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lzokay
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Jack Andersen 2018-12-23 15:43:24 -10:00
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CMakeLists.txt Normal file
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cmake_minimum_required(VERSION 3.10)
project(lzokay)
add_library(lzokay lzokay.hpp lzokay.cpp)
set(LZOKAY_INCLUDE_DIR ${CMAKE_CURRENT_SOURCE_DIR} CACHE PATH "lzokay include path" FORCE)
add_executable(lzokaytest test.cpp)
target_link_libraries(lzokaytest lzokay)

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The MIT License
Copyright (c) 2018 Jack Andersen
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.

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LZ👌
===
A minimal, C++14 implementation of the
[LZO compression format](http://www.oberhumer.com/opensource/lzo/).
Objective
---------
The implementation provides compression behavior similar to the
`lzo1x_999_compress` function in `lzo2` (i.e. higher compression, lower speed).
The implementation is fixed to the default parameters of the original and
provides no facilities for various compression "levels" or an initialization
dictionary.
The decompressor is compatible with data compressed by other LZO1X
implementations.
Usage
-----
```cpp
#include <lzokay.hpp>
#include <cstring>
int compress_and_decompress(const uint8_t* data, std::size_t length) {
lzokay::EResult error;
/* This variable and 5th parameter of compress() is optional, but may
* be reused across multiple compression runs; avoiding repeat
* allocation/deallocation of the work memory used by the compressor.
*/
lzokay::Dict<> dict;
std::size_t compressed_size = lzokay::compress_worst_size(length);
std::unique_ptr<uint8_t[]> compressed(new uint8_t[compressed_size]);
error = lzokay::compress(data, length, compressed.get(), compressed_size, dict);
if (error < lzokay::EResult::Success)
return 1;
std::unique_ptr<uint8_t[]> decompressed(new uint8_t[length]);
std::size_t decompressed_size = length;
error = lzokay::decompress(compressed.get(), compressed_size,
decompressed.get(), decompressed_size);
if (error < lzokay::EResult::Success)
return 1;
if (std::memcmp(data, decompressed.get(), decompressed_size) != 0)
return 1;
return 0;
}
```
License
-------
LZ👌 is available under the
[MIT License](https://github.com/jackoalan/lzokay/blob/master/LICENSE)
and has no external dependencies.

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lzokay.cpp Normal file
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#include "lzokay.hpp"
#include <cstring>
#include <algorithm>
/*
* Based on documentation from the Linux sources: Documentation/lzo.txt
* https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/Documentation/lzo.txt
*/
namespace lzokay {
#if _WIN32
#define HOST_BIG_ENDIAN 0
#elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
#define HOST_BIG_ENDIAN 1
#else
#define HOST_BIG_ENDIAN 0
#endif
#if HOST_BIG_ENDIAN
static uint16_t get_le16(const uint8_t* p) {
uint16_t val = *reinterpret_cast<const uint16_t*>(p);
#if __GNUC__
return __builtin_bswap16(val);
#elif _WIN32
return _byteswap_ushort(val);
#else
return (val = (val << 8) | ((val >> 8) & 0xFF));
#endif
}
#else
static uint16_t get_le16(const uint8_t* p) {
return *reinterpret_cast<const uint16_t*>(p);
}
#endif
