summaryrefslogtreecommitdiffstats
path: root/drivers/char/ftape/compressor/lzrw3.c
diff options
context:
space:
mode:
Diffstat (limited to 'drivers/char/ftape/compressor/lzrw3.c')
-rw-r--r--drivers/char/ftape/compressor/lzrw3.c743
1 files changed, 0 insertions, 743 deletions
diff --git a/drivers/char/ftape/compressor/lzrw3.c b/drivers/char/ftape/compressor/lzrw3.c
deleted file mode 100644
index a032a0ee2a9..00000000000
--- a/drivers/char/ftape/compressor/lzrw3.c
+++ /dev/null
@@ -1,743 +0,0 @@
-/*
- * $Source: /homes/cvs/ftape-stacked/ftape/compressor/lzrw3.c,v $
- * $Revision: 1.1 $
- * $Date: 1997/10/05 19:12:29 $
- *
- * Implementation of Ross Williams lzrw3 algorithm. Adaption for zftape.
- *
- */
-
-#include "../compressor/lzrw3.h" /* Defines single exported function "compress". */
-
-/******************************************************************************/
-/* */
-/* LZRW3.C */
-/* */
-/******************************************************************************/
-/* */
-/* Author : Ross Williams. */
-/* Date : 30-Jun-1991. */
-/* Release : 1. */
-/* */
-/******************************************************************************/
-/* */
-/* This file contains an implementation of the LZRW3 data compression */
-/* algorithm in C. */
-/* */
-/* The algorithm is a general purpose compression algorithm that runs fast */
-/* and gives reasonable compression. The algorithm is a member of the Lempel */
-/* Ziv family of algorithms and bases its compression on the presence in the */
-/* data of repeated substrings. */
-/* */
-/* This algorithm is unpatented and the code is public domain. As the */
-/* algorithm is based on the LZ77 class of algorithms, it is unlikely to be */
-/* the subject of a patent challenge. */
-/* */
-/* Unlike the LZRW1 and LZRW1-A algorithms, the LZRW3 algorithm is */
-/* deterministic and is guaranteed to yield the same compressed */
-/* representation for a given file each time it is run. */
-/* */
-/* The LZRW3 algorithm was originally designed and implemented */
-/* by Ross Williams on 31-Dec-1990. */
-/* */
-/* Here are the results of applying this code, compiled under THINK C 4.0 */
-/* and running on a Mac-SE (8MHz 68000), to the standard calgary corpus. */
-/* */
-/* +----------------------------------------------------------------+ */
-/* | DATA COMPRESSION TEST | */
-/* | ===================== | */
-/* | Time of run : Sun 30-Jun-1991 09:31PM | */
-/* | Timing accuracy : One part in 100 | */
-/* | Context length : 262144 bytes (= 256.0000K) | */
-/* | Test suite : Calgary Corpus Suite | */
-/* | Files in suite : 14 | */
-/* | Algorithm : LZRW3 | */
-/* | Note: All averages are calculated from the un-rounded values. | */
-/* +----------------------------------------------------------------+ */
-/* | File Name Length CxB ComLen %Remn Bits Com K/s Dec K/s | */
-/* | ---------- ------ --- ------ ----- ---- ------- ------- | */
-/* | rpus:Bib.D 111261 1 55033 49.5 3.96 19.46 32.27 | */
-/* | us:Book1.D 768771 3 467962 60.9 4.87 17.03 31.07 | */
-/* | us:Book2.D 610856 3 317102 51.9 4.15 19.39 34.15 | */
-/* | rpus:Geo.D 102400 1 82424 80.5 6.44 11.65 18.18 | */
-/* | pus:News.D 377109 2 205670 54.5 4.36 17.14 27.47 | */
-/* | pus:Obj1.D 21504 1 13027 60.6 4.85 13.40 18.95 | */
-/* | pus:Obj2.D 246814 1 116286 47.1 3.77 19.31 30.10 | */
-/* | s:Paper1.D 53161 1 27522 51.8 4.14 18.60 31.15 | */
-/* | s:Paper2.D 82199 1 45160 54.9 4.40 18.45 32.84 | */
-/* | rpus:Pic.D 513216 2 122388 23.8 1.91 35.29 51.05 | */
-/* | us:Progc.D 39611 1 19669 49.7 3.97 18.87 30.64 | */
-/* | us:Progl.D 71646 1 28247 39.4 3.15 24.34 40.66 | */
-/* | us:Progp.D 49379 1 19377 39.2 3.14 23.91 39.23 | */
-/* | us:Trans.D 93695 1 33481 35.7 2.86 25.48 40.37 | */
-/* +----------------------------------------------------------------+ */
-/* | Average 224401 1 110953 50.0 4.00 20.17 32.72 | */
-/* +----------------------------------------------------------------+ */
-/* */
-/******************************************************************************/
-
-/******************************************************************************/
-
-/* The following structure is returned by the "compress" function below when */
