RetroShare/libretroshare/src/file_sharing/hash_cache.cc

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/*
* RetroShare Hash cache
*
* file_sharing/hash_cache.cc
*
* Copyright 2016 Mr.Alice
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License Version 2 as published by the Free Software Foundation.
*
* This library 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
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
* USA.
*
* Please report all bugs and problems to "retroshare.project@gmail.com".
*
*/
#include "util/rsdir.h"
#include "util/rsprint.h"
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#include "rsserver/p3face.h"
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#include "pqi/authssl.h"
#include "hash_cache.h"
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#include "filelist_io.h"
#include "file_sharing_defaults.h"
#define HASHSTORAGE_DEBUG 1
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static const uint32_t DEFAULT_INACTIVITY_SLEEP_TIME = 50*1000;
static const uint32_t MAX_INACTIVITY_SLEEP_TIME = 2*1000*1000;
HashStorage::HashStorage(const std::string& save_file_name)
: mFilePath(save_file_name), mHashMtx("Hash Storage mutex")
{
mInactivitySleepTime = DEFAULT_INACTIVITY_SLEEP_TIME;
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mRunning = false ;
mLastSaveTime = 0 ;
{
RS_STACK_MUTEX(mHashMtx) ;
locked_load() ;
}
}
void HashStorage::data_tick()
{
FileHashJob job;
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RsFileHash hash;
uint64_t size ;
{
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bool empty ;
uint32_t st ;
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{
RS_STACK_MUTEX(mHashMtx) ;
if(mChanged && mLastSaveTime + MIN_INTERVAL_BETWEEN_HASH_CACHE_SAVE < time(NULL))
{
locked_save();
mLastSaveTime = time(NULL) ;
mChanged = false ;
}
}
{
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RS_STACK_MUTEX(mHashMtx) ;
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empty = mFilesToHash.empty();
st = mInactivitySleepTime ;
}
// sleep off mutex!
if(empty)
{
std::cerr << "nothing to hash. Sleeping for " << st << " us" << std::endl;
usleep(st); // when no files to hash, just wait for 2 secs. This avoids a dramatic loop.
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if(st > MAX_INACTIVITY_SLEEP_TIME)
{
RS_STACK_MUTEX(mHashMtx) ;
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mInactivitySleepTime = MAX_INACTIVITY_SLEEP_TIME;
if(!mChanged) // otherwise it might prevent from saving the hash cache
{
std::cerr << "Stopping hashing thread." << std::endl;
shutdown();
mRunning = false ;
std::cerr << "done." << std::endl;
}
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RsServer::notify()->notifyHashingInfo(NOTIFY_HASHTYPE_FINISH, "") ;
}
else
{
RS_STACK_MUTEX(mHashMtx) ;
mInactivitySleepTime = 2*st ;
}
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return ;
}
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mInactivitySleepTime = DEFAULT_INACTIVITY_SLEEP_TIME;
{
RS_STACK_MUTEX(mHashMtx) ;
job = mFilesToHash.begin()->second ;
mFilesToHash.erase(mFilesToHash.begin()) ;
}
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std::cerr << "Hashing file " << job.full_path << "..." ; std::cerr.flush();
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std::string tmpout;
//rs_sprintf(tmpout, "%lu/%lu (%s - %d%%) : %s", cnt+1, n_files, friendlyUnit(size).c_str(), int(size/double(total_size)*100.0), fe.name.c_str()) ;
RsServer::notify()->notifyHashingInfo(NOTIFY_HASHTYPE_HASH_FILE, job.full_path) ;
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if(!RsDirUtil::getFileHash(job.full_path, hash,size, this))
std::cerr << "ERROR: cannot hash file " << job.full_path << std::endl;
else
std::cerr << "done."<< std::endl;
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// store the result
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{
RS_STACK_MUTEX(mHashMtx) ;
HashStorageInfo& info(mFiles[job.full_path]);
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info.filename = job.full_path ;
info.size = size ;
info.modf_stamp = job.ts ;
info.time_stamp = time(NULL);
info.hash = hash;
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mChanged = true ;
}
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}
// call the client
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if(!hash.isNull())
job.client->hash_callback(job.client_param, job.full_path, hash, size);
}
bool HashStorage::requestHash(const std::string& full_path,uint64_t size,time_t mod_time,RsFileHash& known_hash,HashStorageClient *c,uint32_t client_param)
{
// check if the hash is up to date w.r.t. cache.