static constexpr std::size_t Max255Count = std::size_t(~0) / 255 - 2;
#define NEEDS_IN(count) \
if (inp + (count) > inp_end) { \
dst_size = outp - dst; \
return EResult::InputOverrun; \
}
#define NEEDS_OUT(count) \
if (outp + (count) > outp_end) { \
dst_size = outp - dst; \
return EResult::OutputOverrun; \
}
#define CONSUME_ZERO_BYTE_LENGTH \
std::size_t offset; \
{ \
const uint8_t *old_inp = inp; \
while (*inp == 0) ++inp; \
offset = inp - old_inp; \
if (offset > Max255Count) { \
dst_size = outp - dst; \
return EResult::Error; \
} \
}
#define WRITE_ZERO_BYTE_LENGTH(length) \
{ \
std::size_t l; \
for (l = length; l > 255; l -= 255) { *outp++ = 0; } \
*outp++ = l; \
}
static constexpr uint32_t M1MaxOffset = 0x0400;
static constexpr uint32_t M2MaxOffset = 0x0800;
static constexpr uint32_t M3MaxOffset = 0x4000;
static constexpr uint32_t M4MaxOffset = 0xbfff;
static constexpr uint32_t M1MinLen = 2;
static constexpr uint32_t M1MaxLen = 2;
static constexpr uint32_t M2MinLen = 3;
static constexpr uint32_t M2MaxLen = 8;
static constexpr uint32_t M3MinLen = 3;
static constexpr uint32_t M3MaxLen = 33;
static constexpr uint32_t M4MinLen = 3;
static constexpr uint32_t M4MaxLen = 9;
static constexpr uint32_t M1Marker = 0x0;
static constexpr uint32_t M2Marker = 0x40;
static constexpr uint32_t M3Marker = 0x20;
static constexpr uint32_t M4Marker = 0x10;
static constexpr uint32_t MaxMatchByLengthLen = 34; /* Max M3 len + 1 */
EResult decompress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size) {
if (src_size < 3) {
dst_size = 0;
return EResult::InputOverrun;
}
const uint8_t* inp = src;
const uint8_t* inp_end = src + src_size;
uint8_t* outp = dst;
uint8_t* outp_end = dst + dst_size;
uint8_t* lbcur;
std::size_t lblen;
std::size_t state = 0;
std::size_t nstate = 0;
/* First byte encoding */
if (*inp >= 22) {
/* 22..255 : copy literal string
* length = (byte - 17) = 4..238
* state = 4 [ don't copy extra literals ]
* skip byte
*/
std::size_t len = *inp++ - uint8_t(17);
NEEDS_IN(len)
NEEDS_OUT(len)
for (std::size_t i = 0; i < len; ++i)
*outp++ = *inp++;
state = 4;
} else if (*inp >= 18) {
/* 18..21 : copy 0..3 literals
* state = (byte - 17) = 0..3 [ copy <state> literals ]
* skip byte
*/
nstate = *inp++ - uint8_t(17);
state = nstate;
NEEDS_IN(nstate)
NEEDS_OUT(nstate)
for (std::size_t i = 0; i < nstate; ++i)
*outp++ = *inp++;
}
/* 0..17 : follow regular instruction encoding, see below. It is worth
* noting that codes 16 and 17 will represent a block copy from
* the dictionary which is empty, and that they will always be
* invalid at this place.
*/
while (true) {
NEEDS_IN(1)
uint8_t inst = *inp++;
if (inst & 0xC0) {
/* [M2]
* 1 L L D D D S S (128..255)
* Copy 5-8 bytes from block within 2kB distance
* state = S (copy S literals after this block)
* length = 5 + L
* Always followed by exactly one byte : H H H H H H H H
* distance = (H << 3) + D + 1
*
* 0 1 L D D D S S (64..127)
* Copy 3-4 bytes from block within 2kB distance
* state = S (copy S literals after this block)
* length = 3 + L
* Always followed by exactly one byte : H H H H H H H H
* distance = (H << 3) + D + 1
*/
NEEDS_IN(1)
lbcur = outp - ((*inp++ << 3) + ((inst >> 2) & 0x7) + 1);
lblen = std::size_t(inst >> 5) + 1;
nstate = inst & uint8_t(0x3);
} else if (inst & M3Marker) {
/* [M3]
* 0 0 1 L L L L L (32..63)