-/* the user asks the function to return identifying information. */
-/* The most important field in the record is the working memory field which */
-/* tells the calling program how much working memory should be passed to */
-/* "compress" when it is called to perform a compression or decompression. */
-/* LZRW3 uses the same amount of memory during compression and decompression. */
-/* For more information on this structure see "compress.h". */
-
-#define U(X) ((ULONG) X)
-#define SIZE_P_BYTE (U(sizeof(UBYTE *)))
-#define SIZE_WORD (U(sizeof(UWORD )))
-#define ALIGNMENT_FUDGE (U(16))
-#define MEM_REQ ( U(4096)*(SIZE_P_BYTE) + ALIGNMENT_FUDGE )
-
-static struct compress_identity identity =
-{
- U(0x032DDEA8), /* Algorithm identification number. */
- MEM_REQ, /* Working memory (bytes) required. */
- "LZRW3", /* Name of algorithm. */
- "1.0", /* Version number of algorithm. */
- "31-Dec-1990", /* Date of algorithm. */
- "Public Domain", /* Copyright notice. */
- "Ross N. Williams", /* Author of algorithm. */
- "Renaissance Software", /* Affiliation of author. */
- "Public Domain" /* Vendor of algorithm. */
-};
-
-LOCAL void compress_compress (UBYTE *,UBYTE *,ULONG,UBYTE *, LONG *);
-LOCAL void compress_decompress(UBYTE *,UBYTE *,LONG, UBYTE *, ULONG *);
-
-/******************************************************************************/
-
-/* This function is the only function exported by this module. */
-/* Depending on its first parameter, the function can be requested to */
-/* compress a block of memory, decompress a block of memory, or to identify */
-/* itself. For more information, see the specification file "compress.h". */
-
-EXPORT void lzrw3_compress(
- UWORD action, /* Action to be performed. */
- UBYTE *wrk_mem, /* Address of working memory we can use.*/
- UBYTE *src_adr, /* Address of input data. */
- LONG src_len, /* Length of input data. */
- UBYTE *dst_adr, /* Address to put output data. */
- void *p_dst_len /* Address of longword for length of output data.*/
-)
-{
- switch (action)
- {
- case COMPRESS_ACTION_IDENTITY:
- *((struct compress_identity **)p_dst_len)= &identity;
- break;
- case COMPRESS_ACTION_COMPRESS:
- compress_compress(wrk_mem,src_adr,src_len,dst_adr,(LONG *)p_dst_len);
- break;
- case COMPRESS_ACTION_DECOMPRESS:
- compress_decompress(wrk_mem,src_adr,src_len,dst_adr,(LONG *)p_dst_len);
- break;
- }
-}
-
-/******************************************************************************/
-/* */
-/* BRIEF DESCRIPTION OF THE LZRW3 ALGORITHM */
-/* ======================================== */
-/* The LZRW3 algorithm is identical to the LZRW1-A algorithm except that */
-/* instead of transmitting history offsets, it transmits hash table indexes. */
-/* In order to decode the indexes, the decompressor must maintain an */
-/* identical hash table. Copy items are straightforward:when the decompressor */
-/* receives a copy item, it simply looks up the hash table to translate the */
-/* index into a pointer into the data already decompressed. To update the */
-/* hash table, it replaces the same table entry with a pointer to the start */
-/* of the newly decoded phrase. The tricky part is with literal items, for at */
-/* the time that the decompressor receives a literal item the decompressor */
-/* does not have the three bytes in the Ziv (that the compressor has) to */
-/* perform the three-byte hash. To solve this problem, in LZRW3, both the */
-/* compressor and decompressor are wired up so that they "buffer" these */
-/* literals and update their hash tables only when three bytes are available. */
-/* This makes the maximum buffering 2 bytes. */
-/* */
-/* Replacement of offsets by hash table indexes yields a few percent extra */
-/* compression at the cost of some speed. LZRW3 is slower than LZRW1, LZRW1-A */
-/* and LZRW2, but yields better compression. */
-/* */
-/* Extra compression could be obtained by using a hash table of depth two. */
-/* However, increasing the depth above one incurs a significant decrease in */
-/* compression speed which was not considered worthwhile. Another reason for */
