/* * Zlib (RFC1950 / RFC1951) compression for PuTTY. * * There will no doubt be criticism of my decision to reimplement * Zlib compression from scratch instead of using the existing zlib * code. People will cry `reinventing the wheel'; they'll claim * that the `fundamental basis of OSS' is code reuse; they'll want * to see a really good reason for me having chosen not to use the * existing code. * * Well, here are my reasons. Firstly, I don't want to link the * whole of zlib into the PuTTY binary; PuTTY is justifiably proud * of its small size and I think zlib contains a lot of unnecessary * baggage for the kind of compression that SSH requires. * * Secondly, I also don't like the alternative of using zlib.dll. * Another thing PuTTY is justifiably proud of is its ease of * installation, and the last thing I want to do is to start * mandating DLLs. Not only that, but there are two _kinds_ of * zlib.dll kicking around, one with C calling conventions on the * exported functions and another with WINAPI conventions, and * there would be a significant danger of getting the wrong one. * * Thirdly, there seems to be a difference of opinion on the IETF * secsh mailing list about the correct way to round off a * compressed packet and start the next. In particular, there's * some talk of switching to a mechanism zlib isn't currently * capable of supporting (see below for an explanation). Given that * sort of uncertainty, I thought it might be better to have code * that will support even the zlib-incompatible worst case. * * Fourthly, it's a _second implementation_. Second implementations * are fundamentally a Good Thing in standardisation efforts. The * difference of opinion mentioned above has arisen _precisely_ * because there has been only one zlib implementation and * everybody has used it. I don't intend that this should happen * again. */ #include #include #ifdef ZLIB_STANDALONE /* * This module also makes a handy zlib decoding tool for when * you're picking apart Zip files or PDFs or PNGs. If you compile * it with ZLIB_STANDALONE defined, it builds on its own and * becomes a command-line utility. * * Therefore, here I provide a self-contained implementation of the * macros required from the rest of the PuTTY sources. */ #define snew(type) ( (type *) malloc(sizeof(type)) ) #define snewn(n, type) ( (type *) malloc((n) * sizeof(type)) ) #define sresize(x, n, type) ( (type *) realloc((x), (n) * sizeof(type)) ) #define sfree(x) ( free((x)) ) #else #include "ssh.h" #endif #ifndef FALSE #define FALSE 0 #define TRUE (!FALSE) #endif /* ---------------------------------------------------------------------- * Basic LZ77 code. This bit is designed modularly, so it could be * ripped out and used in a different LZ77 compressor. Go to it, * and good luck :-) */ struct LZ77InternalContext; struct LZ77Context { struct LZ77InternalContext *ictx; void *userdata; void (*literal) (struct LZ77Context * ctx, unsigned char c); void (*match) (struct LZ77Context * ctx, int distance, int len); }; /* * Initialise the private fields of an LZ77Context. It's up to the * user to initialise the public fields. */ static int lz77_init(struct LZ77Context *ctx); /* * Supply data to be compressed. Will update the private fields of * the LZ77Context, and will call literal() and match() to output. * If `compress' is FALSE, it will never emit a match, but will * instead call literal() for everything. */ static void lz77_compress(struct LZ77Context *ctx, unsigned char *data, int len, int compress); /* * Modifiable parameters. */ #define WINSIZE 32768 /* window size. Must be power of 2! */ #define HASHMAX 2039 /* one more than max hash value */ #define MAXMATCH 32 /* how many matches we track */ #define HASHCHARS 3 /* how many chars make a hash */ /* * This compressor takes a less slapdash approach than the * gzip/zlib one. Rather than allowing our hash chains to fall into * disuse near the far end, we keep them doubly linked so we can * _find_ the far end, and then every time we add a new byte to the * window (thus rolling round by one and removing the previous * byte), we can carefully remove the hash chain entry. */ #define INVALID -1 /* invalid hash _and_ invalid offset */ struct WindowEntry { short