* Copy of small block within 16kB distance (preferably less than 34B)
* length = 2 + (L ?: 31 + (zero_bytes * 255) + non_zero_byte)
* Always followed by exactly one LE16 : D D D D D D D D : D D D D D D S S
* distance = D + 1
* state = S (copy S literals after this block)
*/
lblen = std::size_t(inst & uint8_t(0x1f)) + 2;
if (lblen == 2) {
CONSUME_ZERO_BYTE_LENGTH
NEEDS_IN(1)
lblen += offset * 255 + 31 + *inp++;
}
NEEDS_IN(2)
nstate = get_le16(inp);
inp += 2;
lbcur = outp - ((nstate >> 2) + 1);
nstate &= 0x3;
} else if (inst & M4Marker) {
/* [M4]
* 0 0 0 1 H L L L (16..31)
* Copy of a block within 16..48kB distance (preferably less than 10B)
* length = 2 + (L ?: 7 + (zero_bytes * 255) + non_zero_byte)
* Always followed by exactly one LE16 : D D D D D D D D : D D D D D D S S
* distance = 16384 + (H << 14) + D
* state = S (copy S literals after this block)
* End of stream is reached if distance == 16384
*/
lblen = std::size_t(inst & uint8_t(0x7)) + 2;
if (lblen == 2) {
CONSUME_ZERO_BYTE_LENGTH
NEEDS_IN(1)
lblen += offset * 255 + 7 + *inp++;
}
NEEDS_IN(2)
nstate = get_le16(inp);
inp += 2;
lbcur = outp - (((inst & 0x8) << 11) + (nstate >> 2));
nstate &= 0x3;
if (lbcur == outp)
break; /* Stream finished */
lbcur -= 16384;
} else {
/* [M1] Depends on the number of literals copied by the last instruction. */
if (state == 0) {
/* If last instruction did not copy any literal (state == 0), this
* encoding will be a copy of 4 or more literal, and must be interpreted
* like this :
*
* 0 0 0 0 L L L L (0..15) : copy long literal string
* length = 3 + (L ?: 15 + (zero_bytes * 255) + non_zero_byte)
* state = 4 (no extra literals are copied)
*/
std::size_t len = inst + 3;
if (len == 3) {
CONSUME_ZERO_BYTE_LENGTH
NEEDS_IN(1)
len += offset * 255 + 15 + *inp++;
}
/* copy_literal_run */
NEEDS_IN(len)
NEEDS_OUT(len)
for (std::size_t i = 0; i < len; ++i)
*outp++ = *inp++;
state = 4;
continue;
} else if (state != 4) {
/* If last instruction used to copy between 1 to 3 literals (encoded in
* the instruction's opcode or distance), the instruction is a copy of a
* 2-byte block from the dictionary within a 1kB distance. It is worth
* noting that this instruction provides little savings since it uses 2
* bytes to encode a copy of 2 other bytes but it encodes the number of
* following literals for free. It must be interpreted like this :
*
* 0 0 0 0 D D S S (0..15) : copy 2 bytes from <= 1kB distance
* length = 2
* state = S (copy S literals after this block)
* Always followed by exactly one byte : H H H H H H H H
* distance = (H << 2) + D + 1
*/
NEEDS_IN(1)
nstate = inst & uint8_t(0x3);
lbcur = outp - ((inst >> 2) + (*inp++ << 2) + 1);
lblen = 2;
} else {
/* If last instruction used to copy 4 or more literals (as detected by
* state == 4), the instruction becomes a copy of a 3-byte block from the
* dictionary from a 2..3kB distance, and must be interpreted like this :
*
* 0 0 0 0 D D S S (0..15) : copy 3 bytes from 2..3 kB distance
* length = 3
* state = S (copy S literals after this block)
* Always followed by exactly one byte : H H H H H H H H
* distance = (H << 2) + D + 2049
*/
NEEDS_IN(1)
nstate = inst & uint8_t(0x3);
lbcur = outp - ((inst >> 2) + (*inp++ << 2) + 2049);
lblen = 3;
}
}
if (lbcur < dst) {
dst_size = outp - dst;
return EResult::LookbehindOverrun;
}
NEEDS_IN(nstate)
NEEDS_OUT(lblen + nstate)
/* Copy lookbehind */
