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How to transfer a binary tree (not a balanced tree) across two different systems efficiently, retaining its complete structure?

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Is it a binary search tree or just a binary tree? –  Amarghosh Aug 31 '10 at 7:33
Please provide details of the memory structure used to store the tree. E.g. are you using a contiguous block of memory? Are you calling malloc for each individual data block in the tree? Where does the root pointer reside? –  PP. Aug 31 '10 at 7:40
+1 just because I don't think it deserves the downvotes. Question is not ambiguous. –  Potatoswatter Aug 31 '10 at 7:53

4 Answers 4

The obvious way would be to convert your binary tree to an array of nodes, replacing each pointer in the original tree with an index to a node in the array. You can then transmit that array, and on the other end reconstruct a tree with identical structure.

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+1. That is what I have used myself in past. –  Dummy00001 Aug 31 '10 at 11:03

This structure given below

   /   \
 [L]   [R]

can be translated easily into


Also, read a post by Eric Lippert.

NOTE: I feel, similar thing should work for arbitrary trees. Any comments?

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for uniformity, (P,-,-) –  Potatoswatter Aug 31 '10 at 8:11
Yes. Thanks for pointing that out! :) –  Pratik Deoghare Aug 31 '10 at 8:12
Note for myself : To get up votes mention Eric Lippert!! ;D –  Pratik Deoghare Aug 31 '10 at 9:53
For arbitrary trees, the '-' is not needed. (X,(L,(P)),(R)) would do. Or won't it? –  lalli Aug 31 '10 at 10:32
@lalli Yes,you are right. +1 –  Pratik Deoghare Aug 31 '10 at 11:42

Define serialization functions.

void serialize( FILE *f, my_tree *node, _Bool is_root ) {
    if ( node == NULL ) {
        fputc( no_child, f );

    if ( ! is_root ) fputc( data_prefix, f );
    write_data( f, node->data );
    fputc( data_terminator, f );

    write_data( node->left_child );
    write_data( node->right_child );

void deserialize_node( FILE *f, my_tree *node ) {
    node->data = read_data_field( f );

    if ( fgetc( f ) != no_child ) {
         node->left_child = calloc( 1, sizeof( my_tree ) );
         deserialize( f, node->left_child, false );

    if ( fgetc( f ) != no_child ) {
         node->right_child = calloc( 1, sizeof( my_tree ) );
         deserialize( f, node->right_child, false );

Come to think of it, this simple scheme (where data_terminator and no_child must be single characters) allows both data_terminator and no_child to be equal.

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-1 because this is a C++ answer for a C question –  Jens Gustedt Aug 31 '10 at 8:10
bah! need to pay attention. –  Potatoswatter Aug 31 '10 at 8:12
@Jens: translated. –  Potatoswatter Aug 31 '10 at 8:33
ok, thanks, downvote removed –  Jens Gustedt Aug 31 '10 at 9:39

The main issue with this is that you have to replace pointers or references from your in memory representation with something else that can be used to unambiguously represent the node that was pointed to.

    /   \
 cat     zebra

One way to do this is to exchange the pointers for keys -- more like an array index than a proper pointer.

1 2 "foo"
3 _ "cat"
_ _ "zebra"
_ _ "dog"

In this representation the first field is the line number (counting starts at 0, which is the root node) of the left child, the second field is the right child, and the third field is the value. The tree is ordered alphabetically. This seems simple, but can be difficult to actually do.

A similar approach would put the key in each entry rather than rely on position. This method could use the original pointers as the keys and the read-in code would have to build a translation/symbol table to switch between the keys and new pointers.

Another way to go about this is with a lisp-esque tree: (foo (cat () (dog () ()) (zebra () () ))

Formatted for easy viewing:


This can be easily generated by a simple in order traversal. It can also be read in with a very simple recursive decent parser. You can also alter this to decrease the sizes of leaf nodes in the serialized format by omitting the nil or () or whatever you chose for NULL pointers.

Another method, which is similar to the first, is to store all of tree in one chunk of memory that can be dumped to and read back from disk. The pointers in this would be relative to the beginning of this memory chunk, rather than absolute pointers. This would be a fast way for two programs on the same type of machine (using the same CPU memory width) to share trees (or other graphs), but is likely to be difficult to implement.

The lisp-esqe version of this is super easy to implement, but does not easily extend to things that aren't trees, where there could be a cyclic reference or more than one parent for a particular node, though it can be done. It also does not easily extend to handle storing more than one structure in a particular file.

The line positional index version works for most types of graphs, but storing more than one structure in a particular file would need to alter this format somewhat.

No matter what you choose you will need to make sure you can handle all values that could be present as node data. For instance if the node data could contain a ", ), or \n then it might cause problems in some of the formats I've show, and those characters would need to be escaped. You could prefix fields with their length or use constant structure layout to account for this, though.

You will also need to make sure that any binary fields are stored in an endian consistent manner if you plan on sharing data between different machine types. You will also want this data to have consistent size (use stdint.h types rather than int and long) and a canonical representation for things like floating point numbers.

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+1 Thorough answer. –  Skurmedel Sep 1 '10 at 8:15

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