windows-nt/Source/XPSP1/NT/base/win32/lz32/winlza/lzcommon.c

/*
** 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;
}
Add source files 2020-09-26 03:20:57 -05:00			`/*`
			`** 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;`
			`}`