next, prev; /* array indices within the window */ short hashval; }; struct HashEntry { short first; /* window index of first in chain */ }; struct Match { int distance, len; }; struct LZ77InternalContext { struct WindowEntry win[WINSIZE]; unsigned char data[WINSIZE]; int winpos; struct HashEntry hashtab[HASHMAX]; unsigned char pending[HASHCHARS]; int npending; }; static int lz77_hash(unsigned char *data) { return (257 * data[0] + 263 * data[1] + 269 * data[2]) % HASHMAX; } static int lz77_init(struct LZ77Context *ctx) { struct LZ77InternalContext *st; int i; st = snew(struct LZ77InternalContext); if (!st) return 0; ctx->ictx = st; for (i = 0; i < WINSIZE; i++) st->win[i].next = st->win[i].prev = st->win[i].hashval = INVALID; for (i = 0; i < HASHMAX; i++) st->hashtab[i].first = INVALID; st->winpos = 0; st->npending = 0; return 1; } static void lz77_advance(struct LZ77InternalContext *st, unsigned char c, int hash) { int off; /* * Remove the hash entry at winpos from the tail of its chain, * or empty the chain if it's the only thing on the chain. */ if (st->win[st->winpos].prev != INVALID) { st->win[st->win[st->winpos].prev].next = INVALID; } else if (st->win[st->winpos].hashval != INVALID) { st->hashtab[st->win[st->winpos].hashval].first = INVALID; } /* * Create a new entry at winpos and add it to the head of its * hash chain. */ st->win[st->winpos].hashval = hash; st->win[st->winpos].prev = INVALID; off = st->win[st->winpos].next = st->hashtab[hash].first; st->hashtab[hash].first = st->winpos; if (off != INVALID) st->win[off].prev = st->winpos; st->data[st->winpos] = c; /* * Advance the window pointer. */ st->winpos = (st->winpos + 1) & (WINSIZE - 1); } #define CHARAT(k) ( (k)<0 ? st->data[(st->winpos+k)&(WINSIZE-1)] : data[k] ) static void lz77_compress(struct LZ77Context *ctx, unsigned char *data, int len, int compress) { struct LZ77InternalContext *st = ctx->ictx; int i, hash, distance, off, nmatch, matchlen, advance; struct Match defermatch, matches[MAXMATCH]; int deferchr; /* * Add any pending characters from last time to the window. (We * might not be able to.) */ for (i = 0; i < st->npending; i++) { unsigned char foo[HASHCHARS]; int j; if (len + st->npending - i < HASHCHARS) { /* Update the pending array. */ for (j = i; j < st->npending; j++) st->pending[j - i] = st->pending[j]; break; } for (j = 0; j < HASHCHARS; j++) foo[j] = (i + j < st->npending ? st->pending[i + j] : data[i + j - st->npending]); lz77_advance(st, foo[0], lz77_hash(foo)); } st->npending -= i; defermatch.distance = 0; /* appease compiler */ defermatch.len = 0; deferchr = '\0'; while (len > 0) { /* Don't even look for a match, if we're not compressing. */ if (compress && len >= HASHCHARS) { /* * Hash the next few characters. */ hash = lz77_hash(data); /* * Look the hash up in the corresponding hash chain and see * what we can find. */ nmatch = 0; for (off = st->hashtab[hash].first; off != INVALID; off = st->win[off].next) { /* distance = 1 if off == st->winpos-1 */ /* distance = WINSIZE if off == st->winpos */ distance = WINSIZE - (off + WINSIZE - st->winpos) % WINSIZE; for (i = 0; i < HASHCHARS; i++) if (CHARAT(i) != CHARAT(i - distance)) break; if (i == HASHCHARS) { matches[nmatch].distance = distance; matches[nmatch].len = 3; if (++nmatch >= MAXMATCH) break; } } } else { nmatch = 0; hash = INVALID; } if (nmatch > 0) { /* * We've now filled up matches[] with nmatch potential * matches. Follow them down to find the longest. (We * assume here that it's always worth favouring a * longer match over a shorter one.) */ matchlen = HASHCHARS; while (matchlen < len) { int j; for (i = j = 0; i < nmatch; i++) { if (CHARAT(matchlen) == CHARAT(matchlen - matches[i].distance)) { matches[j++] = matches[i]; } } if (j == 0) break; matchlen++; nmatch = j; } /* * We've now got all the longest matches. We favour the * shorter distances, which means we go with matches[0]. * So see if we want to defer it or throw it away. */ matches[0].len = matchlen; if (defermatch.len > 0) { if (matches[0].len > defermatch.len + 1) { /* We have a better match. Emit the deferred char, * and defer this match. */ ctx->literal(ctx, (unsigned char) deferchr); defermatch = matches[0]; deferchr = data[0]; advance = 1; } else { /* We