token.c

/*
 * Routines used by the file-transfer code.
 *
 * Copyright (C) 1996 Andrew Tridgell
 * Copyright (C) 1996 Paul Mackerras
 * Copyright (C) 2003-2020 Wayne Davison
 *
 * 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 3 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, visit the http://fsf.org website.
 */

#include "rsync.h"
#include "itypes.h"
#include <zlib.h>
#ifdef SUPPORT_ZSTD
#include <zstd.h>
#endif
#ifdef SUPPORT_LZ4
#include <lz4.h>
#endif

extern int do_compression;
extern int protocol_version;
extern int module_id;
extern int do_compression_level;
extern char *skip_compress;

#ifndef Z_INSERT_ONLY
#define Z_INSERT_ONLY Z_SYNC_FLUSH
#endif

static int compression_level; /* The compression level for the current file. */
static int skip_compression_level; /* The least possible compressing for handling skip-compress files. */
static int per_file_default_level; /* The default level that each new file gets prior to checking its suffix. */

struct suffix_tree {
	struct suffix_tree *sibling;
	struct suffix_tree *child;
	char letter, word_end;
};

static char *match_list;
static struct suffix_tree *suftree;

void init_compression_level(void)
{
	int min_level, max_level, def_level, off_level;

	switch (do_compression) {
	case CPRES_NONE:
		return;
	case CPRES_ZLIB:
	case CPRES_ZLIBX:
		min_level = 1;
		max_level = Z_BEST_COMPRESSION;
		def_level = 6; /* Z_DEFAULT_COMPRESSION is -1, so set it to the real default */
		off_level = skip_compression_level = Z_NO_COMPRESSION;
		if (do_compression_level == Z_DEFAULT_COMPRESSION)
			do_compression_level = def_level;
		break;
#ifdef SUPPORT_ZSTD
	case CPRES_ZSTD:
		min_level = skip_compression_level = ZSTD_minCLevel();
		max_level = ZSTD_maxCLevel();
		def_level = ZSTD_CLEVEL_DEFAULT;
		off_level = CLVL_NOT_SPECIFIED;
		if (do_compression_level == 0)
			do_compression_level = def_level;
		break;
#endif
#ifdef SUPPORT_LZ4
	case CPRES_LZ4:
		min_level = skip_compression_level = 0;
		max_level = 0;
		def_level = 0;
		off_level = CLVL_NOT_SPECIFIED;
		break;
#endif
	default: /* paranoia to prevent missing case values */
		NOISY_DEATH("Unknown do_compression value");
	}

	if (do_compression_level == CLVL_NOT_SPECIFIED)
		do_compression_level = def_level;
	else if (do_compression_level == off_level) {
		do_compression = CPRES_NONE;
		return;
	}

	/* We don't bother with any errors or warnings -- just make sure that the values are valid. */
	if (do_compression_level < min_level)
		do_compression_level = min_level;
	else if (do_compression_level > max_level)
		do_compression_level = max_level;
}

static void add_suffix(struct suffix_tree **prior, char ltr, const char *str)
{
	struct suffix_tree *node, *newnode;

	if (ltr == '[') {
		const char *after = strchr(str, ']');
		/* Treat "[foo" and "[]" as having a literal '['. */
		if (after && after++ != str+1) {
			while ((ltr = *str++) != ']')
				add_suffix(prior, ltr, after);
			return;
		}
	}

	for (node = *prior; node; prior = &node->sibling, node = node->sibling) {
		if (node->letter == ltr) {
			if (*str)
				add_suffix(&node->child, *str, str+1);
			else
				node->word_end = 1;
			return;
		}
		if (node->letter > ltr)
			break;
	}
	newnode = new(struct suffix_tree);
	newnode->sibling = node;
	newnode->child = NULL;
	newnode->letter = ltr;
	*prior = newnode;
	if (*str) {
		add_suffix(&newnode->child, *str, str+1);
		newnode->word_end = 0;
	} else
		newnode->word_end = 1;
}

static void add_nocompress_suffixes(const char *str)
{
	char *buf, *t;
	const char *f = str;

	buf = new_array(char, strlen(f) + 1);

	while (*f) {
		if (*f == '/') {
			f++;
			continue;
		}

		t = buf;
		do {
			if (isUpper(f))
				*t++ = toLower(f);
			else
				*t++ = *f;
		} while (*++f != '/' && *f);
		*t++ = '\0';

		add_suffix(&suftree, *buf, buf+1);
	}

	free(buf);
}

static void init_set_compression(void)
{
	const char *f;
	char *t, *start;

	if (skip_compress)
		add_nocompress_suffixes(skip_compress);

