pcompress/delta2/delta2.c

/*
 * This file is a part of Pcompress, a chunked parallel multi-
 * algorithm lossless compression and decompression program.
 *
 * Copyright (C) 2012 Moinak Ghosh. All rights reserved.
 * Use is subject to license terms.
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser 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
 * Lesser General Public License for more details.
 *
 * moinakg@belenix.org, http://moinakg.wordpress.com/
 */

/*
 * These routines perform a kind of Adaptive Delta Encoding.
 * Initially the buffer is scanned to identify spans of values that
 * are monotonically increasing in arithmetic progression. These
 * values are not single bytes but consists of a stride of bytes
 * packed into an integer representation. Multiple stride lengths
 * (3, 5, 7, 8) are tried to find the one that gives the maximum
 * reduction. A span length threshold in bytes is used. Byte spans
 * less than this threshold are ignored.
 * Bytes are packed into integers in big-endian format.
 *
 * After an optimal stride length has been identified the encoder
 * performs a delta run length encoding on the spans. Two types of
 * objects are output by the encoder:
 * 1) A literal run of unmodified bytes. Header: 1 zero byte followed
 *    by a 64bit length in bytes.
 * 2) An encoded run length of a series in arithmetic progression.
 *    Header: 1 byte stride length
 *            64bit length of span in bytes
 *            64bit starting value of series
 *            64bit delta value
 */
#include <stdio.h>
#include <utils.h>
#include "delta2.h"

// Size of original data. 64 bits.
#define	MAIN_HDR	(sizeof (uint64_t))

// Literal text header block:
// 1-byte flag
// 64bit length of run in bytes.
#define	LIT_HDR		(1 + sizeof (uint64_t))

// Delta encoded header block:
// 1-byte flag indicating stride length
// 64bit length of span in bytes
// 64bit initial value
// 64bit delta value
#define	DELTA_HDR	(1 + (sizeof (uint64_t)) * 3)

int
delta2_encode(uchar_t *src, size_t srclen, uchar_t *dst, size_t *dstlen, int rle_thresh)
{
	uint64_t snum, gtot1, gtot2, tot;
	uint64_t cnt, val, sval;
	uint64_t vl1, vl2, vld1, vld2;
	uchar_t *pos, *pos1, *pos2, stride, st1;
	uchar_t strides[4] = {3, 5, 7, 8};
	int st, sz;

	gtot1 = ULL_MAX;
	stride = 0;
	sz = sizeof (strides) / sizeof (strides[0]);

	/*
	 * Estimate which stride length gives the max reduction given rle_thresh.
	 */
	for (st = 0; st < sz; st++) {
		snum = 0;
		gtot2 = MAIN_HDR + LIT_HDR;
		vl1 = 0;
		vld1 = 0;
		tot = 0;
		pos = src;
		st1 = strides[st];
		for (cnt = 0; cnt < (srclen - sizeof (cnt)); cnt += st1) {
			vl2 = *((uint64_t *)pos);
			vl2 = htonll(vl2);
			vl2 >>= ((sizeof (vl2) - st1) << 3);
			vld2 = vl2 - vl1;
			if (vld1 != vld2) {
				if (snum > rle_thresh) {
					if (tot > 0) {
						gtot2 += LIT_HDR;
						tot = 0;
					}
					gtot2 += DELTA_HDR;
				} else {
					gtot2 += snum;
					tot += snum;
				}
				snum = 0;
			}
			snum += st1;
			vld1 = vld2;
			vl1 = vl2;
			pos += st1;
		}
		if (snum > 1) {
			if (snum > rle_thresh) {
				gtot2 += DELTA_HDR;
			} else {
				gtot2 += snum;
			}
		}
		if (gtot2 < gtot1) {
			gtot1 = gtot2;
			stride = st1;
		}
	}

	if (!(gtot1 < srclen && srclen - gtot1 > (DELTA_HDR + LIT_HDR + MAIN_HDR))) {
		DEBUG_STAT_EN(fprintf(stderr, "No Delta\n"));
		return (-1);
	}
	DEBUG_STAT_EN(fprintf(stderr, "Found Delta: %llu (srclen: %llu), stride: %d\n", gtot1, srclen, stride));

