/* Copyright (C) Andrew Tridgell 1996 Copyright (C) Paul Mackerras 1996 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "rsync.h" #include "zlib/zlib.h" extern int do_compression; static int compression_level = Z_DEFAULT_COMPRESSION; /* determine the compression level based on a wildcard filename list */ void set_compression(char *fname) { extern int module_id; char *dont; char *tok; if (!do_compression) return; compression_level = Z_DEFAULT_COMPRESSION; dont = lp_dont_compress(module_id); if (!dont || !*dont) return; if ((dont[0] == '*') && (!dont[1])) { /* an optimization to skip the rest of this routine */ compression_level = 0; return; } dont = strdup(dont); fname = strdup(fname); if (!dont || !fname) return; strlower(dont); strlower(fname); for (tok=strtok(dont," ");tok;tok=strtok(NULL," ")) { if (fnmatch(tok, fname, 0) == 0) { compression_level = 0; break; } } free(dont); free(fname); } /* non-compressing recv token */ static int simple_recv_token(int f,char **data) { static int residue; static char *buf; int n; if (!buf) { buf = (char *)malloc(CHUNK_SIZE); if (!buf) out_of_memory("simple_recv_token"); } if (residue == 0) { int i = read_int(f); if (i <= 0) return i; residue = i; } *data = buf; n = MIN(CHUNK_SIZE,residue); residue -= n; read_buf(f,buf,n); return n; } /* non-compressing send token */ static void simple_send_token(int f,int token, struct map_struct *buf,OFF_T offset,int n) { extern int write_batch; /* dw */ int hold_int; /* dw */ if (n > 0) { int l = 0; while (l < n) { int n1 = MIN(CHUNK_SIZE,n-l); write_int(f,n1); write_buf(f,map_ptr(buf,offset+l,n1),n1); if (write_batch) { write_batch_delta_file( (char *) &n1, sizeof(int) ); write_batch_delta_file(map_ptr(buf,offset+l,n1),n1); } l += n1; } } /* a -2 token means to send data only and no token */ if (token != -2) { write_int(f,-(token+1)); if (write_batch) { hold_int = -(token+1); write_batch_delta_file( (char *) &hold_int, sizeof(int) ); } } } /* Flag bytes in compressed stream are encoded as follows: */ #define END_FLAG 0 /* that's all folks */ #define TOKEN_LONG 0x20 /* followed by 32-bit token number */ #define TOKENRUN_LONG 0x21 /* ditto with 16-bit run count */ #define DEFLATED_DATA 0x40 /* + 6-bit high len, then low len byte */ #define TOKEN_REL 0x80 /* + 6-bit relative token number */ #define TOKENRUN_REL 0xc0 /* ditto with 16-bit run count */ #define MAX_DATA_COUNT 16383 /* fit 14 bit count into 2 bytes with flags */ /* For coding runs of tokens */ static int last_token = -1; static int run_start; static int last_run_end; /* Deflation state */ static z_stream tx_strm; /* Output buffer */ static char *obuf; /* Send a deflated token */ static void send_deflated_token(int f, int token, struct map_struct *buf, OFF_T offset, int nb, int toklen) { int n, r; static int init_done, flush_pending; extern int write_batch; /* dw */ char temp_byte; /* dw */ if (last_token == -1) { /* initialization */ if (!init_done) { tx_strm.next_in = NULL; tx_strm.zalloc = NULL; tx_strm.zfree = NULL; if (deflateInit2(&tx_strm, compression_level, Z_DEFLATED, -15, 8, Z_DEFAULT_STRATEGY) != Z_OK) { rprintf(FERROR, "compression init failed\n"); exit_cleanup(RERR_STREAMIO); } if ((obuf = malloc(MAX_DATA_COUNT+2)) == NULL) out_of_memory("send_deflated_token"); init_done = 1; } else deflateReset(&tx_strm); last_run_end = 0; run_start = token; flush_pending = 0; } else if (last_token == -2) { run_start = token; } else if (nb != 0 || token != last_token + 1 || token >= run_start + 65536) { /* output previous run */ r = run_start - last_run_end; n = last_token - run_start; if (r >= 0 && r <= 63) { write_byte(f, (n==0? TOKEN_REL: TOKENRUN_REL) + r); if (write_batch) { /* dw */ temp_byte = (char)( (n==0? TOKEN_REL: TOKENRUN_REL) + r); write_batch_delta_file(&temp_byte,sizeof(char)); } } else { write_byte(f, (n==0? TOKEN_LONG: TOKENRUN_LONG)); write_int(f, run_start); if (write_batch) { /* dw */ temp_byte = (char)(n==0? TOKEN_LONG: TOKENRUN_LONG); write_batch_delta_file(&temp_byte,sizeof(temp_byte)); write_batch_delta_file((char *)&run_start,sizeof(run_start)); } } if (n != 0) { write_byte(f, n); write_byte(f, n >> 8); if (write_batch) { /* dw */ write_batch_delta_file((char *)&n,sizeof(char)); temp_byte = (char) n >> 8; write_batch_delta_file(&temp_byte,sizeof(temp_byte)); } } last_run_end = last_token; run_start = token; } last_token = token; if (nb != 0 || flush_pending) { /* deflate the data starting at offset */ int flush = Z_NO_FLUSH; tx_strm.avail_in = 0; tx_strm.avail_out = 0; do { if (tx_strm.avail_in == 0 && nb != 0) { /* give it some more input */ n = MIN(nb, CHUNK_SIZE); tx_strm.next_in = (Bytef *) map_ptr(buf, offset, n); tx_strm.avail_in = n; nb -= n; offset += n; } if (tx_strm.avail_out == 0) { tx_strm.next_out = (Bytef *)(obuf + 2); tx_strm.avail_out = MAX_DATA_COUNT; if (flush != Z_NO_FLUSH) { /* * We left the last 4 bytes in the * buffer, in case they are the * last 4. Move them to the front. */ memcpy(tx_strm.next_out, obuf+MAX_DATA_COUNT-2, 4); tx_strm.next_out += 4; tx_strm.avail_out -= 4; } } if (nb == 0 && token != -2) flush = Z_SYNC_FLUSH; r = deflate(&tx_strm, flush); if (r != Z_OK) { rprintf(FERROR, "deflate returned %d\n", r); exit_cleanup(RERR_STREAMIO); } if (nb == 0 || tx_strm.avail_out == 0) { n = MAX_DATA_COUNT - tx_strm.avail_out; if (flush != Z_NO_FLUSH) { /* * We have to trim off the last 4 * bytes of output when flushing * (they are just 0, 0, ff, ff). */ n -= 4; } if (n > 0) { obuf[0] = DEFLATED_DATA + (n >> 8); obuf[1] = n; write_buf(f, obuf, n+2); if (write_batch) /* dw */ write_batch_delta_file(obuf,n+2); } } } while (nb != 0 || tx_strm.avail_out == 0); flush_pending = token == -2; } if (token == -1) { /* end of file - clean up */ write_byte(f, END_FLAG); if (write_batch) { /* dw */ temp_byte = END_FLAG; write_batch_delta_file((char *)&temp_byte,sizeof(temp_byte)); } } else if (token != -2) { /* add the data in the current block to the compressor's history and hash table */ tx_strm.next_in = (Bytef *) map_ptr(buf, offset, toklen); tx_strm.avail_in = toklen; tx_strm.next_out = (Bytef *) obuf; tx_strm.avail_out = MAX_DATA_COUNT; r = deflate(&tx_strm, Z_INSERT_ONLY); if (r != Z_OK || tx_strm.avail_in != 0) { rprintf(FERROR, "deflate on token returned %d (%d bytes left)\n", r, tx_strm.avail_in); exit_cleanup(RERR_STREAMIO); } } } /* tells us what the receiver is in the middle of doing */ static enum { r_init, r_idle, r_running, r_inflating, r_inflated } recv_state; /* for inflating stuff */ static z_stream rx_strm; static char *cbuf; static char *dbuf; /* for decoding runs of tokens */ static int rx_token; static int rx_run; /* Receive a deflated token and inflate it */ static int recv_deflated_token(int f, char **data) { int n, r, flag; static int init_done; static int saved_flag; for (;;) { switch (recv_state) { case r_init: if (!init_done) { rx_strm.next_out = NULL; rx_strm.zalloc = NULL; rx_strm.zfree = NULL; if (inflateInit2(&rx_strm, -15) != Z_OK) { rprintf(FERROR, "inflate init failed\n"); exit_cleanup(RERR_STREAMIO); } if ((cbuf = malloc(MAX_DATA_COUNT)) == NULL || (dbuf = malloc(CHUNK_SIZE)) == NULL) out_of_memory("recv_deflated_token"); init_done = 1; } else { inflateReset(&rx_strm); } recv_state = r_idle; rx_token = 0; break; case r_idle: case r_inflated: if (saved_flag) { flag = saved_flag & 0xff; saved_flag = 0; } else flag = read_byte(f); if ((flag & 0xC0) == DEFLATED_DATA) { n = ((flag & 0x3f) << 8) + read_byte(f); read_buf(f, cbuf, n); rx_strm.next_in = (Bytef *)cbuf; rx_strm.avail_in = n; recv_state = r_inflating; break; } if (recv_state == r_inflated) { /* check previous inflated stuff ended correctly */ rx_strm.avail_in = 0; rx_strm.next_out = (Bytef *)dbuf; rx_strm.avail_out = CHUNK_SIZE; r = inflate(&rx_strm, Z_SYNC_FLUSH); n = CHUNK_SIZE - rx_strm.avail_out; /* * Z_BUF_ERROR just means no progress was * made, i.e. the decompressor didn't have * any pending output for us. */ if (r != Z_OK && r != Z_BUF_ERROR) { rprintf(FERROR, "inflate flush returned %d (%d bytes)\n", r, n); exit_cleanup(RERR_STREAMIO); } if (n != 0 && r != Z_BUF_ERROR) { /* have to return some more data and save the flag for later. */ saved_flag = flag + 0x10000; *data = dbuf; return n; } /* * At this point the decompressor should * be expecting to see the 0, 0, ff, ff bytes. */ if (!inflateSyncPoint(&rx_strm)) { rprintf(FERROR, "decompressor lost sync!\n"); exit_cleanup(RERR_STREAMIO); } rx_strm.avail_in = 4; rx_strm.next_in = (Bytef *)cbuf; cbuf[0] = cbuf[1] = 0; cbuf[2] = cbuf[3] = 0xff; inflate(&rx_strm, Z_SYNC_FLUSH); recv_state = r_idle; } if (flag == END_FLAG) { /* that's all folks */ recv_state = r_init; return 0; } /* here we have a token of some kind */ if (flag & TOKEN_REL) { rx_token += flag & 0x3f; flag >>= 6; } else rx_token = read_int(f); if (flag & 1) { rx_run = read_byte(f); rx_run += read_byte(f) << 8; recv_state = r_running; } return -1 - rx_token; case r_inflating: rx_strm.next_out = (Bytef *)dbuf; rx_strm.avail_out = CHUNK_SIZE; r = inflate(&rx_strm, Z_NO_FLUSH); n = CHUNK_SIZE - rx_strm.avail_out; if (r != Z_OK) { rprintf(FERROR, "inflate returned %d (%d bytes)\n", r, n); exit_cleanup(RERR_STREAMIO); } if (rx_strm.avail_in == 0) recv_state = r_inflated; if (n != 0) { *data = dbuf; return n; } break; case r_running: ++rx_token; if (--rx_run == 0) recv_state = r_idle; return -1 - rx_token; } } } /* * put the data corresponding to a token that we've just returned * from recv_deflated_token into the decompressor's history buffer. */ static void see_deflate_token(char *buf, int len) { int r, blklen; unsigned char hdr[5]; rx_strm.avail_in = 0; blklen = 0; hdr[0] = 0; do { if (rx_strm.avail_in == 0 && len != 0) { if (blklen == 0) { /* Give it a fake stored-block header. */ rx_strm.next_in = (Bytef *)hdr; rx_strm.avail_in = 5; blklen = len; if (blklen > 0xffff) blklen = 0xffff; hdr[1] = blklen; hdr[2] = blklen >> 8; hdr[3] = ~hdr[1]; hdr[4] = ~hdr[2]; } else { rx_strm.next_in = (Bytef *)buf; rx_strm.avail_in = blklen; len -= blklen; blklen = 0; } } rx_strm.next_out = (Bytef *)dbuf; rx_strm.avail_out = CHUNK_SIZE; r = inflate(&rx_strm, Z_SYNC_FLUSH); if (r != Z_OK) { rprintf(FERROR, "inflate (token) returned %d\n", r); exit_cleanup(RERR_STREAMIO); } } while (len || rx_strm.avail_out == 0); } /* * transmit a verbatim buffer of length n followed by a token * If token == -1 then we have reached EOF * If n == 0 then don't send a buffer */ void send_token(int f,int token,struct map_struct *buf,OFF_T offset, int n,int toklen) { if (!do_compression) { simple_send_token(f,token,buf,offset,n); } else { send_deflated_token(f, token, buf, offset, n, toklen); } } /* * receive a token or buffer from the other end. If the reurn value is >0 then * it is a data buffer of that length, and *data will point at the data. * if the return value is -i then it represents token i-1 * if the return value is 0 then the end has been reached */ int recv_token(int f,char **data) { int tok; if (!do_compression) { tok = simple_recv_token(f,data); } else { tok = recv_deflated_token(f, data); } return tok; } /* * look at the data corresponding to a token, if necessary */ void see_token(char *data, int toklen) { if (do_compression) see_deflate_token(data, toklen); }