	/* A non-daemon transfer skips the default suffix list if the
	 * user specified --skip-compress. */
	if (skip_compress && module_id < 0)
		f = "";
	else
		f = lp_dont_compress(module_id);

	match_list = t = new_array(char, strlen(f) + 2);

	per_file_default_level = do_compression_level;

	while (*f) {
		if (*f == ' ') {
			f++;
			continue;
		}

		start = t;
		do {
			if (isUpper(f))
				*t++ = toLower(f);
			else
				*t++ = *f;
		} while (*++f != ' ' && *f);
		*t++ = '\0';

		if (t - start == 1+1 && *start == '*') {
			/* Optimize a match-string of "*". */
			*match_list = '\0';
			suftree = NULL;
			per_file_default_level = skip_compression_level;
			break;
		}

		/* Move *.foo items into the stuffix tree. */
		if (*start == '*' && start[1] == '.' && start[2]
		 && !strpbrk(start+2, ".?*")) {
			add_suffix(&suftree, start[2], start+3);
			t = start;
		}
	}
	*t++ = '\0';
}

/* determine the compression level based on a wildcard filename list */
void set_compression(const char *fname)
{
	const struct suffix_tree *node;
	const char *s;
	char ltr;

	if (!do_compression)
		return;

	if (!match_list)
		init_set_compression();

	compression_level = per_file_default_level;

	if (!*match_list && !suftree)
		return;

	if ((s = strrchr(fname, '/')) != NULL)
		fname = s + 1;

	for (s = match_list; *s; s += strlen(s) + 1) {
		if (iwildmatch(s, fname)) {
			compression_level = skip_compression_level;
			return;
		}
	}

	if (!(node = suftree) || !(s = strrchr(fname, '.'))
	 || s == fname || !(ltr = *++s))
		return;

	while (1) {
		if (isUpper(&ltr))
			ltr = toLower(&ltr);
		while (node->letter != ltr) {
			if (node->letter > ltr)
				return;
			if (!(node = node->sibling))
				return;
		}
		if ((ltr = *++s) == '\0') {
			if (node->word_end)
				compression_level = skip_compression_level;
			return;
		}
		if (!(node = node->child))
			return;
	}
}

/* non-compressing recv token */
static int32 simple_recv_token(int f, char **data)
{
	static int32 residue;
	static char *buf;
	int32 n;

	if (!buf)
		buf = new_array(char, CHUNK_SIZE);

	if (residue == 0) {
		int32 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, int32 token, struct map_struct *buf, OFF_T offset, int32 n)
{
	if (n > 0) {
		int32 len = 0;
		while (len < n) {
			int32 n1 = MIN(CHUNK_SIZE, n-len);
			write_int(f, n1);
			write_buf(f, map_ptr(buf, offset+len, n1), n1);
			len += n1;
		}
	}
	/* a -2 token means to send data only and no token */
	if (token != -2)
		write_int(f, -(token+1));
}

/* 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 */

/* zlib.h says that if we want to be able to compress something in a single
 * call, avail_out must be at least 0.1% larger than avail_in plus 12 bytes.
 * We'll add in 0.1%+16, just to be safe (and we'll avoid floating point,
 * to ensure that this is a compile-time value). */
#define AVAIL_OUT_SIZE(avail_in_size) ((avail_in_size)*1001/1000+16)

/* For coding runs of tokens */
static int32 last_token = -1;
static int32 run_start;
static int32 last_run_end;

/* Deflation state */
static z_stream tx_strm;

/* Output buffer */
static char *obuf;

/* We want obuf to be able to hold both MAX_DATA_COUNT+2 bytes as well as
 * AVAIL_OUT_SIZE(CHUNK_SIZE) bytes, so make sure that it's large enough. */
#if MAX_DATA_COUNT+2 > AVAIL_OUT_SIZE(CHUNK_SIZE)
#define OBUF_SIZE	(MAX_DATA_COUNT+2)
#else
#define OBUF_SIZE	AVAIL_OUT_SIZE(CHUNK_SIZE)
#endif

/* Send a deflated token */
static void
send_deflated_token(int f, int32 token, struct map_struct *buf, OFF_T offset, int32 nb, int32 toklen)
{
	static int init_done, flush_pending;
	int32 n, r;

