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I didn't understand what do the Huffman tables of Jpeg contain, could someone explain this to me? Thanks

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en.wikipedia.org/wiki/JPEG explains the format in detail. –  macarthy Feb 10 '11 at 6:37

2 Answers 2

up vote 4 down vote accepted

Huffman encoding is a variable-length data compression method. It works by assigning the most frequent values in an input "text" to the encodings with the smallest bit lengths.

For example, the input:

Seems every eel eeks elegantly

may encode the letter e as binary 1 and all other letters as various other longer codes, all starting with 0. That way, the resultant bit stream would be smaller than if every letter was a fixed size. By way of example, let's examine the quantities of each character and construct a tree that puts the common ones at the top.

Letter  Count
------  -----
e          10
<SPC>       4
l           3
sy          2
Smvrkgant   1
<EOF>       1

The end of file marker EOF is there since you generally have to have a multiple of eight bits in your file. It's to stop any padding at the end from being treated as a real character.

                                 __________#__________
                ________________/______________       \
       ________/________                   ____\____   e
    __/__             __\__             __/__       \
   /     \           /     \           /     \     / \
  /       \         /       \         /      SPC  l   s
 / \     / \       / \     / \       / \
y   S   m   v     r   k   g   \     n   t
                             / \
                            a  EOF

Now this isn't necessarily the most efficient tree but it's enough to establish how the encodings are done. Let's first look at the uncompressed data. Assuming an eight-bit encoding, those thirty characters (don't need the EOF for the uncompressed data) are going to take up 240 bits.

But, if you use the tree above to locate the characters, outputting a zero bit if you take the left sub-tree and a one bit if you take the right, you get the following:

Word            Encoding
----------      --------
Seems<SPC>      00001 1 1 00010 0111 0101                           (20 bits)
every<SPC>      1 00011 1 00100 00000 0101                          (21 bits)
eel<SPC>        1 1 0110 0101                                       (10 bits)
eeks<SPC>       1 1 00101 0111 0101                                 (15 bits)
elegantly<EOF>  1 0110 1 00110 001110 01000 01001 0110 00000 001111 (42 bits)

That give a grand total of 108 bits, rounded up to 112 since it'll be on a byte boundary, but that's still about 47% of the uncompressed size.

Now whether that's worth it for a small file like this is debatable, since you have to add the space taken up by the actual tree itself, otherwise you cannot decode it at the other end (a). But certainly, for larger files where the distribution of characters isn't even, it can lead to impressive savings in space.

The same method can be used on arbitrary input streams, not just textual input.

So, after all that, the Huffman tables in a JPEG are simply the tables that allow you to uncompress the stream into usable information.

The encoding process for JPEG consists of a few different steps (color conversion, chroma resolution reduction, block-based discrete cosine transforms, and so on) but the final step is a lossless Huffman encoding on each block which is what those tables are used to reverse when reading the image.


(a) There is another variant of Huffman called Adaptive Huffman, where the table isn't actually stored. Instead, during compression, the table starts with a single special bit sequence meant to introduce a new real character to the table, and possibly the EOF sequence as well.

When introducing a new character to the table, you would output the introducer bit sequence followed by the full bits of the character.

Then, after each character is output and the counts updated, the table/tree is rebalanced based on the new counts to be the most space-efficient (though the rebalancing may be deferred to improve speed, say to a 1K boundary for example).

This means that the table itself can be built in exactly the same way at the other end (decompression), starting with the same minimal one with just an introducer (and possibly EOF) sequence.

When you see the introducer sequence during decode, you can add the character following it with a count of zero, output the character, then adjust the count and re-balance (or defer as previously mentioned).

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The DHT marker doesn't specify directly which symbol is associated with a code. It contains a vector with counts of how many codes there are of a given length. After that it contains a vector with symbol values.

So when you want to decode you have to generate the huffman codes from the first vector and then associate every code with a symbol in the second vector.

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