/* Copyright (C) 2009 J.F.Dockes
* 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.,
* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#ifndef TEST_CIRCACHE
#include "autoconfig.h"
#include <stdio.h>
#include <assert.h>
#include <errno.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <sys/types.h>
#include <sys/uio.h>
#include <unistd.h>
#include <stdlib.h>
#include <memory.h>
#include <zlib.h>
#include <sstream>
#include <iostream>
#include <map>
#include "circache.h"
#include "conftree.h"
#include "debuglog.h"
#include "smallut.h"
#include "md5.h"
using namespace std;
typedef unsigned char UCHAR;
typedef unsigned int UINT;
typedef unsigned long ULONG;
static bool inflateToDynBuf(void *inp, UINT inlen, void **outpp, UINT *outlenp);
/*
* File structure:
* - Starts with a 1-KB header block, with a param dictionary.
* - Stored items follow. Each item has a header and 2 segments for
* the metadata and the data.
* The segment sizes are stored in the ascii header/marker:
* circacheSizes = xxx yyy zzz
* xxx bytes of metadata
* yyy bytes of data
* zzz bytes of padding up to next object (only one entry has non zero)
*
* There is a write position, which can be at eof while
* the file is growing, or inside the file if we are recycling. This is stored
* in the header (oheadoffs), together with the maximum size
*
* If we are recycling, we have to take care to compute the size of the
* possible remaining area from the last object invalidated by the write,
* pad it with neutral data and store the size in the new header. To help with
* this, the address for the last object written is also kept in the header
* (nheadoffs, npadsize)
*
*/
// First block size
#define CIRCACHE_FIRSTBLOCK_SIZE 1024
// Entry header.
// 3 x 32 bits sizes as hex integers + 1 x 16 bits flag + at least 1 zero
// 15 + 3x(9) + 3 + 1 = 46
static const char *headerformat = "circacheSizes = %x %x %x %hx";
#define CIRCACHE_HEADER_SIZE 64
class EntryHeaderData {
public:
EntryHeaderData() : dicsize(0), datasize(0), padsize(0), flags(0) {}
UINT dicsize;
UINT datasize;
UINT padsize;
unsigned short flags;
};
enum EntryFlags {EFNone = 0, EFDataCompressed = 1};
// A callback class for the header-hopping function.
class CCScanHook {
public:
virtual ~CCScanHook() {}
enum status {Stop, Continue, Error, Eof};
virtual status takeone(off_t offs, const string& udi,
const EntryHeaderData& d) = 0;
};
// We have an auxiliary in-memory multimap of hashed-udi -> offset to
// speed things up. This is created the first time the file is scanned
// (on the first get), and not saved to disk.
// The map key: hashed udi. As a very short hash seems sufficient,
// maybe we could find something faster/simpler than md5?
#define UDIHLEN 4
class UdiH {
public:
UCHAR h[UDIHLEN];
UdiH(const string& udi)
{
MD5_CTX ctx;
MD5Init(&ctx);
MD5Update(&ctx, (const UCHAR*)udi.c_str(), udi.length());
UCHAR md[16];
MD5Final(md, &ctx);
memcpy(h, md, UDIHLEN);
}
string asHexString() const {
static const char hex[]="0123456789abcdef";
string out;
for (int i = 0; i < UDIHLEN; i++) {
out.append(1, hex[h[i] >> 4]);
out.append(1, hex[h[i] & 0x0f]);
}
return out;
}
bool operator==(const UdiH& r) const
{
for (int i = 0; i < UDIHLEN; i++)
if (h[i] != r.h[i])
return false;
return true;
}
bool operator<(const UdiH& r) const
{
for (int i = 0; i < UDIHLEN; i++) {
if (h[i] < r.h[i])
return true;
if (h[i] > r.h[i])
return false;
}
return false;
}
};
typedef multimap<UdiH, off_t> kh_type;
typedef multimap<UdiH, off_t>::value_type kh_value_type;
class CirCacheInternal {
public:
int m_fd;
////// These are cache persistent state and written to the first block:
// Maximum file size, after which we begin reusing old space
off_t m_maxsize;
// Offset of the oldest header.
off_t m_oheadoffs;
// Offset of last write (newest header)
off_t m_nheadoffs;
// Pad size for newest entry.
int m_npadsize;
// Keep history or only last entry
bool m_uniquentries;
///////////////////// End header entries
// A place to hold data when reading
char *m_buffer;
size_t m_bufsiz;
// Error messages
ostringstream m_reason;
// State for rewind/next/getcurrent operation. This could/should
// be moved to a separate iterator.
off_t m_itoffs;
EntryHeaderData m_ithd;
// Offset cache
kh_type m_ofskh;
bool m_ofskhcplt; // Has cache been fully read since open?