	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_PROTOCOL);
			}
			obuf = new_array(char, OBUF_SIZE);
			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);
		} else {
			write_byte(f, (n==0? TOKEN_LONG: TOKENRUN_LONG));
			write_int(f, run_start);
		}
		if (n != 0) {
			write_byte(f, n);
			write_byte(f, n >> 8);
		}
		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);
				}
			}
		} 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);
	} else if (token != -2 && do_compression == CPRES_ZLIB) {
		/* Add the data in the current block to the compressor's
		 * history and hash table. */
		do {
			/* Break up long sections in the same way that
			 * see_deflate_token() does. */
			int32 n1 = toklen > 0xffff ? 0xffff : toklen;
			toklen -= n1;
			tx_strm.next_in = (Bytef *)map_ptr(buf, offset, n1);
			tx_strm.avail_in = n1;
			if (protocol_version >= 31) /* Newer protocols avoid a data-duplicating bug */
				offset += n1;
			tx_strm.next_out = (Bytef *) obuf;
			tx_strm.avail_out = AVAIL_OUT_SIZE(CHUNK_SIZE);
			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);
			}
		} while (toklen > 0);
	}
}

/* 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 int32 rx_token;
static int32 rx_run;

/* Receive a deflated token and inflate it */
static int32 recv_deflated_token(int f, char **data)
{
	static int init_done;
	static int32 saved_flag;
	int32 n, flag;
	int r;

	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_PROTOCOL);
				}
				cbuf = new_array(char, MAX_DATA_COUNT);
				dbuf = new_array(char, AVAIL_OUT_SIZE(CHUNK_SIZE));
				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 = AVAIL_OUT_SIZE(CHUNK_SIZE);
				r = inflate(&rx_strm, Z_SYNC_FLUSH);
				n = AVAIL_OUT_SIZE(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] = (char)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 = AVAIL_OUT_SIZE(CHUNK_SIZE);
			r = inflate(&rx_strm, Z_NO_FLUSH);
			n = AVAIL_OUT_SIZE(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, int32 len)
{
	int r;
	int32 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;
				if (protocol_version >= 31) /* Newer protocols avoid a data-duplicating bug */
					buf += blklen;
				len -= blklen;
				blklen = 0;
			}
		}
		rx_strm.next_out = (Bytef *)dbuf;
		rx_strm.avail_out = AVAIL_OUT_SIZE(CHUNK_SIZE);
		r = inflate(&rx_strm, Z_SYNC_FLUSH);
		if (r != Z_OK && r != Z_BUF_ERROR) {
			rprintf(FERROR, "inflate (token) returned %d\n", r);
			exit_cleanup(RERR_STREAMIO);
		}
	} while (len || rx_strm.avail_out == 0);
}

#ifdef SUPPORT_ZSTD

static ZSTD_inBuffer zstd_in_buff;
static ZSTD_outBuffer zstd_out_buff;
static ZSTD_CCtx *zstd_cctx;

static void send_zstd_token(int f, int32 token, struct map_struct *buf, OFF_T offset, int32 nb)
{
	static int comp_init_done, flush_pending;
	ZSTD_EndDirective flush = ZSTD_e_continue;
	int32 n, r;

	/* initialization */
	if (!comp_init_done) {
		zstd_cctx = ZSTD_createCCtx();
		if (!zstd_cctx) {
			rprintf(FERROR, "compression init failed\n");
			exit_cleanup(RERR_PROTOCOL);
		}

		obuf = new_array(char, OBUF_SIZE);

		ZSTD_CCtx_setParameter(zstd_cctx, ZSTD_c_compressionLevel, do_compression_level);
		zstd_out_buff.dst = obuf + 2;

		comp_init_done = 1;
	}

	if (last_token == -1) {
		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);
		} else {
			write_byte(f, (n==0? TOKEN_LONG: TOKENRUN_LONG));
			write_int(f, run_start);
		}
		if (n != 0) {
			write_byte(f, n);
			write_byte(f, n >> 8);
		}
		last_run_end = last_token;
		run_start = token;
	}

	last_token = token;

	if (nb || flush_pending) {

		zstd_in_buff.src = map_ptr(buf, offset, nb);
		zstd_in_buff.size = nb;
		zstd_in_buff.pos = 0;

		do {
			if (zstd_out_buff.size == 0) {
				zstd_out_buff.size = MAX_DATA_COUNT;
				zstd_out_buff.pos = 0;
			}

