tumble / file revision

 /*

  * t2p: Create a PDF file from the contents of one or more TIFF

  *      bilevel image files.  The images in the resulting PDF file

  *      will be compressed using ITU-T T.6 (G4) fax encoding.

  *

  * PDF routines

  * $Id: pdf_name_tree.c,v 1.5 2003/03/07 23:45:46 eric Exp $

  * Copyright 2003 Eric Smith <eric@brouhaha.com>

  *

  * This program is free software; you can redistribute it and/or modify

  * it under the terms of the GNU General Public License version 2 as

  * published by the Free Software Foundation.  Note that permission is

  * not granted to redistribute this program under the terms of any

  * other version of the General Public License.

  *

  * 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 USA

  */

 #include <stdbool.h>

 #include <stdint.h>

 #include <stdio.h>

 #include <stdlib.h>

 #include <string.h>

 #include "bitblt.h"

 #include "pdf.h"

 #include "pdf_util.h"

 #include "pdf_prim.h"

 #include "pdf_private.h"

 #include "pdf_name_tree.h"

 #define MAX_NAME_TREE_NODE_ENTRIES 16

 struct pdf_name_tree_node

 {

   struct pdf_obj *dict;    /* indirect reference */

   struct pdf_name_tree_node *parent;  /* NULL for root */

   bool leaf;

   int count;               /* how many kids or names/numbers are

 			      attached to this node */

   struct pdf_name_tree_node *kids [MAX_NAME_TREE_NODE_ENTRIES];  /* non-leaf only */

   struct pdf_obj *min_key;

   struct pdf_obj *max_key;

   /* following fields valid in leaf nodes only: */

   struct pdf_obj *keys [MAX_NAME_TREE_NODE_ENTRIES];

   struct pdf_obj *values [MAX_NAME_TREE_NODE_ENTRIES];

 };

 struct pdf_name_tree *pdf_new_name_tree (pdf_file_handle pdf_file,

 					 bool number_tree)

 {

   struct pdf_name_tree *tree;

   struct pdf_name_tree_node *root;

   root = pdf_calloc (1, sizeof (struct pdf_name_tree_node));

   tree = pdf_calloc (1, sizeof (struct pdf_name_tree));

   tree->pdf_file = pdf_file;

   tree->root = root;

   tree->number_tree = number_tree;

   root->parent = NULL;

   root->leaf = 1;

   tree->next = pdf_file->name_tree_list;

   pdf_file->name_tree_list = tree;

   return (tree);

 }

 static void pdf_split_name_tree_node (struct pdf_name_tree *tree,

 				      struct pdf_name_tree_node *node)

 {

   struct pdf_name_tree_node *parent;

   struct pdf_name_tree_node *new_node;

   int i, j;

   parent = node->parent;

   if (! parent)

     {

       /* create new root above current root */

       struct pdf_name_tree_node *new_root_node;

       new_root_node = pdf_calloc (1, sizeof (struct pdf_name_tree_node));

       new_root_node->parent = NULL;

       new_root_node->leaf = 0;

       new_root_node->count = 1;

       new_root_node->kids [0] = node;

       new_root_node->min_key = node->min_key;

       new_root_node->max_key = node->max_key;

       parent = new_root_node;

       node->parent = new_root_node;

       tree->root = new_root_node;

     }

   new_node = pdf_calloc (1, sizeof (struct pdf_name_tree_node));

   new_node->parent = parent;

   new_node->leaf = node->leaf;

   /* move half the node's entries into the new node */

   i = node->count / 2;

   j = node->count - i;

   memcpy (& new_node->kids [0],

 	  & node->kids [i],

 	  j * sizeof (struct pdf_name_tree_node *));

   memcpy (& new_node->keys [0],

 	  & node->keys [i],

 	  j * sizeof (struct pdf_obj *));

   memcpy (& new_node->values [0],

 	  & node->values [i],

 	  j * sizeof (struct pdf_obj *));

   node->count = i;

   new_node->count = j;

   /* set max_key of the old node */

   if (node->leaf)

     node->max_key = node->keys [node->count - 1];

   else

     node->max_key = node->kids [node->count - 1]->max_key;

   /* set min_key and max_key in the new node */

   if (new_node->leaf)

     {

       new_node->min_key = new_node->keys [0];

       new_node->max_key = new_node->keys [new_node->count - 1];

     }

   else

     {

       new_node->min_key = new_node->kids [0]->min_key;

       new_node->max_key = new_node->kids [new_node->count - 1]->max_key;

     }

   /* insert new node in parent's kids array */

   /* find entry of old node */

   for (i = 0; i < parent->count; i++)

     if (parent->kids [i] == node)

       break;