don't have a better match. Do the deferred one. */ ctx->match(ctx, defermatch.distance, defermatch.len); advance = defermatch.len - 1; defermatch.len = 0; } } else { /* There was no deferred match. Defer this one. */ defermatch = matches[0]; deferchr = data[0]; advance = 1; } } else { /* * We found no matches. Emit the deferred match, if * any; otherwise emit a literal. */ if (defermatch.len > 0) { ctx->match(ctx, defermatch.distance, defermatch.len); advance = defermatch.len - 1; defermatch.len = 0; } else { ctx->literal(ctx, data[0]); advance = 1; } } /* * Now advance the position by `advance' characters, * keeping the window and hash chains consistent. */ while (advance > 0) { if (len >= HASHCHARS) { lz77_advance(st, *data, lz77_hash(data)); } else { st->pending[st->npending++] = *data; } data++; len--; advance--; } } } /* ---------------------------------------------------------------------- * Zlib compression. We always use the static Huffman tree option. * Mostly this is because it's hard to scan a block in advance to * work out better trees; dynamic trees are great when you're * compressing a large file under no significant time constraint, * but when you're compressing little bits in real time, things get * hairier. * * I suppose it's possible that I could compute Huffman trees based * on the frequencies in the _previous_ block, as a sort of * heuristic, but I'm not confident that the gain would balance out * having to transmit the trees. */ struct Outbuf { unsigned char *outbuf; int outlen, outsize; unsigned long outbits; int noutbits; int firstblock; int comp_disabled; }; static void outbits(struct Outbuf *out, unsigned long bits, int nbits) { assert(out->noutbits + nbits <= 32); out->outbits |= bits << out->noutbits; out->noutbits += nbits; while (out->noutbits >= 8) { if (out->outlen >= out->outsize) { out->outsize = out->outlen + 64; out->outbuf = sresize(out->outbuf, out->outsize, unsigned char); } out->outbuf[out->outlen++] = (unsigned char) (out->outbits & 0xFF); out->outbits >>= 8; out->noutbits -= 8; } } static const unsigned char mirrorbytes[256] = { 0x00, 0x80, 0x40, 0xc0, 0x20, 0xa0, 0x60, 0xe0, 0x10, 0x90, 0x50, 0xd0, 0x30, 0xb0, 0x70, 0xf0, 0x08, 0x88, 0x48, 0xc8, 0x28, 0xa8, 0x68, 0xe8, 0x18, 0x98, 0x58, 0xd8, 0x38, 0xb8, 0x78, 0xf8, 0x04, 0x84, 0x44, 0xc4, 0x24, 0xa4, 0x64, 0xe4, 0x14, 0x94, 0x54, 0xd4, 0x34, 0xb4, 0x74, 0xf4, 0x0c, 0x8c, 0x4c, 0xcc, 0x2c, 0xac, 0x6c, 0xec, 0x1c, 0x9c, 0x5c, 0xdc, 0x3c, 0xbc, 0x7c, 0xfc, 0x02, 0x82, 0x42, 0xc2, 0x22, 0xa2, 0x62, 0xe2, 0x12, 0x92, 0x52, 0xd2, 0x32, 0xb2, 0x72, 0xf2, 0x0a, 0x8a, 0x4a, 0xca, 0x2a, 0xaa, 0x6a, 0xea, 0x1a, 0x9a, 0x5a, 0xda, 0x3a, 0xba, 0x7a, 0xfa, 0x06, 0x86, 0x46, 0xc6, 0x26, 0xa6, 0x66, 0xe6, 0x16, 0x96, 0x56, 0xd6, 0x36, 0xb6, 0x76, 0xf6, 0x0e, 0x8e, 0x4e, 0xce, 0x2e, 0xae, 0x6e, 0xee, 0x1e, 0x9e, 0x5e, 0xde, 0x3e, 0xbe, 0x7e, 0xfe, 0x01, 0x81, 0x41, 0xc1, 0x21, 0xa1, 0x61, 0xe1, 0x11, 0x91, 0x51, 0xd1, 0x31, 0xb1, 0x71, 0xf1, 0x09, 0x89, 0x49, 0xc9, 0x29, 0xa9, 0x69, 0xe9, 0x19, 0x99, 0x59, 0xd9, 0x39, 0xb9, 0x79, 0xf9, 0x05, 0x85, 0x45, 0xc5, 0x25, 0xa5, 0x65, 0xe5, 0x15, 0x95, 0x55, 0xd5, 0x35, 0xb5, 0x75, 0xf5, 0x0d, 0x8d, 0x4d, 0xcd, 0x2d, 0xad, 0x6d, 0xed, 0x1d, 0x9d, 0x5d, 0xdd, 0x3d, 0xbd, 0x7d, 0xfd, 0x03, 0x83, 0x43, 0xc3, 0x23, 0xa3, 0x63, 0xe3, 0x13, 0x93, 0x53, 0xd3, 0x33, 0xb3, 0x73, 0xf3, 0x0b, 0x8b, 0x4b, 0xcb, 0x2b, 0xab, 0x6b, 0xeb, 0x1b, 0x9b, 0x5b, 0xdb, 0x3b, 0xbb, 0x7b, 0xfb, 0x07, 0x87, 0x47, 0xc7, 0x27, 0xa7, 0x67, 0xe7, 0x17, 0x97, 0x57, 0xd7, 0x37, 0xb7, 0x77, 0xf7, 0x0f, 0x8f, 0x4f, 0xcf, 0x2f, 0xaf, 0x6f, 0xef, 0x1f, 0x9f, 0x5f, 0xdf, 0x3f, 0xbf, 0x7f, 0xff, }; typedef struct { short code, extrabits; int min, max; } coderecord; static const coderecord lencodes[] = { {257, 0, 3, 3}, {258, 0, 4, 4}, {259, 0, 5, 5}, {260, 0, 6, 6}, {261, 0, 7, 7}, {262, 0, 8, 8}, {263, 0, 9, 9}, {264, 0, 10, 10}, {265, 1, 11, 12}, {266, 1, 13, 14}, {267, 1, 15, 16}, {268, 1, 17, 18}, {269, 2, 19, 22}, {270, 2, 23, 26}, {271, 2, 27, 30}, {272, 2, 31, 34}, {273, 3, 35, 42}, {274, 3, 43, 50}, {275, 3, 51, 58}, {276, 3, 59, 66}, {277, 4, 67, 82}, {278, 4, 83, 98}, {279, 4, 99, 114}, {280, 4, 115, 130}, {281, 5, 131, 162}, {282, 5, 163, 194}, {283, 5, 195, 226}, {284, 5, 