	/*
	 * Now perform encoding using the stride length.
	 */
	snum = 0;
	vl1 = 0;
	vld1 = 0;
	gtot1 = 0;
	pos = src;
	pos1 = dst;
	*((uint64_t *)pos1) = htonll(srclen);
	pos1 += MAIN_HDR;
	pos2 = pos1;
	pos1 += LIT_HDR;

	vl2 = *((uint64_t *)pos);
	vl2 = htonll(vl2);
	vl2 >>= ((sizeof (vl2) - stride) << 3);
	sval = vl2;

	for (cnt = 0; cnt < (srclen - sizeof (cnt)); cnt += stride) {
		val = *((uint64_t *)pos);
		vl2 = htonll(val);
		vl2 >>= ((sizeof (vl2) - stride) << 3);
		vld2 = vl2 - vl1;
		if (vld1 != vld2) {
			if (snum > rle_thresh) {
				if (gtot1 > 0) {
					/*
					 * Encode previous literal run, if any.
					 */
					*pos2 = 0;
					pos2++;
					*((uint64_t *)pos2) = htonll(gtot1);
					pos2 += (gtot1 + sizeof (uint64_t));
					gtot1 = 0;
				}
				/*
				 * RLE Encode delta series.
				 */
				*pos2 = stride;
				pos2++;
				*((uint64_t *)pos2) = htonll(snum);
				pos2 += sizeof (uint64_t);
				*((uint64_t *)pos2) = htonll(sval);
				pos2 += sizeof (uint64_t);
				*((uint64_t *)pos2) = htonll(vld1);
				pos2 += sizeof (uint64_t);
				pos1 = pos2 + LIT_HDR;
			} else {
				gtot1 += snum;
			}
			snum = 0;
			sval = vl2;
		}
		*((uint64_t *)pos1) = val;
		pos1 += stride;
		snum += stride;
		vld1 = vld2;
		vl1 = vl2;
		pos += stride;
	}

	if (snum > 0) {
		if (snum > rle_thresh) {
			if (gtot1 > 0) {
				*pos2 = 0;
				pos2++;
				*((uint64_t *)pos2) = htonll(gtot1);
				pos2 += (gtot1 + sizeof (uint64_t));
				gtot1 = 0;
			}
			*pos2 = stride;
			pos2++;
			*((uint64_t *)pos2) = htonll(snum);
			pos2 += sizeof (uint64_t);
			*((uint64_t *)pos2) = htonll(sval);
			pos2 += sizeof (uint64_t);
			*((uint64_t *)pos2) = htonll(vld1);
			pos2 += sizeof (uint64_t);
		} else {
			gtot1 += snum;
			*pos2 = 0;
			pos2++;
			*((uint64_t *)pos2) = htonll(gtot1);
			pos2 += (gtot1 + sizeof (uint64_t));
		}
	}

	val = srclen - (pos - src);
	if (val > 0) {
		/*
		 * Encode left over bytes, if any, at the end into a
		 * literal run.
		 */
		*pos2 = 0;
		pos2++;
		*((uint64_t *)pos2) = htonll(val);
		pos2 += sizeof (uint64_t);
		for (cnt = 0; cnt < val; cnt++) {
			*pos2 = *pos;
			pos2++; pos++;
		}
	}
	*dstlen = pos2 - dst;
	return (0);
}

int
delta2_decode(uchar_t *src, size_t srclen, uchar_t *dst, size_t *dstlen)
{
	uchar_t *pos, *pos1, *last;
	uint64_t olen, val, sval, delta, rcnt, cnt, out;
	uchar_t stride;

	pos = src;
	pos1 = dst;

	last = pos + srclen;
	olen = ntohll(*((uint64_t *)pos));
	if (*dstlen < (olen + 8))
		return (-1);

	out = 0;
	pos += MAIN_HDR;

	while (pos < last) {
		if (*pos == 0) {
			/*
			 * Copy over literal run of bytes.
			 */
			pos++;
			rcnt = ntohll(*((uint64_t *)pos));
			pos += sizeof (rcnt);
			if (out + rcnt > *dstlen) {
				return (-1);
			}
			for (cnt = 0; cnt < rcnt; cnt++) {
				*pos1 = *pos;
				pos++; pos1++; out++;
			}
		} else {
			stride = *pos;
			pos++;
			rcnt = ntohll(*((uint64_t *)pos));
			pos += sizeof (rcnt);
			sval = ntohll(*((uint64_t *)pos));
			pos += sizeof (sval);
			delta = ntohll(*((uint64_t *)pos));
			pos += sizeof (delta);
			if (out + rcnt > *dstlen) {
				return (-1);
			}

			/*
			 * Recover original bytes from the arithmetic series using
			 * length, starting value and delta.
			 */
			for (cnt = 0; cnt < rcnt/stride; cnt++) {
				val = sval << ((sizeof (val) - stride) << 3);
				*((uint64_t *)pos1) = ntohll(val);
				out += stride;
				sval += delta;
				pos1 += stride;
			}
		}
	}
	*dstlen = out;
	return (0);
}