for (std::size_t i = 0; i < lblen; ++i)
*outp++ = *lbcur++;
state = nstate;
/* Copy literal */
for (std::size_t i = 0; i < nstate; ++i)
*outp++ = *inp++;
}
dst_size = outp - dst;
if (lblen != 3) /* Ensure terminating M4 was encountered */
return EResult::Error;
if (inp == inp_end)
return EResult::Success;
else if (inp < inp_end)
return EResult::InputNotConsumed;
else
return EResult::InputOverrun;
}
struct State {
const uint8_t* src;
const uint8_t* src_end;
const uint8_t* inp;
uint32_t wind_sz;
uint32_t wind_b;
uint32_t wind_e;
uint32_t cycle1_countdown;
const uint8_t* bufp;
uint32_t buf_sz;
/* Access next input byte and advance both ends of circular buffer */
void get_byte(uint8_t* buf) {
if (inp >= src_end) {
if (wind_sz > 0)
--wind_sz;
buf[wind_e] = 0;
if (wind_e < DictBase::MaxMatchLen)
buf[DictBase::BufSize + wind_e] = 0;
} else {
buf[wind_e] = *inp;
if (wind_e < DictBase::MaxMatchLen)
buf[DictBase::BufSize + wind_e] = *inp;
++inp;
}
if (++wind_e == DictBase::BufSize)
wind_e = 0;
if (++wind_b == DictBase::BufSize)
wind_b = 0;
}
uint32_t pos2off(uint32_t pos) const {
return wind_b > pos ? wind_b - pos : DictBase::BufSize - (pos - wind_b);
}
};
class DictImpl : public DictBase {
public:
struct Match3Impl : DictBase::Match3 {
static uint32_t make_key(const uint8_t* data) {
return ((0x9f5f * (((uint32_t(data[0]) << 5 ^ uint32_t(data[1])) << 5) ^ data[2])) >> 5) & 0x3fff;
}
uint16_t get_head(uint32_t key) const {
return (chain_sz[key] == 0) ? uint16_t(UINT16_MAX) : head[key];
}
void init() {
std::fill(std::begin(chain_sz), std::end(chain_sz), 0);
}
void remove(uint32_t pos, const uint8_t* b) {
--chain_sz[make_key(b + pos)];
}
void advance(State& s, uint32_t& match_pos, uint32_t& match_count, const uint8_t* b) {
uint32_t key = make_key(b + s.wind_b);
match_pos = chain[s.wind_b] = get_head(key);
match_count = chain_sz[key]++;
if (match_count > DictBase::MaxMatchLen)
match_count = DictBase::MaxMatchLen;
head[key] = uint16_t(s.wind_b);
}
void skip_advance(State& s, const uint8_t* b) {
uint32_t key = make_key(b + s.wind_b);
chain[s.wind_b] = get_head(key);
head[key] = uint16_t(s.wind_b);
best_len[s.wind_b] = uint16_t(DictBase::MaxMatchLen + 1);
chain_sz[key]++;
}
};
struct Match2Impl : DictBase::Match2 {
static uint32_t make_key(const uint8_t* data) {
return uint32_t(data[0]) ^ (uint32_t(data[1]) << 8);
}
void init() {
std::fill(std::begin(head), std::end(head), UINT16_MAX);
}
void add(uint16_t pos, const uint8_t* b) {
head[make_key(b + pos)] = pos;
}
void remove(uint32_t pos, const uint8_t* b) {
uint16_t& p = head[make_key(b + pos)];
if (p == pos)
p = UINT16_MAX;
}
bool search(State& s, uint32_t& lb_pos, uint32_t& lb_len,
uint32_t best_pos[MaxMatchByLengthLen], const uint8_t* b) const {
uint16_t pos = head[make_key(b + s.wind_b)];
if (pos == UINT16_MAX)
return false;
if (best_pos[2] == 0)
best_pos[2] = pos + 1;
if (lb_len < 2) {
lb_len = 2;
lb_pos = pos;
}
return true;
}
};
void init(State& s, const uint8_t* src, std::size_t src_size) {
auto& match3 = static_cast<Match3Impl&>(_storage->match3);
auto& match2 = static_cast<Match2Impl&>(_storage->match2);
s.cycle1_countdown = DictBase::MaxDist;
match3.init();
match2.init();
s.src = src;
s.src_end = src + src_size;
s.inp = src;
s.wind_sz = uint32_t(std::min(src_size, std::size_t(MaxMatchLen)));
s.wind_b = 0;
s.wind_e = s.wind_sz;