227, 257}, {285, 0, 258, 258}, }; static const coderecord distcodes[] = { {0, 0, 1, 1}, {1, 0, 2, 2}, {2, 0, 3, 3}, {3, 0, 4, 4}, {4, 1, 5, 6}, {5, 1, 7, 8}, {6, 2, 9, 12}, {7, 2, 13, 16}, {8, 3, 17, 24}, {9, 3, 25, 32}, {10, 4, 33, 48}, {11, 4, 49, 64}, {12, 5, 65, 96}, {13, 5, 97, 128}, {14, 6, 129, 192}, {15, 6, 193, 256}, {16, 7, 257, 384}, {17, 7, 385, 512}, {18, 8, 513, 768}, {19, 8, 769, 1024}, {20, 9, 1025, 1536}, {21, 9, 1537, 2048}, {22, 10, 2049, 3072}, {23, 10, 3073, 4096}, {24, 11, 4097, 6144}, {25, 11, 6145, 8192}, {26, 12, 8193, 12288}, {27, 12, 12289, 16384}, {28, 13, 16385, 24576}, {29, 13, 24577, 32768}, }; static void zlib_literal(struct LZ77Context *ectx, unsigned char c) { struct Outbuf *out = (struct Outbuf *) ectx->userdata; if (out->comp_disabled) { /* * We're in an uncompressed block, so just output the byte. */ outbits(out, c, 8); return; } if (c <= 143) { /* 0 through 143 are 8 bits long starting at 00110000. */ outbits(out, mirrorbytes[0x30 + c], 8); } else { /* 144 through 255 are 9 bits long starting at 110010000. */ outbits(out, 1 + 2 * mirrorbytes[0x90 - 144 + c], 9); } } static void zlib_match(struct LZ77Context *ectx, int distance, int len) { const coderecord *d, *l; int i, j, k; struct Outbuf *out = (struct Outbuf *) ectx->userdata; assert(!out->comp_disabled); while (len > 0) { int thislen; /* * We can transmit matches of lengths 3 through 258 * inclusive. So if len exceeds 258, we must transmit in * several steps, with 258 or less in each step. * * Specifically: if len >= 261, we can transmit 258 and be * sure of having at least 3 left for the next step. And if * len <= 258, we can just transmit len. But if len == 259 * or 260, we must transmit len-3. */ thislen = (len > 260 ? 258 : len <= 258 ? len : len - 3); len -= thislen; /* * Binary-search to find which length code we're * transmitting. */ i = -1; j = sizeof(lencodes) / sizeof(*lencodes); while (1) { assert(j - i >= 2); k = (j + i) / 2; if (thislen < lencodes[k].min) j = k; else if (thislen > lencodes[k].max) i = k; else { l = &lencodes[k]; break; /* found it! */ } } /* * Transmit the length code. 256-279 are seven bits * starting at 0000000; 280-287 are eight bits starting at * 11000000. */ if (l->code <= 279) { outbits(out, mirrorbytes[(l->code - 256) * 2], 7); } else { outbits(out, mirrorbytes[0xc0 - 280 + l->code], 8); } /* * Transmit the extra bits. */ if (l->extrabits) outbits(out, thislen - l->min, l->extrabits); /* * Binary-search to find which distance code we're * transmitting. */ i = -1; j = sizeof(distcodes) / sizeof(*distcodes); while (1) { assert(j - i >= 2); k = (j + i) / 2; if (distance < distcodes[k].min) j = k; else if (distance > distcodes[k].max) i = k; else { d = &distcodes[k]; break; /* found it! */ } } /* * Transmit the distance code. Five bits starting at 00000. */ outbits(out, mirrorbytes[d->code * 8], 5); /* * Transmit the extra bits. */ if (d->extrabits) outbits(out, distance - d->min, d->extrabits); } } void *zlib_compress_init(void) { struct Outbuf *out; struct LZ77Context *ectx = snew(struct LZ77Context); lz77_init(ectx); ectx->literal = zlib_literal; ectx->match = zlib_match; out = snew(struct Outbuf); out->outbits = out->noutbits = 0; out->firstblock = 1; out->comp_disabled = FALSE; ectx->userdata = out; return ectx; } void zlib_compress_cleanup(void *handle) { struct LZ77Context *ectx = (struct LZ77Context *)handle; sfree(ectx->userdata); sfree(ectx->ictx); sfree(ectx); } /* * Turn off actual LZ77 analysis for one block, to facilitate * construction of a precise-length IGNORE packet. Returns the * length adjustment (which is only valid for packets < 65536 * bytes, but that seems reasonable enough). */ static int zlib_disable_compression(void *handle) { struct LZ77Context *ectx = (struct LZ77Context *)handle; struct Outbuf *out = (struct Outbuf *) ectx->userdata; int n; out->comp_disabled = TRUE; n = 0; /* * If this is the first block, we will start by outputting two * header bytes, and then three bits to begin an uncompressed * block. This will cost three bytes (because we will start on * a byte boundary, this is certain). */ if (out->firstblock) { n = 3; } else { /* * Otherwise, we will output seven bits to close the * previous static