// Add udi->offset translation to map
bool khEnter(const string& udi, off_t ofs)
{
UdiH h(udi);
LOGDEB2(("Circache::khEnter: h %s offs %lu udi [%s]\n",
h.asHexString().c_str(), (ULONG)ofs, udi.c_str()));
pair<kh_type::iterator, kh_type::iterator> p = m_ofskh.equal_range(h);
if (p.first != m_ofskh.end() && p.first->first == h) {
for (kh_type::iterator it = p.first; it != p.second; it++) {
LOGDEB2(("Circache::khEnter: col h %s, ofs %lu\n",
it->first.asHexString().c_str(),
(ULONG)it->second));
if (it->second == ofs) {
// (h,offs) already there. Happens
LOGDEB2(("Circache::khEnter: already there\n"));
return true;
}
}
}
m_ofskh.insert(kh_value_type(h, ofs));
LOGDEB2(("Circache::khEnter: inserted\n"));
return true;
}
void khDump()
{
for (kh_type::const_iterator it = m_ofskh.begin();
it != m_ofskh.end(); it++) {
LOGDEB(("Circache::KHDUMP: %s %d\n",
it->first.asHexString().c_str(), (ULONG)it->second));
}
}
// Return list of candidate offsets for udi (possibly several
// because there may be hash collisions, and also multiple
// instances).
bool khFind(const string& udi, vector<off_t>& ofss)
{
ofss.clear();
UdiH h(udi);
LOGDEB2(("Circache::khFind: h %s udi [%s]\n",
h.asHexString().c_str(), udi.c_str()));
pair<kh_type::iterator, kh_type::iterator> p = m_ofskh.equal_range(h);
#if 0
if (p.first == m_ofskh.end()) LOGDEB(("KHFIND: FIRST END()\n"));
if (p.second == m_ofskh.end()) LOGDEB(("KHFIND: SECOND END()\n"));
if (!(p.first->first == h))
LOGDEB(("KHFIND: NOKEY: %s %s\n",
p.first->first.asHexString().c_str(),
p.second->first.asHexString().c_str()));
#endif
if (p.first == m_ofskh.end() || !(p.first->first == h))
return false;
for (kh_type::iterator it = p.first; it != p.second; it++) {
ofss.push_back(it->second);
}
return true;
}
// Clear entry for udi/offs
bool khClear(const pair<string, off_t>& ref)
{
UdiH h(ref.first);
pair<kh_type::iterator, kh_type::iterator> p = m_ofskh.equal_range(h);
if (p.first != m_ofskh.end() && (p.first->first == h)) {
for (kh_type::iterator it = p.first; it != p.second; ) {
kh_type::iterator tmp = it++;
if (tmp->second == ref.second)
m_ofskh.erase(tmp);
}
}
return true;
}
// Clear entries for list of udi/offs
bool khClear(const list<pair<string, off_t> >& udis)
{
for (list<pair<string, off_t> >::const_iterator it = udis.begin();
it != udis.end(); it++)
khClear(*it);
return true;
}
// Clear all entries for udi
bool khClear(const string& udi)
{
UdiH h(udi);
pair<kh_type::iterator, kh_type::iterator> p = m_ofskh.equal_range(h);
if (p.first != m_ofskh.end() && (p.first->first == h)) {
for (kh_type::iterator it = p.first; it != p.second; ) {
kh_type::iterator tmp = it++;
m_ofskh.erase(tmp);
}
}
return true;
}
CirCacheInternal()
: m_fd(-1), m_maxsize(-1), m_oheadoffs(-1),
m_nheadoffs(0), m_npadsize(0), m_uniquentries(false),
m_buffer(0), m_bufsiz(0), m_ofskhcplt(false)
{}
~CirCacheInternal()
{
if (m_fd >= 0)
close(m_fd);
if (m_buffer)
free(m_buffer);
}
char *buf(size_t sz)
{
if (m_bufsiz >= sz)
return m_buffer;
if ((m_buffer = (char *)realloc(m_buffer, sz))) {
m_bufsiz = sz;
} else {
m_reason << "CirCache:: realloc(" << sz << ") failed";
m_bufsiz = 0;
}
return m_buffer;
}
// Name for the cache file
string datafn(const string& d)
{
return path_cat(d, "circache.crch");
}
bool writefirstblock()
{
assert(m_fd >= 0);
ostringstream s;
s <<
"maxsize = " << m_maxsize << "\n" <<
"oheadoffs = " << m_oheadoffs << "\n" <<
"nheadoffs = " << m_nheadoffs << "\n" <<
"npadsize = " << m_npadsize << "\n" <<
"unient = " << m_uniquentries << "\n" <<
" " <<
" " <<
" " <<
"\0";
int sz = int(s.str().size());
assert(sz < CIRCACHE_FIRSTBLOCK_SIZE);
lseek(m_fd, 0, 0);
if (write(m_fd, s.str().c_str(), sz) != sz) {
m_reason << "writefirstblock: write() failed: errno " << errno;
return false;
}