std::copy_n(s.inp, s.wind_sz, _storage->buffer);
s.inp += s.wind_sz;
if (s.wind_e == DictBase::BufSize)
s.wind_e = 0;
if (s.wind_sz < 3)
std::fill_n(_storage->buffer + s.wind_b + s.wind_sz, 3, 0);
}
void reset_next_input_entry(State& s, Match3Impl& match3, Match2Impl& match2) {
/* Remove match from about-to-be-clobbered buffer entry */
if (s.cycle1_countdown == 0) {
match3.remove(s.wind_e, _storage->buffer);
match2.remove(s.wind_e, _storage->buffer);
} else {
--s.cycle1_countdown;
}
}
void advance(State& s, uint32_t& lb_off, uint32_t& lb_len,
uint32_t best_off[MaxMatchByLengthLen], bool skip) {
auto& match3 = static_cast<Match3Impl&>(_storage->match3);
auto& match2 = static_cast<Match2Impl&>(_storage->match2);
if (skip) {
for (uint32_t i = 0; i < lb_len - 1; ++i) {
reset_next_input_entry(s, match3, match2);
match3.skip_advance(s, _storage->buffer);
match2.add(uint16_t(s.wind_b), _storage->buffer);
s.get_byte(_storage->buffer);
}
}
lb_len = 1;
lb_off = 0;
uint32_t lb_pos;
uint32_t best_pos[MaxMatchByLengthLen] = {};
uint32_t match_pos, match_count;
match3.advance(s, match_pos, match_count, _storage->buffer);
int best_char = _storage->buffer[s.wind_b];
uint32_t best_len = lb_len;
if (lb_len >= s.wind_sz) {
if (s.wind_sz == 0)
best_char = -1;
lb_off = 0;
match3.best_len[s.wind_b] = DictBase::MaxMatchLen + 1;
} else {
if (match2.search(s, lb_pos, lb_len, best_pos, _storage->buffer) && s.wind_sz >= 3) {
for (uint32_t i = 0; i < match_count; ++i, match_pos = match3.chain[match_pos]) {
auto ref_ptr = _storage->buffer + s.wind_b;
auto match_ptr = _storage->buffer + match_pos;
auto mismatch = std::mismatch(ref_ptr, ref_ptr + s.wind_sz, match_ptr);
auto match_len = uint32_t(mismatch.first - ref_ptr);
if (match_len < 2)
continue;
if (match_len < MaxMatchByLengthLen && best_pos[match_len] == 0)
best_pos[match_len] = match_pos + 1;
if (match_len > lb_len) {
lb_len = match_len;
lb_pos = match_pos;
if (match_len == s.wind_sz || match_len > match3.best_len[match_pos])
break;
}
}
}
if (lb_len > best_len)
lb_off = s.pos2off(lb_pos);
match3.best_len[s.wind_b] = uint16_t(lb_len);
for (auto posit = std::begin(best_pos) + 2, offit = best_off + 2;
posit != std::end(best_pos); ++posit, ++offit) {
*offit = (*posit > 0) ? s.pos2off(*posit - 1) : 0;
}
}
reset_next_input_entry(s, match3, match2);
match2.add(uint16_t(s.wind_b), _storage->buffer);
s.get_byte(_storage->buffer);
if (best_char < 0) {
s.buf_sz = 0;
lb_len = 0;
/* Signal exit */
} else {
s.buf_sz = s.wind_sz + 1;
}
s.bufp = s.inp - s.buf_sz;
}
};
static void find_better_match(const uint32_t best_off[MaxMatchByLengthLen], uint32_t& lb_len, uint32_t& lb_off) {
if (lb_len <= M2MinLen || lb_off <= M2MaxOffset)
return;
if (lb_off > M2MaxOffset && lb_len >= M2MinLen + 1 && lb_len <= M2MaxLen + 1 &&
best_off[lb_len - 1] != 0 && best_off[lb_len - 1] <= M2MaxOffset) {
lb_len -= 1;
lb_off = best_off[lb_len];
} else if (lb_off > M3MaxOffset && lb_len >= M4MaxLen + 1 && lb_len <= M2MaxLen + 2 &&
best_off[lb_len - 2] && best_off[lb_len] <= M2MaxOffset) {
lb_len -= 2;
lb_off = best_off[lb_len];
} else if (lb_off > M3MaxOffset && lb_len >= M4MaxLen + 1 && lb_len <= M3MaxLen + 1 &&
best_off[lb_len - 1] != 0 && best_off[lb_len - 2] <= M3MaxOffset) {
lb_len -= 1;
lb_off = best_off[lb_len];
}
}
static EResult encode_literal_run(uint8_t*& outp, const uint8_t* outp_end, const uint8_t* dst, std::size_t& dst_size,