block, and _then_ three bits to begin an * uncompressed block, and then flush the current byte. * This may cost two bytes or three, depending on noutbits. */ n += (out->noutbits + 10) / 8; } /* * Now we output four bytes for the length / ~length pair in * the uncompressed block. */ n += 4; return n; } int zlib_compress_block(void *handle, unsigned char *block, int len, unsigned char **outblock, int *outlen) { struct LZ77Context *ectx = (struct LZ77Context *)handle; struct Outbuf *out = (struct Outbuf *) ectx->userdata; int in_block; out->outbuf = NULL; out->outlen = out->outsize = 0; /* * If this is the first block, output the Zlib (RFC1950) header * bytes 78 9C. (Deflate compression, 32K window size, default * algorithm.) */ if (out->firstblock) { outbits(out, 0x9C78, 16); out->firstblock = 0; in_block = FALSE; } else in_block = TRUE; if (out->comp_disabled) { if (in_block) outbits(out, 0, 7); /* close static block */ while (len > 0) { int blen = (len < 65535 ? len : 65535); /* * Start a Deflate (RFC1951) uncompressed block. We * transmit a zero bit (BFINAL=0), followed by two more * zero bits (BTYPE=00). Of course these are in the * wrong order (00 0), not that it matters. */ outbits(out, 0, 3); /* * Output zero bits to align to a byte boundary. */ if (out->noutbits) outbits(out, 0, 8 - out->noutbits); /* * Output the block length, and then its one's * complement. They're little-endian, so all we need to * do is pass them straight to outbits() with bit count * 16. */ outbits(out, blen, 16); outbits(out, blen ^ 0xFFFF, 16); /* * Do the `compression': we need to pass the data to * lz77_compress so that it will be taken into account * for subsequent (distance,length) pairs. But * lz77_compress is passed FALSE, which means it won't * actually find (or even look for) any matches; so * every character will be passed straight to * zlib_literal which will spot out->comp_disabled and * emit in the uncompressed format. */ lz77_compress(ectx, block, blen, FALSE); len -= blen; block += blen; } outbits(out, 2, 3); /* open new block */ } else { if (!in_block) { /* * Start a Deflate (RFC1951) fixed-trees block. We * transmit a zero bit (BFINAL=0), followed by a zero * bit and a one bit (BTYPE=01). Of course these are in * the wrong order (01 0). */ outbits(out, 2, 3); } /* * Do the compression. */ lz77_compress(ectx, block, len, TRUE); /* * End the block (by transmitting code 256, which is * 0000000 in fixed-tree mode), and transmit some empty * blocks to ensure we have emitted the byte containing the * last piece of genuine data. There are three ways we can * do this: * * - Minimal flush. Output end-of-block and then open a * new static block. This takes 9 bits, which is * guaranteed to flush out the last genuine code in the * closed block; but allegedly zlib can't handle it. * * - Zlib partial flush. Output EOB, open and close an * empty static block, and _then_ open the new block. * This is the best zlib can handle. * * - Zlib sync flush. Output EOB, then an empty * _uncompressed_ block (000, then sync to byte * boundary, then send bytes 00 00 FF FF). Then open the * new block. * * For the moment, we will use Zlib partial flush. */ outbits(out, 0, 7); /* close block */ outbits(out, 2, 3 + 7); /* empty static block */ outbits(out, 2, 3); /* open new block */ } out->comp_disabled = FALSE; *outblock = out->outbuf; *outlen = out->outlen; return 1; } /* ---------------------------------------------------------------------- * Zlib decompression. Of course, even though our compressor always * uses static trees, our _decompressor_ has to be capable of * handling dynamic trees if it sees them. */ /* * The way we work the Huffman decode is to have a table lookup on * the first N bits of the input stream (in the order they arrive, * of course, i.e. the first bit of the Huffman code is in bit 0). * Each table entry lists the number of bits to consume, plus * either an output code or a pointer to a secondary table. */ struct zlib_table; struct zlib_tableentry; struct zlib_tableentry { unsigned char nbits; short code; struct zlib_table *nexttable; }; struct zlib_table { int mask; /* mask applied to input bit stream */ struct zlib_tableentry *table; }; #define MAXCODELEN 16 #define MAXSYMS 