return true;
}
bool readfirstblock()
{
assert(m_fd >= 0);
char bf[CIRCACHE_FIRSTBLOCK_SIZE];
lseek(m_fd, 0, 0);
if (read(m_fd, bf, CIRCACHE_FIRSTBLOCK_SIZE) !=
CIRCACHE_FIRSTBLOCK_SIZE) {
m_reason << "readfirstblock: read() failed: errno " << errno;
return false;
}
string s(bf, CIRCACHE_FIRSTBLOCK_SIZE);
ConfSimple conf(s, 1);
string value;
if (!conf.get("maxsize", value, "")) {
m_reason << "readfirstblock: conf get maxsize failed";
return false;
}
m_maxsize = atol(value.c_str());
if (!conf.get("oheadoffs", value, "")) {
m_reason << "readfirstblock: conf get oheadoffs failed";
return false;
}
m_oheadoffs = atol(value.c_str());
if (!conf.get("nheadoffs", value, "")) {
m_reason << "readfirstblock: conf get nheadoffs failed";
return false;
}
m_nheadoffs = atol(value.c_str());
if (!conf.get("npadsize", value, "")) {
m_reason << "readfirstblock: conf get npadsize failed";
return false;
}
m_npadsize = atol(value.c_str());
if (!conf.get("unient", value, "")) {
m_uniquentries = false;
} else {
m_uniquentries = stringToBool(value);
}
return true;
}
bool writeEntryHeader(off_t offset, const EntryHeaderData& d)
{
char bf[CIRCACHE_HEADER_SIZE];
memset(bf, 0, CIRCACHE_HEADER_SIZE);
snprintf(bf, CIRCACHE_HEADER_SIZE,
headerformat, d.dicsize, d.datasize, d.padsize, d.flags);
if (lseek(m_fd, offset, 0) != offset) {
m_reason << "CirCache::weh: lseek(" << offset <<
") failed: errno " << errno;
return false;
}
if (write(m_fd, bf, CIRCACHE_HEADER_SIZE) != CIRCACHE_HEADER_SIZE) {
m_reason << "CirCache::weh: write failed. errno " << errno;
return false;
}
return true;
}
CCScanHook::status readEntryHeader(off_t offset, EntryHeaderData& d)
{
assert(m_fd >= 0);
if (lseek(m_fd, offset, 0) != offset) {
m_reason << "readEntryHeader: lseek(" << offset <<
") failed: errno " << errno;
return CCScanHook::Error;
}
char bf[CIRCACHE_HEADER_SIZE];
int ret = read(m_fd, bf, CIRCACHE_HEADER_SIZE);
if (ret == 0) {
// Eof
m_reason << " Eof ";
return CCScanHook::Eof;
}
if (ret != CIRCACHE_HEADER_SIZE) {
m_reason << " readheader: read failed errno " << errno;
return CCScanHook::Error;
}
if (sscanf(bf, headerformat, &d.dicsize, &d.datasize,
&d.padsize, &d.flags) != 4) {
m_reason << " readEntryHeader: bad header at " <<
offset << " [" << bf << "]";
return CCScanHook::Error;
}
LOGDEB2(("Circache:readEntryHeader: dcsz %u dtsz %u pdsz %u flgs %hu\n",
d.dicsize, d.datasize, d.padsize, d.flags));
return CCScanHook::Continue;
}
CCScanHook::status scan(off_t startoffset, CCScanHook *user,
bool fold = false)
{
assert(m_fd >= 0);
off_t so0 = startoffset;
bool already_folded = false;
while (true) {
if (already_folded && startoffset == so0) {
m_ofskhcplt = true;
return CCScanHook::Eof;
}
EntryHeaderData d;
CCScanHook::status st;
switch ((st = readEntryHeader(startoffset, d))) {
case CCScanHook::Continue: break;
case CCScanHook::Eof:
if (fold && !already_folded) {
already_folded = true;
startoffset = CIRCACHE_FIRSTBLOCK_SIZE;
continue;
}
/* FALLTHROUGH */
default:
return st;
}
string udi;
if (d.dicsize) {
// d.dicsize is 0 for erased entries
char *bf;
if ((bf = buf(d.dicsize+1)) == 0) {
return CCScanHook::Error;
}
bf[d.dicsize] = 0;
if (read(m_fd, bf, d.dicsize) != int(d.dicsize)) {
m_reason << "scan: read failed errno " << errno;
return CCScanHook::Error;
}
string b(bf, d.dicsize);
ConfSimple conf(b, 1);
if (!conf.get("udi", udi, "")) {
m_reason << "scan: no udi in dic";
return CCScanHook::Error;
}
khEnter(udi, startoffset);
}
// Call callback
CCScanHook::status a =
user->takeone(startoffset, udi, d);
switch (a) {
case CCScanHook::Continue:
break;
default:
return a;
}
startoffset += CIRCACHE_HEADER_SIZE + d.dicsize +
d.datasize + d.padsize;
}
}
bool readHUdi(off_t hoffs, EntryHeaderData& d, string& udi)
{
if (readEntryHeader(hoffs, d) != CCScanHook::Continue)
