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compression.cpp
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compression.cpp
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#ifdef __APPLE__
#define _DARWIN_UNLIMITED_STREAMS
#endif
#include "compression.hpp"
#include "errors.hpp"
#include "protozero/varint.hpp"
#include "serial.hpp"
void decompressor::begin() {
within = true;
zs.zalloc = NULL;
zs.zfree = NULL;
zs.opaque = NULL;
zs.msg = (char *) "";
int d = inflateInit(&zs);
if (d != Z_OK) {
fprintf(stderr, "initialize decompression: %d %s\n", d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
}
int decompressor::fread(void *p, size_t size, size_t nmemb, std::atomic<long long> *geompos) {
zs.next_out = (Bytef *) p;
zs.avail_out = size * nmemb;
while (zs.avail_out > 0) {
if (zs.avail_in == 0) {
size_t n = ::fread((Bytef *) buf.c_str(), sizeof(char), buf.size(), fp);
if (n == 0) {
if (within) {
fprintf(stderr, "Reached EOF while decompressing\n");
exit(EXIT_IMPOSSIBLE);
} else {
break;
}
}
zs.next_in = (Bytef *) buf.c_str();
zs.avail_in = n;
}
size_t avail_before = zs.avail_in;
if (within) {
int d = inflate(&zs, Z_NO_FLUSH);
*geompos += avail_before - zs.avail_in;
if (d == Z_OK) {
// it made some progress
} else if (d == Z_STREAM_END) {
// it may have made some progress and now we are done
within = false;
break;
} else {
fprintf(stderr, "decompression error %d %s\n", d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
} else {
size_t n = std::min(zs.avail_in, zs.avail_out);
memcpy(zs.next_out, zs.next_in, n);
*geompos += n;
zs.avail_out -= n;
zs.avail_in -= n;
zs.next_out += n;
zs.next_in += n;
}
}
return (size * nmemb - zs.avail_out) / size;
}
void decompressor::end(std::atomic<long long> *geompos) {
// "within" means that we haven't received end-of-stream yet,
// so consume more compressed data until we get there.
// This can be necessary if the caller knows that it is at
// the end of the feature stream (because it got a 0-length
// feature) but the decompressor doesn't know yet.
if (within) {
while (true) {
if (zs.avail_in == 0) {
size_t n = ::fread((Bytef *) buf.c_str(), sizeof(char), buf.size(), fp);
zs.next_in = (Bytef *) buf.c_str();
zs.avail_in = n;
}
zs.avail_out = 0;
size_t avail_before = zs.avail_in;
int d = inflate(&zs, Z_NO_FLUSH);
*geompos += avail_before - zs.avail_in;
if (d == Z_STREAM_END) {
break;
}
if (d == Z_OK) {
continue;
}
fprintf(stderr, "decompression: got %d, not Z_STREAM_END\n", d);
exit(EXIT_IMPOSSIBLE);
}
within = false;
}
int d = inflateEnd(&zs);
if (d != Z_OK) {
fprintf(stderr, "end decompression: %d %s\n", d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
}
int decompressor::deserialize_ulong_long(unsigned long long *zigzag, std::atomic<long long> *geompos) {
*zigzag = 0;
int shift = 0;
while (1) {
char c;
if (fread(&c, sizeof(char), 1, geompos) != 1) {
return 0;
}
if ((c & 0x80) == 0) {
*zigzag |= ((unsigned long long) c) << shift;
shift += 7;
break;
} else {
*zigzag |= ((unsigned long long) (c & 0x7F)) << shift;
shift += 7;
}
}
return 1;
}
int decompressor::deserialize_long_long(long long *n, std::atomic<long long> *geompos) {
unsigned long long zigzag = 0;
int ret = deserialize_ulong_long(&zigzag, geompos);
*n = protozero::decode_zigzag64(zigzag);
return ret;
}
int decompressor::deserialize_int(int *n, std::atomic<long long> *geompos) {
long long ll = 0;
int ret = deserialize_long_long(&ll, geompos);
*n = ll;
return ret;
}
int decompressor::deserialize_uint(unsigned *n, std::atomic<long long> *geompos) {
unsigned long long v;
deserialize_ulong_long(&v, geompos);
*n = v;
return 1;
}
void compressor::begin() {
zs.zalloc = NULL;
zs.zfree = NULL;
zs.opaque = NULL;
zs.msg = (char *) "";
int d = deflateInit(&zs, Z_DEFAULT_COMPRESSION);
if (d != Z_OK) {
fprintf(stderr, "initialize compression: %d %s\n", d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
}
void compressor::compressor::end(std::atomic<long long> *fpos, const char *fname) {
std::string buf;
buf.resize(5000);
if (zs.avail_in != 0) {
fprintf(stderr, "compression end called with data available\n");
exit(EXIT_IMPOSSIBLE);
}
zs.next_in = (Bytef *) buf.c_str();
zs.avail_in = 0;
while (true) {
zs.next_out = (Bytef *) buf.c_str();
zs.avail_out = buf.size();
int d = deflate(&zs, Z_FINISH);
::fwrite_check(buf.c_str(), sizeof(char), zs.next_out - (Bytef *) buf.c_str(), fp, fpos, fname);
if (d == Z_OK || d == Z_BUF_ERROR) {
// it can take several calls to flush out all the buffered data
continue;
}
if (d != Z_STREAM_END) {
fprintf(stderr, "%s: finish compression: %d %s\n", fname, d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
break;
}
zs.next_out = (Bytef *) buf.c_str();
zs.avail_out = buf.size();
int d = deflateEnd(&zs);
if (d != Z_OK) {
fprintf(stderr, "%s: end compression: %d %s\n", fname, d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
::fwrite_check(buf.c_str(), sizeof(char), zs.next_out - (Bytef *) buf.c_str(), fp, fpos, fname);
}
int compressor::fclose() {
return ::fclose(fp);
}
void compressor::fwrite_check(const char *p, size_t size, size_t nmemb, std::atomic<long long> *fpos, const char *fname) {
std::string buf;
buf.resize(size * nmemb * 2 + 200);
zs.next_in = (Bytef *) p;
zs.avail_in = size * nmemb;
while (zs.avail_in > 0) {
zs.next_out = (Bytef *) buf.c_str();
zs.avail_out = buf.size();
int d = deflate(&zs, Z_NO_FLUSH);
if (d != Z_OK) {
fprintf(stderr, "%s: deflate: %d %s\n", fname, d, zs.msg);
exit(EXIT_IMPOSSIBLE);
}
::fwrite_check(buf.c_str(), sizeof(char), zs.next_out - (Bytef *) buf.c_str(), fp, fpos, fname);
}
}
void compressor::serialize_ulong_long(unsigned long long val, std::atomic<long long> *fpos, const char *fname) {
while (1) {
unsigned char b = val & 0x7F;
if ((val >> 7) != 0) {
b |= 0x80;
fwrite_check((const char *) &b, 1, 1, fpos, fname);
val >>= 7;
} else {
fwrite_check((const char *) &b, 1, 1, fpos, fname);
break;
}
}
}
void compressor::serialize_long_long(long long val, std::atomic<long long> *fpos, const char *fname) {
unsigned long long zigzag = protozero::encode_zigzag64(val);
serialize_ulong_long(zigzag, fpos, fname);
}
void compressor::serialize_int(int val, std::atomic<long long> *fpos, const char *fname) {
serialize_long_long(val, fpos, fname);
}
void compressor::serialize_uint(unsigned val, std::atomic<long long> *fpos, const char *fname) {
serialize_ulong_long(val, fpos, fname);
}