string of length
** cbMaxMatchLen, rgbyteRingBuf[r..r + cbMaxMatchLen - 1], into one of the trees
** (rgbyteRingBuf[r]'th tree).
**
** Arguments: nodeToInsert - start of string in ring buffer to insert
** (also, associated tree root)
** bDoArithmeticInsert - flag for performing regular LZ node
** insertion or arithmetic encoding node
** insertion
**
** Returns: void
**
** Globals: cbCurMatch - set to length of longest match
** iCurMatch - set to start index of longest matching string in
** ring buffer
**
** N.b., if cbCurMatch == cbMaxMatchLen, we remove the old node in favor of
** the new one, since the old node will be deleted sooner.
*/
VOID LZInsertNode(INT nodeToInsert, BOOL bDoArithmeticInsert, PLZINFO pLZI)
{
INT i, p, cmp, temp;
BYTE FAR *key;
// Sanity check
if (!pLZI) {
return;
}
cmp = 1;
key = pLZI->rgbyteRingBuf + nodeToInsert;
p = RING_BUF_LEN + 1 + key[0];
pLZI->rightChild[nodeToInsert] = pLZI->leftChild[nodeToInsert] = NIL;
pLZI->cbCurMatch = 0;
FOREVER
{
if (cmp >= 0)
{
if (pLZI->rightChild[p] != NIL)
p = pLZI->rightChild[p];
else
{
pLZI->rightChild[p] = nodeToInsert;
pLZI->parent[nodeToInsert] = p;
return;
}
}
else
{
if (pLZI->leftChild[p] != NIL)
p = pLZI->leftChild[p];
else
{
pLZI->leftChild[p] = nodeToInsert;
pLZI->parent[nodeToInsert] = p;
return;
}
}
for (i = 1; i < pLZI->cbMaxMatchLen; i++)
if ((cmp = key[i] - pLZI->rgbyteRingBuf[p + i]) != 0)
break;
if (bDoArithmeticInsert == TRUE)
{
// Do node insertion for arithmetic encoding.
if (i > MAX_LITERAL_LEN)
{
if (i > pLZI->cbCurMatch)
{
pLZI->iCurMatch = (nodeToInsert - p) & (RING_BUF_LEN - 1);
if ((pLZI->cbCurMatch = i) >= pLZI->cbMaxMatchLen)
break;
}
else if (i == pLZI->cbCurMatch)
{
if ((temp = (nodeToInsert - p) & (RING_BUF_LEN - 1)) < pLZI->iCurMatch)
pLZI->iCurMatch = temp;
}
}
}
else
{
// Do node insertion for LZ.
if (i > pLZI->cbCurMatch)
{
pLZI->iCurMatch = p;
if ((pLZI->cbCurMatch = i) >= pLZI->cbMaxMatchLen)
break;
}
}
}
pLZI->parent[nodeToInsert] = pLZI->parent[p];
pLZI->leftChild[nodeToInsert] = pLZI->leftChild[p];
pLZI->rightChild[nodeToInsert] = pLZI->rightChild[p];
pLZI->parent[pLZI->leftChild[p]] = nodeToInsert;
pLZI->parent[pLZI->rightChild[p]] = nodeToInsert;
if (pLZI->rightChild[pLZI->parent[p]] == p)
pLZI->rightChild[pLZI->parent[p]] = nodeToInsert;
else
pLZI->leftChild[pLZI->parent[p]] = nodeToInsert;
// Remove p.
pLZI->parent[p] = NIL;
return;
}
/*
** void LZDeleteNode(int nodeToDelete);
**
** Delete a tree from the forest.
**
** Arguments: nodeToDelete - tree to delete from forest
**
** Returns: void
**
** Globals: Parent[], RightChild[], and LeftChild[] updated to reflect the
** deletion of nodeToDelete.
*/
VOID LZDeleteNode(INT nodeToDelete, PLZINFO pLZI)
{
INT q;
// Sanity check
if (!pLZI) {
return;
}
if (pLZI->parent[nodeToDelete] == NIL)
// Tree nodeToDelete is not in the forest.
return;
if (pLZI->rightChild[nodeToDelete] == NIL)
q = pLZI->leftChild[nodeToDelete];
else if (pLZI->leftChild[nodeToDelete] == NIL)
q = pLZI->rightChild[nodeToDelete];
else
{
q = pLZI->leftChild[nodeToDelete];
if (pLZI->rightChild[q] != NIL)
{
do
{
q = pLZI->rightChild[q];
} while (pLZI->rightChild[q] != NIL);
pLZI->rightChild[pLZI->parent[q]] = pLZI->leftChild[q];
pLZI->parent[pLZI->leftChild[q]] = pLZI->parent[q];
pLZI->leftChild[q] = pLZI->leftChild[nodeToDelete];
pLZI->parent[pLZI->leftChild[nodeToDelete]] = q;
}
pLZI->rightChild[q] = pLZI->rightChild[nodeToDelete];
pLZI->parent[pLZI->rightChild[nodeToDelete]] = q;
}
pLZI->parent[q] = pLZI->parent[nodeToDelete];
if (pLZI->rightChild[pLZI->parent[nodeToDelete]] == nodeToDelete)
pLZI->rightChild[pLZI->parent[nodeToDelete]] = q;
else
pLZI->leftChild[pLZI->parent[nodeToDelete]] = q;
// Remove nodeToDelete.
pLZI->parent[nodeToDelete] = NIL;
return;
}