return false;
string dic;
if (!readDicData(hoffs, d, dic, 0))
return false;
if (d.dicsize == 0) {
// This is an erased entry
udi.erase();
return true;
}
ConfSimple conf(dic);
if (!conf.get("udi", udi)) {
m_reason << "Bad file: no udi in dic";
return false;
}
return true;
}
bool readDicData(off_t hoffs, EntryHeaderData& hd, string& dic,
string* data)
{
off_t offs = hoffs + CIRCACHE_HEADER_SIZE;
// This syscall could be avoided in some cases if we saved the offset
// at each seek. In most cases, we just read the header and we are
// at the right position
if (lseek(m_fd, offs, 0) != offs) {
m_reason << "CirCache::get: lseek(" << offs << ") failed: " <<
errno;
return false;
}
char *bf = 0;
if (hd.dicsize) {
bf = buf(hd.dicsize);
if (bf == 0)
return false;
if (read(m_fd, bf, hd.dicsize) != int(hd.dicsize)) {
m_reason << "CirCache::get: read() failed: errno " << errno;
return false;
}
dic.assign(bf, hd.dicsize);
} else {
dic.erase();
}
if (data == 0)
return true;
if (hd.datasize) {
bf = buf(hd.datasize);
if (bf == 0)
return false;
if (read(m_fd, bf, hd.datasize) != int(hd.datasize)){
m_reason << "CirCache::get: read() failed: errno " << errno;
return false;
}
if (hd.flags & EFDataCompressed) {
LOGDEB1(("Circache:readdicdata: data compressed\n"));
void *uncomp;
unsigned int uncompsize;
if (!inflateToDynBuf(bf, hd.datasize, &uncomp, &uncompsize)) {
m_reason << "CirCache: decompression failed ";
return false;
}
data->assign((char *)uncomp, uncompsize);
free(uncomp);
} else {
LOGDEB1(("Circache:readdicdata: data NOT compressed\n"));
data->assign(bf, hd.datasize);
}
} else {
data->erase();
}
return true;
}
};
CirCache::CirCache(const string& dir)
: m_dir(dir)
{
m_d = new CirCacheInternal;
LOGDEB0(("CirCache: [%s]\n", m_dir.c_str()));
}
CirCache::~CirCache()
{
delete m_d;
m_d = 0;
}
string CirCache::getReason()
{
return m_d ? m_d->m_reason.str() : "Not initialized";
}
bool CirCache::create(off_t m_maxsize, int flags)
{
LOGDEB(("CirCache::create: [%s] flags 0x%x\n", m_dir.c_str(), flags));
assert(m_d != 0);
struct stat st;
if (stat(m_dir.c_str(), &st) < 0) {
if (mkdir(m_dir.c_str(), 0777) < 0) {
m_d->m_reason << "CirCache::create: mkdir(" << m_dir <<
") failed" << " errno " << errno;
return false;
}
} else {
if (!(flags & CC_CRTRUNCATE))
return open(CC_OPWRITE);
}
if ((m_d->m_fd = ::open(m_d->datafn(m_dir).c_str(),
O_CREAT | O_RDWR | O_TRUNC,
0666)) < 0) {
m_d->m_reason << "CirCache::create: open/creat(" <<
m_d->datafn(m_dir) << ") failed " << "errno " << errno;
return false;
}
m_d->m_maxsize = m_maxsize;
m_d->m_oheadoffs = CIRCACHE_FIRSTBLOCK_SIZE;
m_d->m_uniquentries = ((flags & CC_CRUNIQUE) != 0);
char buf[CIRCACHE_FIRSTBLOCK_SIZE];
memset(buf, 0, CIRCACHE_FIRSTBLOCK_SIZE);
if (::write(m_d->m_fd, buf, CIRCACHE_FIRSTBLOCK_SIZE) !=
CIRCACHE_FIRSTBLOCK_SIZE) {
m_d->m_reason << "CirCache::create: write header failed, errno "
<< errno;
return false;
}
return m_d->writefirstblock();
}
bool CirCache::open(OpMode mode)
{
assert(m_d != 0);
if (m_d->m_fd >= 0)
::close(m_d->m_fd);
if ((m_d->m_fd = ::open(m_d->datafn(m_dir).c_str(),
mode == CC_OPREAD ? O_RDONLY : O_RDWR)) < 0) {
m_d->m_reason << "CirCache::open: open(" << m_d->datafn(m_dir) <<
") failed " << "errno " << errno;
return false;
}
return m_d->readfirstblock();
}
class CCScanHookDump : public CCScanHook {
public:
virtual status takeone(off_t offs, const string& udi,
const EntryHeaderData& d)
{
cout << "Scan: offs " << offs << " dicsize " << d.dicsize
<< " datasize " << d.datasize << " padsize " << d.padsize <<
" flags " << d.flags <<
" udi [" << udi << "]" << endl;
return Continue;
}
};
bool CirCache::dump()
{
CCScanHookDump dumper;
// Start at oldest header. This is eof while the file is growing, scan will
// fold to bot at once.