-/* keeping the depth down to one was to allow easy comparison with the */
-/* LZRW1-A and LZRW2 algorithms so as to demonstrate the exact effect of the */
-/* use of direct hash indexes. */
-/* */
-/* +---+ */
-/* |___|4095 */
-/* |___| */
-/* +---------------------*_|<---+ /----+---\ */
-/* | |___| +---|Hash | */
-/* | |___| |Function| */
-/* | |___| \--------/ */
-/* | |___|0 ^ */
-/* | +---+ | */
-/* | Hash +-----+ */
-/* | Table | */
-/* | --- */
-/* v ^^^ */
-/* +-------------------------------------|----------------+ */
-/* |||||||||||||||||||||||||||||||||||||||||||||||||||||||| */
-/* +-------------------------------------|----------------+ */
-/* | |1......18| | */
-/* |<------- Lempel=History ------------>|<--Ziv-->| | */
-/* | (=bytes already processed) |<-Still to go-->| */
-/* |<-------------------- INPUT BLOCK ------------------->| */
-/* */
-/* The diagram above for LZRW3 looks almost identical to the diagram for */
-/* LZRW1. The difference is that in LZRW3, the compressor transmits hash */
-/* table indices instead of Lempel offsets. For this to work, the */
-/* decompressor must maintain a hash table as well as the compressor and both */
-/* compressor and decompressor must "buffer" literals, as the decompressor */
-/* cannot hash phrases commencing with a literal until another two bytes have */
-/* arrived. */
-/* */
-/* LZRW3 Algorithm Execution Summary */
-/* --------------------------------- */
-/* 1. Hash the first three bytes of the Ziv to yield a hash table index h. */
-/* 2. Look up the hash table yielding history pointer p. */
-/* 3. Match where p points with the Ziv. If there is a match of three or */
-/* more bytes, code those bytes (in the Ziv) as a copy item, otherwise */
-/* code the next byte in the Ziv as a literal item. */
-/* 4. Update the hash table as possible subject to the constraint that only */
-/* phrases commencing three bytes back from the Ziv can be hashed and */
-/* entered into the hash table. (This enables the decompressor to keep */
-/* pace). See the description and code for more details. */
-/* */
-/******************************************************************************/
-/* */
-/* DEFINITION OF COMPRESSED FILE FORMAT */
-/* ==================================== */
-/* * A compressed file consists of a COPY FLAG followed by a REMAINDER. */
-/* * The copy flag CF uses up four bytes with the first byte being the */
-/* least significant. */
-/* * If CF=1, then the compressed file represents the remainder of the file */
-/* exactly. Otherwise CF=0 and the remainder of the file consists of zero */
-/* or more GROUPS, each of which represents one or more bytes. */
-/* * Each group consists of two bytes of CONTROL information followed by */
-/* sixteen ITEMs except for the last group which can contain from one */
-/* to sixteen items. */
-/* * An item can be either a LITERAL item or a COPY item. */
-/* * Each item corresponds to a bit in the control bytes. */
-/* * The first control byte corresponds to the first 8 items in the group */
-/* with bit 0 corresponding to the first item in the group and bit 7 to */
-/* the eighth item in the group. */
-/* * The second control byte corresponds to the second 8 items in the group */
-/* with bit 0 corresponding to the ninth item in the group and bit 7 to */
-/* the sixteenth item in the group. */
-/* * A zero bit in a control word means that the corresponding item is a */
-/* literal item. A one bit corresponds to a copy item. */
-/* * A literal item consists of a single byte which represents itself. */
-/* * A copy item consists of two bytes that represent from 3 to 18 bytes. */
-/* * The first byte in a copy item will be denoted C1. */
-/* * The second byte in a copy item will be denoted C2. */
-/* * Bits will be selected using square brackets. */
-/* For example: C1[0..3] is the low nibble of the first control byte. */
-/* of copy item C1. */
-/* * The LENGTH of a copy item is defined to be C1[0..3]+3 which is a number */
-/* in the range [3,18]. */
-/* * The INDEX of a copy item is defined to be C1[4..7]*256+C2[0..8] which */
-/* is a number in the range [0,4095]. */
-/* * A copy item represents the sequence of bytes */