			/* File ended, flush */
			if (token != -2)
				flush = ZSTD_e_flush;

			r = ZSTD_compressStream2(zstd_cctx, &zstd_out_buff, &zstd_in_buff, flush);
			if (ZSTD_isError(r)) {
				rprintf(FERROR, "ZSTD_compressStream returned %d\n", r);
				exit_cleanup(RERR_STREAMIO);
			}

			/*
			 * Nothing is sent if the buffer isn't full so avoid smaller
			 * transfers. If a file is finished then we flush the internal
			 * state and send a smaller buffer so that the remote side can
			 * finish the file.
			 */
			if (zstd_out_buff.pos == zstd_out_buff.size || flush == ZSTD_e_flush) {
				n = zstd_out_buff.pos;

				obuf[0] = DEFLATED_DATA + (n >> 8);
				obuf[1] = n;
				write_buf(f, obuf, n+2);

				zstd_out_buff.size = 0;
			}
			/*
			 * Loop while the input buffer isn't full consumed or the
			 * internal state isn't fully flushed.
			 */
		} while (zstd_in_buff.pos < zstd_in_buff.size || r > 0);
		flush_pending = token == -2;
	}

	if (token == -1) {
		/* end of file - clean up */
		write_byte(f, END_FLAG);
	}
}

static ZSTD_DCtx *zstd_dctx;

static int32 recv_zstd_token(int f, char **data)
{
	static int decomp_init_done;
	static int out_buffer_size;
	int32 n, flag;
	int r;

	if (!decomp_init_done) {
		zstd_dctx = ZSTD_createDCtx();
		if (!zstd_dctx) {
			rprintf(FERROR, "ZSTD_createDStream failed\n");
			exit_cleanup(RERR_PROTOCOL);
		}

		/* Output buffer fits two decompressed blocks */
		out_buffer_size = ZSTD_DStreamOutSize() * 2;
		cbuf = new_array(char, MAX_DATA_COUNT);
		dbuf = new_array(char, out_buffer_size);

		zstd_in_buff.src = cbuf;
		zstd_out_buff.dst = dbuf;

		decomp_init_done = 1;
	}

	for (;;) {
		switch (recv_state) {
		case r_init:
			recv_state = r_idle;
			rx_token = 0;
			break;

		case r_idle:
			flag = read_byte(f);
			if ((flag & 0xC0) == DEFLATED_DATA) {
				n = ((flag & 0x3f) << 8) + read_byte(f);
				read_buf(f, cbuf, n);

				zstd_in_buff.size = n;
				zstd_in_buff.pos = 0;

				recv_state = r_inflating;
				break;
			}

			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_inflated: /* zstd doesn't get into this state */
			break;

		case r_inflating:
			zstd_out_buff.size = out_buffer_size;
			zstd_out_buff.pos = 0;

			r = ZSTD_decompressStream(zstd_dctx, &zstd_out_buff, &zstd_in_buff);
			n = zstd_out_buff.pos;
			if (ZSTD_isError(r)) {
				rprintf(FERROR, "ZSTD decomp returned %d (%d bytes)\n", r, n);
				exit_cleanup(RERR_STREAMIO);
			}

			/*
			 * If the input buffer is fully consumed and the output
			 * buffer is not full then next step is to read more
			 * data.
			 */
			if (zstd_in_buff.size == zstd_in_buff.pos && n < out_buffer_size)
				recv_state = r_idle;

			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;
		}
	}
}
#endif /* SUPPORT_ZSTD */

#ifdef SUPPORT_LZ4
static void
send_compressed_token(int f, int32 token, struct map_struct *buf, OFF_T offset, int32 nb)
{
	static int init_done, flush_pending;
	int size = MAX(LZ4_compressBound(CHUNK_SIZE), MAX_DATA_COUNT+2);
	int32 n, r;

	if (last_token == -1) {
		if (!init_done) {
			obuf = new_array(char, size);
			init_done = 1;
		}
		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);
		} else {
			write_byte(f, (n==0? TOKEN_LONG: TOKENRUN_LONG));
			write_int(f, run_start);
		}
		if (n != 0) {
			write_byte(f, n);
			write_byte(f, n >> 8);
		}
		last_run_end = last_token;
		run_start = token;
	}

	last_token = token;

	if (nb != 0 || flush_pending) {
		int available_in, available_out = 0;
		const char *next_in;

		do {
			char *next_out = obuf + 2;