288 /* * Build a single-level decode table for elements * [minlength,maxlength) of the provided code/length tables, and * recurse to build subtables. */ static struct zlib_table *zlib_mkonetab(int *codes, unsigned char *lengths, int nsyms, int pfx, int pfxbits, int bits) { struct zlib_table *tab = snew(struct zlib_table); int pfxmask = (1 << pfxbits) - 1; int nbits, i, j, code; tab->table = snewn(1 << bits, struct zlib_tableentry); tab->mask = (1 << bits) - 1; for (code = 0; code <= tab->mask; code++) { tab->table[code].code = -1; tab->table[code].nbits = 0; tab->table[code].nexttable = NULL; } for (i = 0; i < nsyms; i++) { if (lengths[i] <= pfxbits || (codes[i] & pfxmask) != pfx) continue; code = (codes[i] >> pfxbits) & tab->mask; for (j = code; j <= tab->mask; j += 1 << (lengths[i] - pfxbits)) { tab->table[j].code = i; nbits = lengths[i] - pfxbits; if (tab->table[j].nbits < nbits) tab->table[j].nbits = nbits; } } for (code = 0; code <= tab->mask; code++) { if (tab->table[code].nbits <= bits) continue; /* Generate a subtable. */ tab->table[code].code = -1; nbits = tab->table[code].nbits - bits; if (nbits > 7) nbits = 7; tab->table[code].nbits = bits; tab->table[code].nexttable = zlib_mkonetab(codes, lengths, nsyms, pfx | (code << pfxbits), pfxbits + bits, nbits); } return tab; } /* * Build a decode table, given a set of Huffman tree lengths. */ static struct zlib_table *zlib_mktable(unsigned char *lengths, int nlengths) { int count[MAXCODELEN], startcode[MAXCODELEN], codes[MAXSYMS]; int code, maxlen; int i, j; /* Count the codes of each length. */ maxlen = 0; for (i = 1; i < MAXCODELEN; i++) count[i] = 0; for (i = 0; i < nlengths; i++) { count[lengths[i]]++; if (maxlen < lengths[i]) maxlen = lengths[i]; } /* Determine the starting code for each length block. */ code = 0; for (i = 1; i < MAXCODELEN; i++) { startcode[i] = code; code += count[i]; code <<= 1; } /* Determine the code for each symbol. Mirrored, of course. */ for (i = 0; i < nlengths; i++) { code = startcode[lengths[i]]++; codes[i] = 0; for (j = 0; j < lengths[i]; j++) { codes[i] = (codes[i] << 1) | (code & 1); code >>= 1; } } /* * Now we have the complete list of Huffman codes. Build a * table. */ return zlib_mkonetab(codes, lengths, nlengths, 0, 0, maxlen < 9 ? maxlen : 9); } static int zlib_freetable(struct zlib_table **ztab) { struct zlib_table *tab; int code; if (ztab == NULL) return -1; if (*ztab == NULL) return 0; tab = *ztab; for (code = 0; code <= tab->mask; code++) if (tab->table[code].nexttable != NULL) zlib_freetable(&tab->table[code].nexttable); sfree(tab->table); tab->table = NULL; sfree(tab); *ztab = NULL; return (0); } struct zlib_decompress_ctx { struct zlib_table *staticlentable, *staticdisttable; struct zlib_table *currlentable, *currdisttable, *lenlentable; enum { START, OUTSIDEBLK, TREES_HDR, TREES_LENLEN, TREES_LEN, TREES_LENREP, INBLK, GOTLENSYM, GOTLEN, GOTDISTSYM, UNCOMP_LEN, UNCOMP_NLEN, UNCOMP_DATA } state; int sym, hlit, hdist, hclen, lenptr, lenextrabits, lenaddon, len, lenrep; int uncomplen; unsigned char lenlen[19]; unsigned char lengths[286 + 32]; unsigned long bits; int nbits; unsigned char window[WINSIZE]; int winpos; unsigned char *outblk; int outlen, outsize; }; void *zlib_decompress_init(void) { struct zlib_decompress_ctx *dctx = snew(struct zlib_decompress_ctx); unsigned char lengths[288]; memset(lengths, 8, 144); memset(lengths + 144, 9, 256 - 144); memset(lengths + 256, 7, 280 - 256); memset(lengths + 280, 8, 288 - 280); dctx->staticlentable = zlib_mktable(lengths, 288); memset(lengths, 5, 32); dctx->staticdisttable = zlib_mktable(lengths, 32); dctx->state = START; /* even before header */ dctx->currlentable = dctx->currdisttable = dctx->lenlentable = NULL; dctx->bits = 0; dctx->nbits = 0; dctx->winpos = 0; return dctx; } void zlib_decompress_cleanup(void *handle) { struct zlib_decompress_ctx *dctx = (struct zlib_decompress_ctx *)handle; if (dctx->currlentable && dctx->currlentable != dctx->staticlentable) zlib_freetable(&dctx->currlentable); if (dctx->currdisttable && dctx->currdisttable != dctx->staticdisttable) zlib_freetable(&dctx->currdisttable); if (dctx->lenlentable) zlib_freetable(&dctx->lenlentable); zlib_freetable(&dctx->staticlentable); zlib_freetable(&dctx->staticdisttable); sfree(dctx); } static