-/* text[POS-OFFSET..POS-OFFSET+LENGTH-1] where */
-/* text is the entire text of the uncompressed string. */
-/* POS is the index in the text of the character following the */
-/* string represented by all the items preceeding the item */
-/* being defined. */
-/* OFFSET is obtained from INDEX by looking up the hash table. */
-/* */
-/******************************************************************************/
-
-/* The following #define defines the length of the copy flag that appears at */
-/* the start of the compressed file. The value of four bytes was chosen */
-/* because the fast_copy routine on my Macintosh runs faster if the source */
-/* and destination blocks are relatively longword aligned. */
-/* The actual flag data appears in the first byte. The rest are zeroed so as */
-/* to normalize the compressed representation (i.e. not non-deterministic). */
-#define FLAG_BYTES 4
-
-/* The following #defines define the meaning of the values of the copy */
-/* flag at the start of the compressed file. */
-#define FLAG_COMPRESS 0 /* Signals that output was result of compression. */
-#define FLAG_COPY 1 /* Signals that output was simply copied over. */
-
-/* The 68000 microprocessor (on which this algorithm was originally developed */
-/* is fussy about non-aligned arrays of words. To avoid these problems the */
-/* following macro can be used to "waste" from 0 to 3 bytes so as to align */
-/* the argument pointer. */
-#define ULONG_ALIGN_UP(X) ((((ULONG)X)+sizeof(ULONG)-1)&~(sizeof(ULONG)-1))
-
-
-/* The following constant defines the maximum length of an uncompressed item. */
-/* This definition must not be changed; its value is hardwired into the code. */
-/* The longest number of bytes that can be spanned by a single item is 18 */
-/* for the longest copy item. */
-#define MAX_RAW_ITEM (18)
-
-/* The following constant defines the maximum length of an uncompressed group.*/
-/* This definition must not be changed; its value is hardwired into the code. */
-/* A group contains at most 16 items which explains this definition. */
-#define MAX_RAW_GROUP (16*MAX_RAW_ITEM)
-
-/* The following constant defines the maximum length of a compressed group. */
-/* This definition must not be changed; its value is hardwired into the code. */
-/* A compressed group consists of two control bytes followed by up to 16 */
-/* compressed items each of which can have a maximum length of two bytes. */
-#define MAX_CMP_GROUP (2+16*2)
-
-/* The following constant defines the number of entries in the hash table. */
-/* This definition must not be changed; its value is hardwired into the code. */
-#define HASH_TABLE_LENGTH (4096)
-
-/* LZRW3, unlike LZRW1(-A), must initialize its hash table so as to enable */
-/* the compressor and decompressor to stay in step maintaining identical hash */
-/* tables. In an early version of the algorithm, the tables were simply */
-/* initialized to zero and a check for zero was included just before the */
-/* matching code. However, this test costs time. A better solution is to */
-/* initialize all the entries in the hash table to point to a constant */
-/* string. The decompressor does the same. This solution requires no extra */
-/* test. The contents of the string do not matter so long as the string is */
-/* the same for the compressor and decompressor and contains at least */
-/* MAX_RAW_ITEM bytes. I chose consecutive decimal digits because they do not */
-/* have white space problems (e.g. there is no chance that the compiler will */
-/* replace more than one space by a TAB) and because they make the length of */
-/* the string obvious by inspection. */
-#define START_STRING_18 ((UBYTE *) "123456789012345678")
-
-/* In this algorithm, hash values have to be calculated at more than one */
-/* point. The following macro neatens the code up for this. */
-#define HASH(PTR) \
- (((40543*(((*(PTR))<<8)^((*((PTR)+1))<<4)^(*((PTR)+2))))>>4) & 0xFFF)
-
-/******************************************************************************/
-
-/* Input : Hand over the required amount of working memory in p_wrk_mem. */
-/* Input : Specify input block using p_src_first and src_len. */