off_t start = m_d->m_oheadoffs;
switch (m_d->scan(start, &dumper, true)) {
case CCScanHook::Stop:
cout << "Scan returns Stop??" << endl;
return false;
case CCScanHook::Continue:
cout << "Scan returns Continue ?? " << CCScanHook::Continue << " " <<
getReason() << endl;
return false;
case CCScanHook::Error:
cout << "Scan returns Error: " << getReason() << endl;
return false;
case CCScanHook::Eof:
cout << "Scan returns Eof (ok)" << endl;
return true;
default:
cout << "Scan returns Unknown ??" << endl;
return false;
}
}
class CCScanHookGetter : public CCScanHook {
public:
string m_udi;
int m_targinstance;
int m_instance;
off_t m_offs;
EntryHeaderData m_hd;
CCScanHookGetter(const string &udi, int ti)
: m_udi(udi), m_targinstance(ti), m_instance(0), m_offs(0){}
virtual status takeone(off_t offs, const string& udi,
const EntryHeaderData& d)
{
LOGDEB2(("Circache:Scan: off %ld udi [%s] dcsz %u dtsz %u pdsz %u "
" flgs %hu\n",
long(offs), udi.c_str(), (UINT)d.dicsize,
(UINT)d.datasize, (UINT)d.padsize, d.flags));
if (!m_udi.compare(udi)) {
m_instance++;
m_offs = offs;
m_hd = d;
if (m_instance == m_targinstance)
return Stop;
}
return Continue;
}
};
// instance == -1 means get latest. Otherwise specify from 1+
bool CirCache::get(const string& udi, string& dic, string& data, int instance)
{
Chrono chron;
assert(m_d != 0);
if (m_d->m_fd < 0) {
m_d->m_reason << "CirCache::get: not open";
return false;
}
LOGDEB0(("CirCache::get: udi [%s], instance %d\n", udi.c_str(), instance));
// If memory map is up to date, use it:
if (m_d->m_ofskhcplt) {
LOGDEB1(("CirCache::get: using ofskh\n"));
//m_d->khDump();
vector<off_t> ofss;
if (m_d->khFind(udi, ofss)) {
LOGDEB1(("Circache::get: h found, colls %d\n", ofss.size()));
int finst = 1;
EntryHeaderData d_good;
off_t o_good = 0;
for (vector<off_t>::iterator it = ofss.begin();
it != ofss.end(); it++) {
LOGDEB1(("Circache::get: trying offs %lu\n", (ULONG)*it));
EntryHeaderData d;
string fudi;
if (!m_d->readHUdi(*it, d, fudi))
return false;
if (!fudi.compare(udi)) {
// Found one, memorize offset. Done if instance
// matches, else go on. If instance is -1 need to
// go to the end of the list anyway
d_good = d;
o_good = *it;
if (finst == instance) {
break;
} else {
finst++;
}
}
}
// Did we read an appropriate entry ?
if (o_good != 0 && (instance == -1 || instance == finst)) {
bool ret = m_d->readDicData(o_good, d_good, dic, &data);
LOGDEB0(("Circache::get: hfound, %d mS\n",
chron.millis()));
return ret;
}
// Else try to scan anyway.
}
}
CCScanHookGetter getter(udi, instance);
off_t start = m_d->m_oheadoffs;
CCScanHook::status ret = m_d->scan(start, &getter, true);
if (ret == CCScanHook::Eof) {
if (getter.m_instance == 0)
return false;
} else if (ret != CCScanHook::Stop) {
return false;
}
bool bret =
m_d->readDicData(getter.m_offs, getter.m_hd, dic, &data);
LOGDEB0(("Circache::get: scanfound, %d mS\n", chron.millis()));
return bret;
}
bool CirCache::erase(const string& udi)
{
assert(m_d != 0);
if (m_d->m_fd < 0) {
m_d->m_reason << "CirCache::erase: not open";
return false;
}
LOGDEB0(("CirCache::erase: udi [%s]\n", udi.c_str()));
// If the mem cache is not up to date, update it, we're too lazy
// to do a scan
if (!m_d->m_ofskhcplt) {
string dic, data;
get("nosuchudi probably exists", dic, data);
if (!m_d->m_ofskhcplt) {
LOGERR(("CirCache::erase : cache not updated after get\n"));
return false;
}
}
vector<off_t> ofss;
if (!m_d->khFind(udi, ofss)) {
// Udi not in there, erase ok
LOGDEB(("CirCache::erase: khFind returns none\n"));
return true;
}
for (vector<off_t>::iterator it = ofss.begin(); it != ofss.end(); it++) {
LOGDEB(("CirCache::erase: reading at %lu\n", (unsigned long)*it));
EntryHeaderData d;
string fudi;
if (!m_d->readHUdi(*it, d, fudi))
return false;
LOGDEB(("CirCache::erase: found fudi [%s]\n", fudi.c_str()));
if (!fudi.compare(udi)) {
EntryHeaderData nd;
nd.padsize = d.dicsize + d.datasize + d.padsize;
LOGDEB(("CirCache::erase: rewriting at %lu\n", (unsigned long)*it));
if (*it == m_d->m_nheadoffs)
m_d->m_npadsize = nd.padsize;
if(!m_d->writeEntryHeader(*it, nd)) {
LOGERR(("CirCache::erase: write header failed\n"));
return false;
}
}
}
m_d->khClear(udi);
return true;
}
// Used to scan the file ahead until we accumulated enough space for the new
// entry.