			if (available_out == 0) {
				available_in = MIN(nb, MAX_DATA_COUNT);
				next_in = map_ptr(buf, offset, available_in);
			} else
				available_in /= 2;

			available_out = LZ4_compress_default(next_in, next_out, available_in, size - 2);
			if (!available_out) {
				rprintf(FERROR, "compress returned %d\n", available_out);
				exit_cleanup(RERR_STREAMIO);
			}
			if (available_out <= MAX_DATA_COUNT) {
				obuf[0] = DEFLATED_DATA + (available_out >> 8);
				obuf[1] = available_out;

				write_buf(f, obuf, available_out + 2);

				available_out = 0;
				nb -= available_in;
				offset += available_in;
			}
		} while (nb != 0);
		flush_pending = token == -2;
	}
	if (token == -1) {
		/* end of file - clean up */
		write_byte(f, END_FLAG);
	}
}

static int32 recv_compressed_token(int f, char **data)
{
	static int init_done;
	int32 n, flag;
	int size = MAX(LZ4_compressBound(CHUNK_SIZE), MAX_DATA_COUNT+2);
	static const char *next_in;
	static int avail_in;
	int avail_out;

	for (;;) {
		switch (recv_state) {
		case r_init:
			if (!init_done) {
				cbuf = new_array(char, MAX_DATA_COUNT);
				dbuf = new_array(char, size);
				init_done = 1;
			}
			recv_state = r_idle;
			rx_token = 0;
			break;

		case r_idle:
			flag = read_byte(f);
			if ((flag & 0xC0) == DEFLATED_DATA) {
				n = ((flag & 0x3f) << 8) + read_byte(f);
				read_buf(f, cbuf, n);
				next_in = (char *)cbuf;
				avail_in = n;
				recv_state = r_inflating;
				break;
			}

			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:
			avail_out = LZ4_decompress_safe(next_in, dbuf, avail_in, size);
			if (avail_out < 0) {
				rprintf(FERROR, "uncompress failed: %d\n", avail_out);
				exit_cleanup(RERR_STREAMIO);
			}
			recv_state = r_idle;
			*data = dbuf;
			return avail_out;

		case r_inflated: /* lz4 doesn't get into this state */
			break;

		case r_running:
			++rx_token;
			if (--rx_run == 0)
				recv_state = r_idle;
			return -1 - rx_token;
		}
	}
}
#endif /* SUPPORT_LZ4 */

/**
 * Transmit a verbatim buffer of length @p 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, int32 token, struct map_struct *buf, OFF_T offset,
		int32 n, int32 toklen)
{
	switch (do_compression) {
	case CPRES_NONE:
		simple_send_token(f, token, buf, offset, n);
		break;
	case CPRES_ZLIB:
	case CPRES_ZLIBX:
		send_deflated_token(f, token, buf, offset, n, toklen);
		break;
#ifdef SUPPORT_ZSTD
	case CPRES_ZSTD:
		send_zstd_token(f, token, buf, offset, n);
		break;
#endif
#ifdef SUPPORT_LZ4
	case CPRES_LZ4:
		send_compressed_token(f, token, buf, offset, n);
		break;
#endif
	default:
		NOISY_DEATH("Unknown do_compression value");
	}
}

/*
 * receive a token or buffer from the other end. If the return 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
 */
int32 recv_token(int f, char **data)
{
	switch (do_compression) {
	case CPRES_NONE:
		return simple_recv_token(f,data);
	case CPRES_ZLIB:
	case CPRES_ZLIBX:
		return recv_deflated_token(f, data);
#ifdef SUPPORT_ZSTD
	case CPRES_ZSTD:
		return recv_zstd_token(f, data);
#endif
#ifdef SUPPORT_LZ4
	case CPRES_LZ4:
		return recv_compressed_token(f, data);
#endif
	default:
		NOISY_DEATH("Unknown do_compression value");
	}
}

/*
 * look at the data corresponding to a token, if necessary
 */
void see_token(char *data, int32 toklen)
{
	switch (do_compression) {
	case CPRES_NONE:
		break;
	case CPRES_ZLIB:
		see_deflate_token(data, toklen);
		break;
	case CPRES_ZLIBX:
		break;
#ifdef SUPPORT_ZSTD
	case CPRES_ZSTD:
		break;
#endif
#ifdef SUPPORT_LZ4
	case CPRES_LZ4:
		/*see_uncompressed_token(data, toklen);*/
		break;
#endif
	default:
		NOISY_DEATH("Unknown do_compression value");
	}
}