-/* Input : Point p_dst_first to the start of the output zone (OZ). */
-/* Input : Point p_dst_len to a ULONG to receive the output length. */
-/* Input : Input block and output zone must not overlap. */
-/* Output : Length of output block written to *p_dst_len. */
-/* Output : Output block in Mem[p_dst_first..p_dst_first+*p_dst_len-1]. May */
-/* Output : write in OZ=Mem[p_dst_first..p_dst_first+src_len+MAX_CMP_GROUP-1].*/
-/* Output : Upon completion guaranteed *p_dst_len<=src_len+FLAG_BYTES. */
-LOCAL void compress_compress(UBYTE *p_wrk_mem,
- UBYTE *p_src_first, ULONG src_len,
- UBYTE *p_dst_first, LONG *p_dst_len)
-{
- /* p_src and p_dst step through the source and destination blocks. */
- register UBYTE *p_src = p_src_first;
- register UBYTE *p_dst = p_dst_first;
-
- /* The following variables are never modified and are used in the */
- /* calculations that determine when the main loop terminates. */
- UBYTE *p_src_post = p_src_first+src_len;
- UBYTE *p_dst_post = p_dst_first+src_len;
- UBYTE *p_src_max1 = p_src_first+src_len-MAX_RAW_ITEM;
- UBYTE *p_src_max16 = p_src_first+src_len-MAX_RAW_ITEM*16;
-
- /* The variables 'p_control' and 'control' are used to buffer control bits. */
- /* Before each group is processed, the next two bytes of the output block */
- /* are set aside for the control word for the group about to be processed. */
- /* 'p_control' is set to point to the first byte of that word. Meanwhile, */
- /* 'control' buffers the control bits being generated during the processing */
- /* of the group. Instead of having a counter to keep track of how many items */
- /* have been processed (=the number of bits in the control word), at the */
- /* start of each group, the top word of 'control' is filled with 1 bits. */
- /* As 'control' is shifted for each item, the 1 bits in the top word are */
- /* absorbed or destroyed. When they all run out (i.e. when the top word is */
- /* all zero bits, we know that we are at the end of a group. */
-# define TOPWORD 0xFFFF0000
- UBYTE *p_control;
- register ULONG control=TOPWORD;
-
- /* THe variable 'hash' always points to the first element of the hash table. */
- UBYTE **hash= (UBYTE **) ULONG_ALIGN_UP(p_wrk_mem);
-
- /* The following two variables represent the literal buffer. p_h1 points to */
- /* the hash table entry corresponding to the youngest literal. p_h2 points */
- /* to the hash table entry corresponding to the second youngest literal. */
- /* Note: p_h1=0=>p_h2=0 because zero values denote absence of a pending */
- /* literal. The variables are initialized to zero meaning an empty "buffer". */
- UBYTE **p_h1=NULL;
- UBYTE **p_h2=NULL;
-
- /* To start, we write the flag bytes. Being optimistic, we set the flag to */
- /* FLAG_COMPRESS. The remaining flag bytes are zeroed so as to keep the */
- /* algorithm deterministic. */
- *p_dst++=FLAG_COMPRESS;
- {UWORD i; for (i=2;i<=FLAG_BYTES;i++) *p_dst++=0;}
-
- /* Reserve the first word of output as the control word for the first group. */
- /* Note: This is undone at the end if the input block is empty. */
- p_control=p_dst; p_dst+=2;
-
- /* Initialize all elements of the hash table to point to a constant string. */
- /* Use of an unrolled loop speeds this up considerably. */
- {UWORD i; UBYTE **p_h=hash;
-# define ZH *p_h++=START_STRING_18
- for (i=0;i<256;i++) /* 256=HASH_TABLE_LENGTH/16. */
- {ZH;ZH;ZH;ZH;
- ZH;ZH;ZH;ZH;
- ZH;ZH;ZH;ZH;
- ZH;ZH;ZH;ZH;}
- }
-
- /* The main loop processes either 1 or 16 items per iteration. As its */
- /* termination logic is complicated, I have opted for an infinite loop */
- /* structure containing 'break' and 'goto' statements. */
- while (TRUE)
- {/* Begin main processing loop. */
-
- /* Note: All the variables here except unroll should be defined within */
- /* the inner loop. Unfortunately the loop hasn't got a block. */
- register UBYTE *p; /* Scans through targ phrase during matching. */
- register UBYTE *p_ziv= NULL ; /* Points to first byte of current Ziv. */
- register UWORD unroll; /* Loop counter for unrolled inner loop. */
- register UWORD index; /* Index of current hash table entry. */
- register UBYTE **p_h0 = NULL ; /* Pointer to current hash table entry. */