   /* it had better have been there! */

   pdf_assert (i < parent->count);

   /* the new node goes in the slot to the right of the old node */

   i++;

   /* move other entries right one position */

   if (i != node->count)

     {

       memmove (& parent->kids [i+1],

 	       & parent->kids [i],

 	       (parent->count - i) * sizeof (struct pdf_name_tree_node *));

     }

   parent->kids [i] = new_node;

   parent->count++;

 }

 static void pdf_add_tree_element (struct pdf_name_tree *tree,

 				  struct pdf_obj *key,

 				  struct pdf_obj *val)

 {

   struct pdf_name_tree_node *node;

   int i;

   /* find node which should contain element */

   node = tree->root;

   while (! node->leaf)

     {

       for (i = 0; i < (node->count - 1); i++)

 	if (pdf_compare_obj (key, node->kids [i + 1]->min_key) < 0)

 	  break;

       node = node->kids [i];

     }

   /* if node is full, split, recursing to root if necessary */

   if (node->count == MAX_NAME_TREE_NODE_ENTRIES)

     {

       pdf_split_name_tree_node (tree, node);

       pdf_add_tree_element (tree, key, val);

       return;

     }

   /* figure out in which slot to insert it */

   for (i = 0; i < node->count; i++)

     if (pdf_compare_obj (key, node->keys [i] < 0))

       break;

   /* move other entries right one position */

   if (i != node->count)

     {

       memmove (& node->keys [i+1],

 	       & node->keys [i],

 	       (node->count - i) * sizeof (struct pdf_obj *));

       memmove (& node->values [i+1],

 	       & node->values [i],

 	       (node->count - i) * sizeof (struct pdf_obj *));

     }

   node->keys [i] = key;

   node->values [i] = val;

   node->count++;

   /* update limits, recursing upwards if necessary */

   if (i == 0)

     {

       node->min_key = key;

       while (node->parent && (node->parent->kids [0] == node))

 	{

 	  node = node->parent;

 	  node->min_key = key;

 	}

     }

   else if (i == (node->count - 1))

     {

       node->max_key = key;

       while (node->parent && (node->parent->kids [node->parent->count - 1] == node))

 	{

 	  node = node->parent;

 	  node->max_key = key;

 	}

     }

 }

 void pdf_add_name_tree_element (struct pdf_name_tree *tree,

 				char *key,

 				struct pdf_obj *val)

 {

   struct pdf_obj *key_obj = pdf_new_string (key);

   pdf_add_tree_element (tree, key_obj, val);

 }

 void pdf_add_number_tree_element (struct pdf_name_tree *tree,

 				  long key,

 				  struct pdf_obj *val)

 {

   struct pdf_obj *key_obj = pdf_new_integer (key);

   pdf_add_tree_element (tree, key_obj, val);

 }

 static void pdf_finalize_name_tree_node (struct pdf_name_tree *tree,

 					 struct pdf_name_tree_node *node)

 {

   int i;

   node->dict = pdf_new_ind_ref (tree->pdf_file, pdf_new_obj (PT_DICTIONARY));

   if (node->leaf)

     {

       /* write Names or Nums array */

       struct pdf_obj *names = pdf_new_obj (PT_ARRAY);

       for (i = 0; i < node->count; i++)

 	{

 	  pdf_add_array_elem (names, node->keys [i]);

 	  pdf_add_array_elem (names, node->values [i]);

 	}

       pdf_set_dict_entry (node->dict,

 			  tree->number_tree ? "Nums" : "Names",

 			  names);

     }

   else

     {

       /* finalize the children first so that their dict ind ref is

 	 available */

       for (i = 0; i < node->count; i++)

 	pdf_finalize_name_tree_node (tree, node->kids [i]);

       /* write Kids array */

       struct pdf_obj *kids = pdf_new_obj (PT_ARRAY);

       for (i = 0; i < node->count; i++)

 	pdf_add_array_elem (kids, node->kids [i]->dict);

       pdf_set_dict_entry (node->dict, "Kids", kids);

     }

   if (! node->parent)

     {

       /* write Limits array */

       struct pdf_obj *limits = pdf_new_obj (PT_ARRAY);

       pdf_add_array_elem (limits, node->min_key);

       pdf_add_array_elem (limits, node->max_key);

       pdf_set_dict_entry (node->dict, "Limits", limits);

     }

 }

 void pdf_finalize_name_trees (pdf_file_handle pdf_file)

 {

   struct pdf_name_tree *tree;

   for (tree = pdf_file->name_tree_list; tree; tree = tree->next)

     pdf_finalize_name_tree_node (tree, tree->root);

 }