class CCScanHookSpacer : public CCScanHook {
public:
UINT sizewanted;
UINT sizeseen;
list<pair<string, off_t> > squashed_udis;
CCScanHookSpacer(int sz)
: sizewanted(sz), sizeseen(0) {assert(sz > 0);}
virtual status takeone(off_t offs, const string& udi,
const EntryHeaderData& d)
{
LOGDEB2(("Circache:ScanSpacer:off %u dcsz %u dtsz %u pdsz %u udi[%s]\n",
(UINT)offs, d.dicsize, d.datasize, d.padsize, udi.c_str()));
sizeseen += CIRCACHE_HEADER_SIZE + d.dicsize + d.datasize + d.padsize;
squashed_udis.push_back(make_pair(udi, offs));
if (sizeseen >= sizewanted)
return Stop;
return Continue;
}
};
bool CirCache::put(const string& udi, const ConfSimple *iconf,
const string& data, unsigned int iflags)
{
assert(m_d != 0);
if (m_d->m_fd < 0) {
m_d->m_reason << "CirCache::put: not open";
return false;
}
// We need the udi in input metadata
string dic;
if (!iconf || !iconf->get("udi", dic) || dic.empty() || dic.compare(udi)) {
m_d->m_reason << "No/bad 'udi' entry in input dic";
LOGERR(("Circache::put: no/bad udi: DIC:[%s] UDI [%s]\n",
dic.c_str(), udi.c_str()));
return false;
}
// Possibly erase older entries. Need to do this first because we may be
// able to reuse the space if the same udi was last written
if (m_d->m_uniquentries && !erase(udi)) {
LOGERR(("CirCache::put: can't erase older entries\n"));
return false;
}
ostringstream s;
iconf->write(s);
dic = s.str();
// Data compression ?
const char *datap = data.c_str();
unsigned int datalen = data.size();
unsigned short flags = 0;
TempBuf compbuf;
if (!(iflags & NoCompHint)) {
ULONG len = compressBound(data.size());
char *bf = compbuf.setsize(len);
if (bf != 0 &&
compress((Bytef*)bf, &len, (Bytef*)data.c_str(), data.size())
== Z_OK) {
if (float(len) < 0.9 * float(data.size())) {
// bf is local but it's our static buffer address
datap = bf;
datalen = len;
flags |= EFDataCompressed;
}
}
}
struct stat st;
if (fstat(m_d->m_fd, &st) < 0) {
m_d->m_reason << "CirCache::put: fstat failed. errno " << errno;
return false;
}
// Characteristics for the new entry.
int nsize = CIRCACHE_HEADER_SIZE + dic.size() + datalen;
int nwriteoffs = m_d->m_oheadoffs;
int npadsize = 0;
bool extending = false;
LOGDEB(("CirCache::put: nsz %d oheadoffs %d\n", nsize, m_d->m_oheadoffs));
// Check if we can recover some pad space from the (physically) previous
// entry.
int recovpadsize = m_d->m_oheadoffs == CIRCACHE_FIRSTBLOCK_SIZE ?
0 : m_d->m_npadsize;
if (recovpadsize != 0) {
// Need to read the latest entry's header, to rewrite it with a
// zero pad size
EntryHeaderData pd;
if (m_d->readEntryHeader(m_d->m_nheadoffs, pd) != CCScanHook::Continue){
return false;
}
assert(int(pd.padsize) == m_d->m_npadsize);
if (pd.dicsize == 0) {
// erased entry. Also recover the header space, no need to rewrite
// the header, we're going to write on it.
recovpadsize += CIRCACHE_HEADER_SIZE;
} else {
LOGDEB(("CirCache::put: recov. prev. padsize %d\n", pd.padsize));
pd.padsize = 0;
if (!m_d->writeEntryHeader(m_d->m_nheadoffs, pd))
return false;
// If we fail between here and the end, the file is broken.
}
nwriteoffs = m_d->m_oheadoffs - recovpadsize;
}
if (nsize <= recovpadsize) {
// If the new entry fits entirely in the pad area from the
// latest one, no need to recycle stuff
LOGDEB(("CirCache::put: new fits in old padsize %d\n", recovpadsize));
npadsize = recovpadsize - nsize;
} else if (st.st_size < m_d->m_maxsize) {
// Still growing the file.
npadsize = 0;
extending = true;
} else {
// Scan the file until we have enough space for the new entry,
// and determine the pad size up to the 1st preserved entry
int scansize = nsize - recovpadsize;
LOGDEB(("CirCache::put: scanning for size %d from offs %u\n",
scansize, (UINT)m_d->m_oheadoffs));
CCScanHookSpacer spacer(scansize);
switch (m_d->scan(m_d->m_oheadoffs, &spacer)) {
case CCScanHook::Stop:
LOGDEB(("CirCache::put: Scan ok, sizeseen %d\n",
spacer.sizeseen));
npadsize = spacer.sizeseen - scansize;
break;
case CCScanHook::Eof:
npadsize = 0;
extending = true;
break;
case CCScanHook::Continue:
case CCScanHook::Error:
return false;
}
// Take the recycled entries off the multimap
m_d->khClear(spacer.squashed_udis);
}
LOGDEB(("CirCache::put: writing %d at %d padsize %d\n",
nsize, nwriteoffs, npadsize));
if (lseek(m_d->m_fd, nwriteoffs, 0) != nwriteoffs) {
m_d->m_reason << "CirCache::put: lseek failed: " << errno;
return false;
}
char head[CIRCACHE_HEADER_SIZE];
memset(head, 0, CIRCACHE_HEADER_SIZE);
snprintf(head, CIRCACHE_HEADER_SIZE,
headerformat, dic.size(), datalen, npadsize, flags);
struct iovec vecs[3];
vecs[0].iov_base = head;
vecs[0].iov_len = CIRCACHE_HEADER_SIZE;
vecs[1].iov_base = (void *)dic.c_str();
vecs[1].iov_len = dic.size();
vecs[2].iov_base = (void *)datap;
vecs[2].iov_len = datalen;
if (writev(m_d->m_fd, vecs, 3) != nsize) {
m_d->m_reason << "put: write failed. errno " << errno;
if (extending)
if (ftruncate(m_d->m_fd, m_d->m_oheadoffs) == -1) {
m_d->m_reason << "put: ftruncate failed. errno " << errno;
}
return false;
}
m_d->khEnter(udi, nwriteoffs);
// Update first block information
m_d->m_nheadoffs = nwriteoffs;
m_d->m_npadsize = npadsize;
// New oldest header is the one just after the one we just wrote.