-
- /* Test for overrun and jump to overrun code if necessary. */
- if (p_dst>p_dst_post)
- goto overrun;
-
- /* The following cascade of if statements efficiently catches and deals */
- /* with varying degrees of closeness to the end of the input block. */
- /* When we get very close to the end, we stop updating the table and */
- /* code the remaining bytes as literals. This makes the code simpler. */
- unroll=16;
- if (p_src>p_src_max16)
- {
- unroll=1;
- if (p_src>p_src_max1)
- {
- if (p_src==p_src_post)
- break;
- else
- goto literal;
- }
- }
-
- /* This inner unrolled loop processes 'unroll' (whose value is either 1 */
- /* or 16) items. I have chosen to implement this loop with labels and */
- /* gotos to heighten the ease with which the loop may be implemented with */
- /* a single decrement and branch instruction in assembly language and */
- /* also because the labels act as highly readable place markers. */
- /* (Also because we jump into the loop for endgame literals (see above)). */
-
- begin_unrolled_loop:
-
- /* To process the next phrase, we hash the next three bytes and use */
- /* the resultant hash table index to look up the hash table. A pointer */
- /* to the entry is stored in p_h0 so as to avoid an array lookup. The */
- /* hash table entry *p_h0 is looked up yielding a pointer p to a */
- /* potential match of the Ziv in the history. */
- index=HASH(p_src);
- p_h0=&hash[index];
- p=*p_h0;
-
- /* Having looked up the candidate position, we are in a position to */
- /* attempt a match. The match loop has been unrolled using the PS */
- /* macro so that failure within the first three bytes automatically */
- /* results in the literal branch being taken. The coding is simple. */
- /* p_ziv saves p_src so we can let p_src wander. */
-# define PS *p++!=*p_src++
- p_ziv=p_src;
- if (PS || PS || PS)
- {
- /* Literal. */
-
- /* Code the literal byte as itself and a zero control bit. */
- p_src=p_ziv; literal: *p_dst++=*p_src++; control&=0xFFFEFFFF;
-
- /* We have just coded a literal. If we had two pending ones, that */
- /* makes three and we can update the hash table. */
- if (p_h2!=0)
- {*p_h2=p_ziv-2;}
-
- /* In any case, rotate the hash table pointers for next time. */
- p_h2=p_h1; p_h1=p_h0;
-
- }
- else
- {
- /* Copy */
-
- /* Match up to 15 remaining bytes using an unrolled loop and code. */
-#if 0
- PS || PS || PS || PS || PS || PS || PS || PS ||
- PS || PS || PS || PS || PS || PS || PS || p_src++;
-#else
- if (
- !( PS || PS || PS || PS || PS || PS || PS || PS ||
- PS || PS || PS || PS || PS || PS || PS )
- ) p_src++;
-#endif
- *p_dst++=((index&0xF00)>>4)|(--p_src-p_ziv-3);
- *p_dst++=index&0xFF;
-
- /* As we have just coded three bytes, we are now in a position to */
- /* update the hash table with the literal bytes that were pending */
- /* upon the arrival of extra context bytes. */
- if (p_h1!=0)
- {
- if (p_h2)
- {*p_h2=p_ziv-2; p_h2=NULL;}
- *p_h1=p_ziv-1; p_h1=NULL;
- }
-
- /* In any case, we can update the hash table based on the current */
- /* position as we just coded at least three bytes in a copy items. */
- *p_h0=p_ziv;
-
- }
- control>>=1;
-
- /* This loop is all set up for a decrement and jump instruction! */
-#ifndef linux
-` end_unrolled_loop: if (--unroll) goto begin_unrolled_loop;
-#else
- /* end_unrolled_loop: */ if (--unroll) goto begin_unrolled_loop;
-#endif
-
- /* At this point it will nearly always be the end of a group in which */
- /* case, we have to do some control-word processing. However, near the */
- /* end of the input block, the inner unrolled loop is only executed once. */
- /* This necessitates the 'if' test. */
- if ((control&TOPWORD)==0)
- {
- /* Write the control word to the place we saved for it in the output. */
- *p_control++= control &0xFF;
- *p_control = (control>>8) &0xFF;
-
- /* Reserve the next word in the output block for the control word */
- /* for the group about to be processed. */
- p_control=p_dst; p_dst+=2;
-
- /* Reset the control bits buffer. */
- control=TOPWORD;
- }
-
- } /* End main processing loop. */
-
- /* After the main processing loop has executed, all the input bytes have */