int zlib_huflookup(unsigned long *bitsp, int *nbitsp, struct zlib_table *tab) { unsigned long bits = *bitsp; int nbits = *nbitsp; while (1) { struct zlib_tableentry *ent; ent = &tab->table[bits & tab->mask]; if (ent->nbits > nbits) return -1; /* not enough data */ bits >>= ent->nbits; nbits -= ent->nbits; if (ent->code == -1) tab = ent->nexttable; else { *bitsp = bits; *nbitsp = nbits; return ent->code; } if (!tab) { /* * There was a missing entry in the table, presumably * due to an invalid Huffman table description, and the * subsequent data has attempted to use the missing * entry. Return a decoding failure. */ return -2; } } } static void zlib_emit_char(struct zlib_decompress_ctx *dctx, int c) { dctx->window[dctx->winpos] = c; dctx->winpos = (dctx->winpos + 1) & (WINSIZE - 1); if (dctx->outlen >= dctx->outsize) { dctx->outsize = dctx->outlen + 512; dctx->outblk = sresize(dctx->outblk, dctx->outsize, unsigned char); } dctx->outblk[dctx->outlen++] = c; } #define EATBITS(n) ( dctx->nbits -= (n), dctx->bits >>= (n) ) int zlib_decompress_block(void *handle, unsigned char *block, int len, unsigned char **outblock, int *outlen) { struct zlib_decompress_ctx *dctx = (struct zlib_decompress_ctx *)handle; const coderecord *rec; int code, blktype, rep, dist, nlen, header; static const unsigned char lenlenmap[] = { 16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15 }; dctx->outblk = snewn(256, unsigned char); dctx->outsize = 256; dctx->outlen = 0; while (len > 0 || dctx->nbits > 0) { while (dctx->nbits < 24 && len > 0) { dctx->bits |= (*block++) << dctx->nbits; dctx->nbits += 8; len--; } switch (dctx->state) { case START: /* Expect 16-bit zlib header. */ if (dctx->nbits < 16) goto finished; /* done all we can */ /* * The header is stored as a big-endian 16-bit integer, * in contrast to the general little-endian policy in * the rest of the format :-( */ header = (((dctx->bits & 0xFF00) >> 8) | ((dctx->bits & 0x00FF) << 8)); EATBITS(16); /* * Check the header: * * - bits 8-11 should be 1000 (Deflate/RFC1951) * - bits 12-15 should be at most 0111 (window size) * - bit 5 should be zero (no dictionary present) * - we don't care about bits 6-7 (compression rate) * - bits 0-4 should be set up to make the whole thing * a multiple of 31 (checksum). */ if ((header & 0x0F00) != 0x0800 || (header & 0xF000) > 0x7000 || (header & 0x0020) != 0x0000 || (header % 31) != 0) goto decode_error; dctx->state = OUTSIDEBLK; break; case OUTSIDEBLK: /* Expect 3-bit block header. */ if (dctx->nbits < 3) goto finished; /* done all we can */ EATBITS(1); blktype = dctx->bits & 3; EATBITS(2); if (blktype == 0) { int to_eat = dctx->nbits & 7; dctx->state = UNCOMP_LEN; EATBITS(to_eat); /* align to byte boundary */ } else if (blktype == 1) { dctx->currlentable = dctx->staticlentable; dctx->currdisttable = dctx->staticdisttable; dctx->state = INBLK; } else if (blktype == 2) { dctx->state = TREES_HDR; } break; case TREES_HDR: /* * Dynamic block header. Five bits of HLIT, five of * HDIST, four of HCLEN. */ if (dctx->nbits < 5 + 5 + 4) goto finished; /* done all we can */ dctx->hlit = 257 + (dctx->bits & 31); EATBITS(5); dctx->hdist = 1 + (dctx->bits & 31); EATBITS(5); dctx->hclen = 4 + (dctx->bits & 15); EATBITS(4); dctx->lenptr = 0; dctx->state = TREES_LENLEN; memset(dctx->lenlen, 0, sizeof(dctx->lenlen)); break; case TREES_LENLEN: if (dctx->nbits < 3) goto finished; while (dctx->lenptr < dctx->hclen && dctx->nbits >= 3) { dctx->lenlen[lenlenmap[dctx->lenptr++]] = (unsigned char) (dctx->bits & 7); EATBITS(3); } if (dctx->lenptr == dctx->hclen) { dctx->lenlentable = zlib_mktable(dctx->lenlen, 19); dctx->state = TREES_LEN; dctx->lenptr = 0; } break; case TREES_LEN: if (dctx->lenptr >= dctx->hlit + dctx->hdist) { dctx->currlentable = zlib_mktable(dctx->lengths, dctx->hlit); dctx->currdisttable = zlib_mktable(dctx->lengths + dctx->hlit, dctx->hdist); zlib_freetable(&dctx->lenlentable); dctx->lenlentable = NULL; dctx->state = INBLK; break; } code = zlib_huflookup(&dctx->bits, &dctx->nbits, dctx->lenlentable); if (code == -1) goto finished; if (code == -2) goto decode_error; if (code < 16) dctx->lengths[dctx->lenptr++] = code; else { dctx->lenextrabits = (code == 16 ? 