const uint8_t* lit_ptr, uint32_t lit_len) {
if (outp == dst && lit_len <= 238) {
NEEDS_OUT(1);
*outp++ = uint8_t(17 + lit_len);
} else if (lit_len <= 3) {
outp[-2] = uint8_t(outp[-2] | lit_len);
} else if (lit_len <= 18) {
NEEDS_OUT(1);
*outp++ = uint8_t(lit_len - 3);
} else {
NEEDS_OUT((lit_len - 18) / 255 + 2);
*outp++ = 0;
WRITE_ZERO_BYTE_LENGTH(lit_len - 18);
}
NEEDS_OUT(lit_len);
outp = std::copy_n(lit_ptr, lit_len, outp);
return EResult::Success;
}
static EResult encode_lookback_match(uint8_t*& outp, const uint8_t* outp_end, const uint8_t* dst, std::size_t& dst_size,
uint32_t lb_len, uint32_t lb_off, uint32_t last_lit_len) {
if (lb_len == 2) {
lb_off -= 1;
NEEDS_OUT(2);
*outp++ = uint8_t(M1Marker | ((lb_off & 0x3) << 2));
*outp++ = uint8_t(lb_off >> 2);
} else if (lb_len <= M2MaxLen && lb_off <= M2MaxOffset) {
lb_off -= 1;
NEEDS_OUT(2);
*outp++ = uint8_t((lb_len - 1) << 5 | ((lb_off & 0x7) << 2));
*outp++ = uint8_t(lb_off >> 3);
} else if (lb_len == M2MinLen && lb_off <= M1MaxOffset + M2MaxOffset && last_lit_len >= 4) {
lb_off -= 1 + M2MaxOffset;
NEEDS_OUT(2);
*outp++ = uint8_t(M1Marker | ((lb_off & 0x3) << 2));
*outp++ = uint8_t(lb_off >> 2);
} else if (lb_off <= M3MaxOffset) {
lb_off -= 1;
if (lb_len <= M3MaxLen) {
NEEDS_OUT(1);
*outp++ = uint8_t(M3Marker | (lb_len - 2));
} else {
lb_len -= M3MaxLen;
NEEDS_OUT(lb_len / 255 + 2);
*outp++ = uint8_t(M3Marker);
WRITE_ZERO_BYTE_LENGTH(lb_len);
}
NEEDS_OUT(2);
*outp++ = uint8_t(lb_off << 2);
*outp++ = uint8_t(lb_off >> 6);
} else {
lb_off -= 0x4000;
if (lb_len <= M4MaxLen) {
NEEDS_OUT(1);
*outp++ = uint8_t(M4Marker | ((lb_off & 0x4000) >> 11) | (lb_len - 2));
} else {
lb_len -= M4MaxLen;
NEEDS_OUT(lb_len / 255 + 2);
*outp++ = uint8_t(M4Marker | ((lb_off & 0x4000) >> 11));
WRITE_ZERO_BYTE_LENGTH(lb_len);
}
NEEDS_OUT(2);
*outp++ = uint8_t(lb_off << 2);
*outp++ = uint8_t(lb_off >> 6);
}
return EResult::Success;
}
EResult compress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size, DictBase& dict) {
EResult err;
State s;
auto& d = static_cast<DictImpl&>(dict);
uint8_t* outp = dst;
uint8_t* outp_end = dst + dst_size;
uint32_t lit_len = 0;
uint32_t lb_off, lb_len;
uint32_t best_off[MaxMatchByLengthLen];
d.init(s, src, src_size);
const uint8_t* lit_ptr = s.inp;
d.advance(s, lb_off, lb_len, best_off, false);
while (s.buf_sz > 0) {
if (lit_len == 0)
lit_ptr = s.bufp;
if (lb_len < 2 || (lb_len == 2 && (lb_off > M1MaxOffset || lit_len == 0 || lit_len >= 4)) ||
(lb_len == 2 && outp == dst) || (outp == dst && lit_len == 0)) {
lb_len = 0;
} else if (lb_len == M2MinLen && lb_off > M1MaxOffset + M2MaxOffset && lit_len >= 4) {
lb_len = 0;
}
if (lb_len == 0) {
++lit_len;
d.advance(s, lb_off, lb_len, best_off, false);
continue;
}
find_better_match(best_off, lb_len, lb_off);
if ((err = encode_literal_run(outp, outp_end, dst, dst_size, lit_ptr, lit_len)) < EResult::Success)
return err;
if ((err = encode_lookback_match(outp, outp_end, dst, dst_size, lb_len, lb_off, lit_len)) < EResult::Success)
return err;
lit_len = 0;
d.advance(s, lb_off, lb_len, best_off, true);
}
if ((err = encode_literal_run(outp, outp_end, dst, dst_size, lit_ptr, lit_len)) < EResult::Success)
return err;
/* Terminating M4 */
NEEDS_OUT(3);
*outp++ = M4Marker | 1;
*outp++ = 0;
*outp++ = 0;
dst_size = outp - dst;