- /* been processed. However, the control word has still to be written to the */
- /* word reserved for it in the output at the start of the most recent group. */
- /* Before writing, the control word has to be shifted so that all the bits */
- /* are in the right place. The "empty" bit positions are filled with 1s */
- /* which partially fill the top word. */
- while(control&TOPWORD) control>>=1;
- *p_control++= control &0xFF;
- *p_control++=(control>>8) &0xFF;
-
- /* If the last group contained no items, delete the control word too. */
- if (p_control==p_dst) p_dst-=2;
-
- /* Write the length of the output block to the dst_len parameter and return. */
- *p_dst_len=p_dst-p_dst_first;
- return;
-
- /* Jump here as soon as an overrun is detected. An overrun is defined to */
- /* have occurred if p_dst>p_dst_first+src_len. That is, the moment the */
- /* length of the output written so far exceeds the length of the input block.*/
- /* The algorithm checks for overruns at least at the end of each group */
- /* which means that the maximum overrun is MAX_CMP_GROUP bytes. */
- /* Once an overrun occurs, the only thing to do is to set the copy flag and */
- /* copy the input over. */
- overrun:
-#if 0
- *p_dst_first=FLAG_COPY;
- fast_copy(p_src_first,p_dst_first+FLAG_BYTES,src_len);
- *p_dst_len=src_len+FLAG_BYTES;
-#else
- fast_copy(p_src_first,p_dst_first,src_len);
- *p_dst_len= -src_len; /* return a negative number to indicate uncompressed data */
-#endif
-}
-
-/******************************************************************************/
-
-/* Input : Hand over the required amount of working memory in p_wrk_mem. */
-/* Input : Specify input block using p_src_first and src_len. */
-/* Input : Point p_dst_first to the start of the output zone. */
-/* Input : Point p_dst_len to a ULONG to receive the output length. */
-/* Input : Input block and output zone must not overlap. User knows */
-/* Input : upperbound on output block length from earlier compression. */
-/* Input : In any case, maximum expansion possible is nine times. */
-/* Output : Length of output block written to *p_dst_len. */
-/* Output : Output block in Mem[p_dst_first..p_dst_first+*p_dst_len-1]. */
-/* Output : Writes only in Mem[p_dst_first..p_dst_first+*p_dst_len-1]. */
-LOCAL void compress_decompress( UBYTE *p_wrk_mem,
- UBYTE *p_src_first, LONG src_len,
- UBYTE *p_dst_first, ULONG *p_dst_len)
-{
- /* Byte pointers p_src and p_dst scan through the input and output blocks. */
- register UBYTE *p_src = p_src_first+FLAG_BYTES;
- register UBYTE *p_dst = p_dst_first;
- /* we need to avoid a SEGV when trying to uncompress corrupt data */
- register UBYTE *p_dst_post = p_dst_first + *p_dst_len;
-
- /* The following two variables are never modified and are used to control */
- /* the main loop. */
- UBYTE *p_src_post = p_src_first+src_len;
- UBYTE *p_src_max16 = p_src_first+src_len-(MAX_CMP_GROUP-2);
-
- /* The hash table is the only resident of the working memory. The hash table */
- /* contains HASH_TABLE_LENGTH=4096 pointers to positions in the history. To */
- /* keep Macintoshes happy, it is longword aligned. */
- UBYTE **hash = (UBYTE **) ULONG_ALIGN_UP(p_wrk_mem);
-
- /* The variable 'control' is used to buffer the control bits which appear in */
- /* groups of 16 bits (control words) at the start of each compressed group. */
- /* When each group is read, bit 16 of the register is set to one. Whenever */
- /* a new bit is needed, the register is shifted right. When the value of the */
- /* register becomes 1, we know that we have reached the end of a group. */
- /* Initializing the register to 1 thus instructs the code to follow that it */
- /* should read a new control word immediately. */
- register ULONG control=1;
-
- /* The value of 'literals' is always in the range 0..3. It is the number of */
- /* consecutive literal items just seen. We have to record this number so as */
- /* to know when to update the hash table. When literals gets to 3, there */
- /* have been three consecutive literals and we can update at the position of */
- /* the oldest of the three. */
- register UWORD literals=0;
-