m_d->m_oheadoffs = nwriteoffs + nsize + npadsize;
if (nwriteoffs + nsize >= m_d->m_maxsize) {
// Max size or top of file reached, next write at BOT.
m_d->m_oheadoffs = CIRCACHE_FIRSTBLOCK_SIZE;
}
return m_d->writefirstblock();
}
bool CirCache::rewind(bool& eof)
{
assert(m_d != 0);
eof = false;
// Read oldest header
m_d->m_itoffs = m_d->m_oheadoffs;
CCScanHook::status st = m_d->readEntryHeader(m_d->m_itoffs, m_d->m_ithd);
switch(st) {
case CCScanHook::Eof:
eof = true;
return false;
case CCScanHook::Continue:
return true;
default:
return false;
}
}
bool CirCache::next(bool& eof)
{
assert(m_d != 0);
eof = false;
// Skip to next header, using values stored from previous one
m_d->m_itoffs += CIRCACHE_HEADER_SIZE + m_d->m_ithd.dicsize +
m_d->m_ithd.datasize + m_d->m_ithd.padsize;
// Looped back ?
if (m_d->m_itoffs == m_d->m_oheadoffs) {
eof = true;
return false;
}
// Read. If we hit physical eof, fold.
CCScanHook::status st = m_d->readEntryHeader(m_d->m_itoffs, m_d->m_ithd);
if (st == CCScanHook::Eof) {
m_d->m_itoffs = CIRCACHE_FIRSTBLOCK_SIZE;
if (m_d->m_itoffs == m_d->m_oheadoffs) {
// Then the file is not folded yet (still growing)
eof = true;
return false;
}
st = m_d->readEntryHeader(m_d->m_itoffs, m_d->m_ithd);
}
if (st == CCScanHook::Continue)
return true;
return false;
}
bool CirCache::getCurrentUdi(string& udi)
{
assert(m_d != 0);
if (!m_d->readHUdi(m_d->m_itoffs, m_d->m_ithd, udi))
return false;
return true;
}
bool CirCache::getCurrent(string& udi, string& dic, string& data)
{
assert(m_d != 0);
if (!m_d->readDicData(m_d->m_itoffs, m_d->m_ithd, dic, &data))
return false;
ConfSimple conf(dic, 1);
conf.get("udi", udi, "");
return true;
}
void *
allocmem(void *cp, /* The array to grow. may be NULL */
int sz, /* Unit size in bytes */
int *np, /* Pointer to current allocation number */
int min, /* Number to allocate the first time */
int maxinc) /* Maximum increment */
{
if (cp == 0) {
cp = malloc(min * sz);
*np = cp ? min : 0;
return cp;
}
int inc = (*np > maxinc) ? : *np;
if ((cp = realloc(cp, (*np + inc) * sz)) != 0)
*np += inc;
return cp;
}
static bool inflateToDynBuf(void* inp, UINT inlen, void **outpp, UINT *outlenp)
{
z_stream d_stream; /* decompression stream */
LOGDEB0(("inflateToDynBuf: inlen %u\n", inlen));
d_stream.zalloc = (alloc_func)0;
d_stream.zfree = (free_func)0;
d_stream.opaque = (voidpf)0;
// Compression works well on html files, 4-6 is quite common, Otoh we
// maybe passed a big, little if at all compressed image or pdf file,
// So we set the initial allocation at 3 times the input size
const int imul = 3;
const int mxinc = 20;
char *outp = 0;
int alloc = 0;
d_stream.next_in = (Bytef*)inp;
d_stream.avail_in = inlen;
d_stream.next_out = 0;
d_stream.avail_out = 0;
int err;
if ((err = inflateInit(&d_stream)) != Z_OK) {
LOGERR(("Inflate: inflateInit: err %d msg %s\n", err, d_stream.msg));
free(outp);
return false;
}
for (;;) {
LOGDEB2(("InflateToDynBuf: avail_in %d total_in %d avail_out %d "
"total_out %d\n", d_stream.avail_in, d_stream.total_in,
d_stream.avail_out, d_stream.total_out));
if (d_stream.avail_out == 0) {
if ((outp = (char*)allocmem(outp, inlen, &alloc,
imul, mxinc)) == 0) {
LOGERR(("Inflate: out of memory, current alloc %d\n",
alloc*inlen));
inflateEnd(&d_stream);
return false;
} else {
LOGDEB2(("inflateToDynBuf: realloc(%d) ok\n", alloc * inlen));
}
d_stream.avail_out = alloc * inlen - d_stream.total_out;
d_stream.next_out = (Bytef*)(outp + d_stream.total_out);