2 : code == 17 ? 3 : 7); dctx->lenaddon = (code == 18 ? 11 : 3); dctx->lenrep = (code == 16 && dctx->lenptr > 0 ? dctx->lengths[dctx->lenptr - 1] : 0); dctx->state = TREES_LENREP; } break; case TREES_LENREP: if (dctx->nbits < dctx->lenextrabits) goto finished; rep = dctx->lenaddon + (dctx->bits & ((1 << dctx->lenextrabits) - 1)); EATBITS(dctx->lenextrabits); while (rep > 0 && dctx->lenptr < dctx->hlit + dctx->hdist) { dctx->lengths[dctx->lenptr] = dctx->lenrep; dctx->lenptr++; rep--; } dctx->state = TREES_LEN; break; case INBLK: code = zlib_huflookup(&dctx->bits, &dctx->nbits, dctx->currlentable); if (code == -1) goto finished; if (code == -2) goto decode_error; if (code < 256) zlib_emit_char(dctx, code); else if (code == 256) { dctx->state = OUTSIDEBLK; if (dctx->currlentable != dctx->staticlentable) { zlib_freetable(&dctx->currlentable); dctx->currlentable = NULL; } if (dctx->currdisttable != dctx->staticdisttable) { zlib_freetable(&dctx->currdisttable); dctx->currdisttable = NULL; } } else if (code < 286) { /* static tree can give >285; ignore */ dctx->state = GOTLENSYM; dctx->sym = code; } break; case GOTLENSYM: rec = &lencodes[dctx->sym - 257]; if (dctx->nbits < rec->extrabits) goto finished; dctx->len = rec->min + (dctx->bits & ((1 << rec->extrabits) - 1)); EATBITS(rec->extrabits); dctx->state = GOTLEN; break; case GOTLEN: code = zlib_huflookup(&dctx->bits, &dctx->nbits, dctx->currdisttable); if (code == -1) goto finished; if (code == -2) goto decode_error; dctx->state = GOTDISTSYM; dctx->sym = code; break; case GOTDISTSYM: rec = &distcodes[dctx->sym]; if (dctx->nbits < rec->extrabits) goto finished; dist = rec->min + (dctx->bits & ((1 << rec->extrabits) - 1)); EATBITS(rec->extrabits); dctx->state = INBLK; while (dctx->len--) zlib_emit_char(dctx, dctx->window[(dctx->winpos - dist) & (WINSIZE - 1)]); break; case UNCOMP_LEN: /* * Uncompressed block. We expect to see a 16-bit LEN. */ if (dctx->nbits < 16) goto finished; dctx->uncomplen = dctx->bits & 0xFFFF; EATBITS(16); dctx->state = UNCOMP_NLEN; break; case UNCOMP_NLEN: /* * Uncompressed block. We expect to see a 16-bit NLEN, * which should be the one's complement of the previous * LEN. */ if (dctx->nbits < 16) goto finished; nlen = dctx->bits & 0xFFFF; EATBITS(16); if (dctx->uncomplen == 0) dctx->state = OUTSIDEBLK; /* block is empty */ else dctx->state = UNCOMP_DATA; break; case UNCOMP_DATA: if (dctx->nbits < 8) goto finished; zlib_emit_char(dctx, dctx->bits & 0xFF); EATBITS(8); if (--dctx->uncomplen == 0) dctx->state = OUTSIDEBLK; /* end of uncompressed block */ break; } } finished: *outblock = dctx->outblk; *outlen = dctx->outlen; return 1; decode_error: sfree(dctx->outblk); *outblock = dctx->outblk = NULL; *outlen = 0; return 0; } #ifdef ZLIB_STANDALONE #include #include int main(int argc, char **argv) { unsigned char buf[16], *outbuf; int ret, outlen; void *handle; int noheader = FALSE, opts = TRUE; char *filename = NULL; FILE *fp; while (--argc) { char *p = *++argv; if (p[0] == '-' && opts) { if (!strcmp(p, "-d")) noheader = TRUE; else if (!strcmp(p, "--")) opts = FALSE; /* next thing is filename */ else { fprintf(stderr, "unknown command line option '%s'\n", p); return 1; } } else if (!filename) { filename = p; } else { fprintf(stderr, "can only handle one filename\n"); return 1; } } handle = zlib_decompress_init(); if (noheader) { /* * Provide missing zlib header if -d was specified. */ zlib_decompress_block(handle, "\x78\x9C", 2, &outbuf, &outlen); assert(outlen == 0); } if (filename) fp = fopen(filename, "rb"); else fp = stdin; if (!fp) { assert(filename); fprintf(stderr, "unable to open '%s'\n", filename); return 1; } while (1) { ret = fread(buf, 1, sizeof(buf), fp); if (ret <= 0) break; zlib_decompress_block(handle, buf, ret, &outbuf, &outlen); if (outbuf) { if (outlen) fwrite(outbuf, 1, outlen, stdout); sfree(outbuf); } else { fprintf(stderr, "decoding error\n"); return 1; } } zlib_decompress_cleanup(handle); if (filename) fclose(fp); return 0; } #else const struct ssh_compress ssh_zlib = { "zlib", zlib_compress_init, zlib_compress_cleanup, zlib_compress_block, zlib_decompress_init, zlib_decompress_cleanup, zlib_decompress_block, zlib_disable_compression, "zlib (RFC1950)" }; #endif