return EResult::Success;
}
}

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#pragma once
#include <cstddef>
#include <cstdint>
#include <memory>
namespace lzokay {
enum class EResult {
LookbehindOverrun = -4,
OutputOverrun = -3,
InputOverrun = -2,
Error = -1,
Success = 0,
InputNotConsumed = 1,
};
class DictBase {
protected:
static constexpr uint32_t HashSize = 0x4000;
static constexpr uint32_t MaxDist = 0xbfff;
static constexpr uint32_t MaxMatchLen = 0x800;
static constexpr uint32_t BufSize = MaxDist + MaxMatchLen;
/* List encoding of previous 3-byte data matches */
struct Match3 {
uint16_t head[HashSize]; /* key -> chain-head-pos */
uint16_t chain_sz[HashSize]; /* key -> chain-size */
uint16_t chain[BufSize]; /* chain-pos -> next-chain-pos */
uint16_t best_len[BufSize]; /* chain-pos -> best-match-length */
};
/* Encoding of 2-byte data matches */
struct Match2 {
uint16_t head[1 << 16]; /* 2-byte-data -> head-pos */
};
struct Data {
Match3 match3;
Match2 match2;
/* Circular buffer caching enough data to access the maximum lookback
* distance of 48K + maximum match length of 2K. An additional 2K is
* allocated so the start of the buffer may be replicated at the end,
* therefore providing efficient circular access.
*/
uint8_t buffer[BufSize + MaxMatchLen];
};
using storage_type = Data;
storage_type* _storage;
DictBase() = default;
friend struct State;
friend EResult compress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size, DictBase& dict);
};
template <template<typename> class _Alloc = std::allocator>
class Dict : public DictBase {
_Alloc<DictBase::storage_type> _allocator;
public:
Dict() { _storage = _allocator.allocate(1); }
~Dict() { _allocator.deallocate(_storage, 1); }
};
EResult decompress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size);
EResult compress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size, DictBase& dict);
inline EResult compress(const uint8_t* src, std::size_t src_size,
uint8_t* dst, std::size_t& dst_size) {
Dict<> dict;
return compress(src, src_size, dst, dst_size, dict);
}
constexpr std::size_t compress_worst_size(std::size_t s) {
return s + s / 16 + 64 + 3;
}
}

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#include "lzokay.hpp"
#include <cstring>
int compress_and_decompress(const uint8_t* data, std::size_t length) {
lzokay::EResult error;
/* This variable and 5th parameter of compress() is optional, but may
* be reused across multiple compression runs; avoiding repeat
* allocation/deallocation of the work memory used by the compressor.
*/
lzokay::Dict<> dict;
std::size_t compressed_size = lzokay::compress_worst_size(length);
std::unique_ptr<uint8_t[]> compressed(new uint8_t[compressed_size]);
error = lzokay::compress(data, length, compressed.get(), compressed_size, dict);
if (error < lzokay::EResult::Success)
return 1;
std::unique_ptr<uint8_t[]> decompressed(new uint8_t[length]);
std::size_t decompressed_size = length;
error = lzokay::decompress(compressed.get(), compressed_size,
decompressed.get(), decompressed_size);
if (error < lzokay::EResult::Success)
return 1;
if (std::memcmp(data, decompressed.get(), decompressed_size) != 0)
return 1;
return 0;
}
int main(int argc, char** argv) {
const char* testdata = "Hello World!";
int ret = compress_and_decompress(reinterpret_cast<const uint8_t*>(testdata), 12);
return ret;
}