}
err = inflate(&d_stream, Z_NO_FLUSH);
if (err == Z_STREAM_END) break;
if (err != Z_OK) {
LOGERR(("Inflate: error %d msg %s\n", err, d_stream.msg));
inflateEnd(&d_stream);
free(outp);
return false;
}
}
*outlenp = d_stream.total_out;
*outpp = (Bytef *)outp;
if ((err = inflateEnd(&d_stream)) != Z_OK) {
LOGERR(("Inflate: inflateEnd error %d msg %s\n", err, d_stream.msg));
return false;
}
LOGDEB0(("inflateToDynBuf: ok, output size %d\n", d_stream.total_out));
return true;
}
#else // TEST ->
#include "autoconfig.h"
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <string>
#include <iostream>
#include "circache.h"
#include "fileudi.h"
#include "conftree.h"
#include "readfile.h"
#include "debuglog.h"
using namespace std;
static char *thisprog;
static char usage [] =
" -c [-u] <dirname> : create\n"
" -p <dirname> <apath> [apath ...] : put files\n"
" -d <dirname> : dump\n"
" -g [-i instance] [-D] <dirname> <udi>: get\n"
" -D: also dump data\n"
;
static void
Usage(FILE *fp = stderr)
{
fprintf(fp, "%s: usage:\n%s", thisprog, usage);
exit(1);
}
static int op_flags;
#define OPT_MOINS 0x1
#define OPT_c 0x2
#define OPT_p 0x8
#define OPT_g 0x10
#define OPT_d 0x20
#define OPT_i 0x40
#define OPT_D 0x80
#define OPT_u 0x100
int main(int argc, char **argv)
{
int instance = -1;
thisprog = argv[0];
argc--; argv++;
while (argc > 0 && **argv == '-') {
(*argv)++;
if (!(**argv))
/* Cas du "adb - core" */
Usage();
while (**argv)
switch (*(*argv)++) {
case 'c': op_flags |= OPT_c; break;
case 'p': op_flags |= OPT_p; break;
case 'g': op_flags |= OPT_g; break;
case 'd': op_flags |= OPT_d; break;
case 'D': op_flags |= OPT_D; break;
case 'u': op_flags |= OPT_u; break;
case 'i': op_flags |= OPT_i; if (argc < 2) Usage();
if ((sscanf(*(++argv), "%d", &instance)) != 1)
Usage();
argc--;
goto b1;
default: Usage(); break;
}
b1: argc--; argv++;
}
DebugLog::getdbl()->setloglevel(DEBDEB1);
DebugLog::setfilename("stderr");
if (argc < 1)
Usage();
string dir = *argv++;argc--;
CirCache cc(dir);
if (op_flags & OPT_c) {
int flags = 0;
if (op_flags & OPT_u)
flags |= CirCache::CC_CRUNIQUE;
if (!cc.create(100*1024, flags)) {
cerr << "Create failed:" << cc.getReason() << endl;
exit(1);
}
} else if (op_flags & OPT_p) {
if (argc < 1)
Usage();
if (!cc.open(CirCache::CC_OPWRITE)) {
cerr << "Open failed: " << cc.getReason() << endl;
exit(1);
}
while (argc) {
string fn = *argv++;argc--;
char dic[1000];
string data, reason;
if (!file_to_string(fn, data, &reason)) {
cerr << "File_to_string: " << reason << endl;
exit(1);
}
string udi;
make_udi(fn, "", udi);
sprintf(dic, "#whatever...\nmimetype = text/plain\nudi=%s\n",
udi.c_str());
string sdic;
sdic.assign(dic, strlen(dic));
ConfSimple conf(sdic);
if (!cc.put(udi, &conf, data, 0)) {
cerr << "Put failed: " << cc.getReason() << endl;
cerr << "conf: ["; conf.write(cerr); cerr << "]" << endl;
exit(1);
}
}
cc.open(CirCache::CC_OPREAD);
} else if (op_flags & OPT_g) {
if (!cc.open(CirCache::CC_OPREAD)) {
cerr << "Open failed: " << cc.getReason() << endl;
exit(1);
}
while (argc) {
string udi = *argv++;argc--;
string dic, data;
if (!cc.get(udi, dic, data, instance)) {
cerr << "Get failed: " << cc.getReason() << endl;
exit(1);
}
cout << "Dict: [" << dic << "]" << endl;
if (op_flags & OPT_D)
cout << "Data: [" << data << "]" << endl;
}
} else if (op_flags & OPT_d) {
if (!cc.open(CirCache::CC_OPREAD)) {
cerr << "Open failed: " << cc.getReason() << endl;
exit(1);
}
cc.dump();
} else
Usage();
exit(0);
}
#endif