AVR-Huffman/en: Unterschied zwischen den Versionen
Bg (Diskussion | Beiträge) (→Facts: reduced code size) |
Bg (Diskussion | Beiträge) (updated) |
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(Eine dazwischenliegende Version desselben Benutzers wird nicht angezeigt) | |||
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|author = Daniel | |author = Daniel | ||
|username = Bg | |username = Bg | ||
|version = 0.1. | |version = 0.1.9 | ||
|update = | |update = | ||
|platform = AVR | |platform = AVR | ||
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==Facts== | ==Facts== | ||
* | * 468 bytes of code for the assembler variant | ||
* C-Interface (avr-gcc) | * C-Interface (avr-gcc) | ||
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===huffman_dec_byte=== | ===huffman_dec_byte=== | ||
This function initializes the huffman-tree when first called with a new context. Every call to this function (including the first one) will return a byte of uncompressed data or ''EOF'' at the end of the compressed file. The function automatically calls the reading function if compressed data is needed. | This function initializes the huffman-tree when first called with a new context. Every call to this function (including the first one) will return a byte of uncompressed data or ''EOF'' (0xFFFF) at the end of the compressed file. The function automatically calls the reading function if compressed data is needed. | ||
===reading-function=== | ===reading-function=== | ||
A pointer to the ''reading-function'' is used to initialize a context. The function takes a parameter which holds the address to be read. The address is always incremented by one, so it is save to ignore the parameter and use an internal address variable. The function also may return an ''EOF'' ( | A pointer to the ''reading-function'' is used to initialize a context. The function takes a parameter which holds the address to be read. The address is always incremented by one, so it is save to ignore the parameter and use an internal address variable. The function also may return an ''EOF'' (0xFFFF), but this is not needed as the data stream includes an EOF-marker. | ||
The function may read data from any location including streams. | The function may read data from any location including streams. | ||
Aktuelle Version vom 7. Juli 2011, 02:12 Uhr
AVR-Huffman Release status: stable [box doku] | |
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Description | decompression of huffman compressed data at runtime |
Author(s) | Daniel (Bg) |
Last Version | 0.1.9 () |
Platform | AVR |
License | GPLv3+ |
Download | SVN browse |
Eine deutsche Version dieses Artikes ist verfügbar unte AVR-Huffman
About[Bearbeiten | Quelltext bearbeiten]
AVR-Huffman is an impementation of huffman-compression, consisting of 3 components:
- tool for compressing binary data (huffman-encode; host; written in portable C)
- tool for uncompressind data (huffman-decode; host; written in portable C)
- implementation of decompression for AVR microcontrollers (available in optimized assembler and C)
Facts[Bearbeiten | Quelltext bearbeiten]
- 468 bytes of code for the assembler variant
- C-Interface (avr-gcc)
API[Bearbeiten | Quelltext bearbeiten]
typedef ... huffman_dec_ctx_t; void huffman_dec_init(huffman_dec_ctx_t* ctx, uint16_t(*rb_func)(uint16_t)); void huffman_dec_set_addr(huffman_dec_ctx_t* ctx,uint16_t addr); uint16_t huffman_dec_byte(huffman_dec_ctx_t* ctx);
huffman_dec_ctx_t[Bearbeiten | Quelltext bearbeiten]
This context type defines the storage structure used by an instance of the huffman decompressor. This means that a variable of this type may hold the information needed for decompressing (for example: the tree, buffers for bitwise reading, pointer to the reading-function).
huffman_dec_init[Bearbeiten | Quelltext bearbeiten]
This function initializes a variable of the type huffman_dec_ctx_t which is located by a pointer to this function. The second argument is a pointer to the function which should be called to read compressed data.
huffman_dec_set_addr[Bearbeiten | Quelltext bearbeiten]
This function can be used to set the address which is given as parameter to the reading function. The address is sored in the context and will be incremented by one automatically.
huffman_dec_byte[Bearbeiten | Quelltext bearbeiten]
This function initializes the huffman-tree when first called with a new context. Every call to this function (including the first one) will return a byte of uncompressed data or EOF (0xFFFF) at the end of the compressed file. The function automatically calls the reading function if compressed data is needed.
reading-function[Bearbeiten | Quelltext bearbeiten]
A pointer to the reading-function is used to initialize a context. The function takes a parameter which holds the address to be read. The address is always incremented by one, so it is save to ignore the parameter and use an internal address variable. The function also may return an EOF (0xFFFF), but this is not needed as the data stream includes an EOF-marker. The function may read data from any location including streams.
dynamic memory requirements[Bearbeiten | Quelltext bearbeiten]
When called the first time avr-huffman-decode allocates dynamic memory for the internal huffman-tree. The memory is allocated via the calloc() function and later freed automatically when reaching the END-OF-FILE marker via the free() function. The required amount of dynamic memory only depends on the number of different symbols (bytes) in the uncompressed file. For each different symbol three bytes are needed. So in the worst-case (all 256 different byte values are present) 768 bytes of dynamic memory are required.
Concept[Bearbeiten | Quelltext bearbeiten]
Fileformat[Bearbeiten | Quelltext bearbeiten]
Note: The used format does not store the tree in an optimal way. This is justified by the reduced complexity of the decoder. The overhead should be in the range of a few bytes.
The file starts with a 15 bit magic-value of 0xC0 0xDE. The last bit may be 1 or 0 so the first two bytes may read as 0xC0 0xDE or 0xC0 0xDF. The next nine bits represent the number of leafs in the tree. The last leaf is always used for the EOF-marker.
Following the number of leafs there is repetitive structure starting always with a byte indicating the number of leaf at the current level followed by the leafs values.
The tree structure is followed by the binary representation of the compressed data. The highest bit in a byte is considered the first bit.
Example[Bearbeiten | Quelltext bearbeiten]
Plaintext:
abcaaab\n
expressed as hexdump:
00000000 61 62 63 61 61 61 62 0a |abcaaab.| 00000008
compressed it would read like this:
00000000 c0 de 05 01 61 00 04 63 0a 62 ff 68 35 e0 |....a..c.b.h5.| 0000000e