- /* Check the leading copy flag to see if the compressor chose to use a copy */
- /* operation instead of a compression operation. If a copy operation was */
- /* used, then all we need to do is copy the data over, set the output length */
- /* and return. */
-#if 0
- if (*p_src_first==FLAG_COPY)
- {
- fast_copy(p_src_first+FLAG_BYTES,p_dst_first,src_len-FLAG_BYTES);
- *p_dst_len=src_len-FLAG_BYTES;
- return;
- }
-#else
- if ( src_len < 0 )
- {
- fast_copy(p_src_first,p_dst_first,-src_len );
- *p_dst_len = (ULONG)-src_len;
- return;
- }
-#endif
-
- /* Initialize all elements of the hash table to point to a constant string. */
- /* Use of an unrolled loop speeds this up considerably. */
- {UWORD i; UBYTE **p_h=hash;
-# define ZJ *p_h++=START_STRING_18
- for (i=0;i<256;i++) /* 256=HASH_TABLE_LENGTH/16. */
- {ZJ;ZJ;ZJ;ZJ;
- ZJ;ZJ;ZJ;ZJ;
- ZJ;ZJ;ZJ;ZJ;
- ZJ;ZJ;ZJ;ZJ;}
- }
-
- /* The outer loop processes either 1 or 16 items per iteration depending on */
- /* how close p_src is to the end of the input block. */
- while (p_src!=p_src_post)
- {/* Start of outer loop */
-
- register UWORD unroll; /* Counts unrolled loop executions. */
-
- /* When 'control' has the value 1, it means that the 16 buffered control */
- /* bits that were read in at the start of the current group have all been */
- /* shifted out and that all that is left is the 1 bit that was injected */
- /* into bit 16 at the start of the current group. When we reach the end */
- /* of a group, we have to load a new control word and inject a new 1 bit. */
- if (control==1)
- {
- control=0x10000|*p_src++;
- control|=(*p_src++)<<8;
- }
-
- /* If it is possible that we are within 16 groups from the end of the */
- /* input, execute the unrolled loop only once, else process a whole group */
- /* of 16 items by looping 16 times. */
- unroll= p_src<=p_src_max16 ? 16 : 1;
-
- /* This inner loop processes one phrase (item) per iteration. */
- while (unroll--)
- { /* Begin unrolled inner loop. */
-
- /* Process a literal or copy item depending on the next control bit. */
- if (control&1)
- {
- /* Copy item. */
-
- register UBYTE *p; /* Points to place from which to copy. */
- register UWORD lenmt; /* Length of copy item minus three. */
- register UBYTE **p_hte; /* Pointer to current hash table entry.*/
- register UBYTE *p_ziv=p_dst; /* Pointer to start of current Ziv. */
-
- /* Read and dismantle the copy word. Work out from where to copy. */
- lenmt=*p_src++;
- p_hte=&hash[((lenmt&0xF0)<<4)|*p_src++];
- p=*p_hte;
- lenmt&=0xF;
-
- /* Now perform the copy using a half unrolled loop. */
- *p_dst++=*p++;
- *p_dst++=*p++;
- *p_dst++=*p++;
- while (lenmt--)
- *p_dst++=*p++;
-
- /* Because we have just received 3 or more bytes in a copy item */
- /* (whose bytes we have just installed in the output), we are now */
- /* in a position to flush all the pending literal hashings that had */
- /* been postponed for lack of bytes. */
- if (literals>0)
- {
- register UBYTE *r=p_ziv-literals;
- hash[HASH(r)]=r;
- if (literals==2)
- {r++; hash[HASH(r)]=r;}
- literals=0;
- }
-
- /* In any case, we can immediately update the hash table with the */
- /* current position. We don't need to do a HASH(...) to work out */
- /* where to put the pointer, as the compressor just told us!!! */
- *p_hte=p_ziv;
-
- }
- else
- {
- /* Literal item. */
-
- /* Copy over the literal byte. */
- *p_dst++=*p_src++;
-
- /* If we now have three literals waiting to be hashed into the hash */
- /* table, we can do one of them now (because there are three). */
- if (++literals == 3)
- {register UBYTE *p=p_dst-3; hash[HASH(p)]=p; literals=2;}
- }
-
- /* Shift the control buffer so the next control bit is in bit 0. */
- control>>=1;
-#if 1
- if (p_dst > p_dst_post)
- {
- /* Shit: we tried to decompress corrupt data */
- *p_dst_len = 0;
- return;
- }
-#endif
- } /* End unrolled inner loop. */
-
- } /* End of outer loop */
-
- /* Write the length of the decompressed data before returning. */
- *p_dst_len=p_dst-p_dst_first;
-}
-
-/******************************************************************************/
-/* End of LZRW3.C */
-/******************************************************************************/