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#ifdef HASHSTORAGE_DEBUG
std::cerr << "HASH Requested for file " << full_path << ": ";
#endif
RS_STACK_MUTEX(mHashMtx) ;
time_t now = time(NULL) ;
std::map<std::string,HashStorageInfo>::iterator it = mFiles.find(full_path) ;
if(it != mFiles.end() && (uint64_t)mod_time == it->second.modf_stamp && size == it->second.size)
{
it->second.time_stamp = now ;
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known_hash = it->second.hash;
#ifdef HASHSTORAGE_DEBUG
std::cerr << "Found in cache." << std::endl ;
#endif
return true ;
}
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#ifdef HASHSTORAGE_DEBUG
std::cerr << "Not in cache. Scheduling for re-hash." << std::endl ;
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#endif
// we need to schedule a re-hashing
if(mFilesToHash.find(full_path) != mFilesToHash.end())
return false ;
FileHashJob job ;
job.client = c ;
job.client_param = client_param ;
job.full_path = full_path ;
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job.ts = mod_time ;
mFilesToHash[full_path] = job;
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if(!mRunning)
{
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mRunning = true ;
std::cerr << "Starting hashing thread." << std::endl;
start() ;
}
return false;
}
void HashStorage::clean()
{
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RS_STACK_MUTEX(mHashMtx) ;
#ifdef HASHSTORAGE_DEBUG
std::cerr << "Cleaning HashStorage..." << std::endl ;
#endif
time_t now = time(NULL) ;
time_t duration = mMaxStorageDurationDays * 24 * 3600 ; // seconds
#ifdef HASHSTORAGE_DEBUG
std::cerr << "cleaning hash cache." << std::endl ;
#endif
for(std::map<std::string,HashStorageInfo>::iterator it(mFiles.begin());it!=mFiles.end();)
if(it->second.time_stamp + duration < (uint64_t)now)
{
#ifdef HASHSTORAGE_DEBUG
std::cerr << " Entry too old: " << it->first << ", ts=" << it->second.time_stamp << std::endl ;
#endif
std::map<std::string,HashStorageInfo>::iterator tmp(it) ;
++tmp ;
mFiles.erase(it) ;
it=tmp ;
mChanged = true ;
}
else
++it ;
#ifdef HASHSTORAGE_DEBUG
std::cerr << "Done." << std::endl;
#endif
}
void HashStorage::locked_load()
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{
unsigned char *data = NULL ;
uint32_t data_size=0;
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if(!FileListIO::loadEncryptedDataFromFile(mFilePath,data,data_size))
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{
std::cerr << "(EE) Cannot read hash cache." << std::endl;
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return ;
}
uint32_t offset = 0 ;
HashStorageInfo info ;
uint32_t n=0;
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while(offset < data_size)
if(readHashStorageInfo(data,data_size,offset,info))
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{
#ifdef HASHSTORAGE_DEBUG
std::cerr << info << std::endl;
++n ;
#endif
mFiles[info.filename] = info ;
}
free(data) ;
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#ifdef HASHSTORAGE_DEBUG
std::cerr << n << " entries loaded." << std::endl ;
#endif
}
void HashStorage::locked_save()
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{
#ifdef HASHSTORAGE_DEBUG
std::cerr << "Saving Hash Cache to file " << mFilePath << "..." << std::endl ;
#endif
unsigned char *data = NULL ;
uint32_t offset = 0 ;
uint32_t total_size = 0;
for(std::map<std::string,HashStorageInfo>::const_iterator it(mFiles.begin());it!=mFiles.end();++it)
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writeHashStorageInfo(data,total_size,offset,it->second) ;
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if(!FileListIO::saveEncryptedDataToFile(mFilePath,data,offset))
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{
std::cerr << "(EE) Cannot save hash cache data." << std::endl;
free(data) ;
return ;
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}
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std::cerr << mFiles.size() << " Entries saved." << std::endl;
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free(data) ;
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}
bool HashStorage::readHashStorageInfo(const unsigned char *data,uint32_t total_size,uint32_t& offset,HashStorageInfo& info) const
{
unsigned char *section_data = NULL ;
uint32_t section_size = 0;
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uint32_t section_offset = 0;
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// This way, the entire section is either read or skipped. That avoids the risk of being stuck somewhere in the middle
// of a section because of some unknown field, etc.
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if(!FileListIO::readField(data,total_size,offset,FILE_LIST_IO_TAG_HASH_STORAGE_ENTRY,section_data,section_size))
return false;
if(!FileListIO::readField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_NAME ,info.filename )) return false ;
if(!FileListIO::readField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_SIZE ,info.size )) return false ;
if(!FileListIO::readField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_UPDATE_TS ,info.time_stamp)) return false ;
if(!FileListIO::readField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_MODIF_TS ,info.modf_stamp)) return false ;
if(!FileListIO::readField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_SHA1_HASH,info.hash )) return false ;
free(section_data);
return true;
}
bool HashStorage::writeHashStorageInfo(unsigned char *& data,uint32_t& total_size,uint32_t& offset,const HashStorageInfo& info) const
{
unsigned char *section_data = NULL ;
uint32_t section_offset = 0 ;
uint32_t section_size = 0;
if(!FileListIO::writeField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_NAME ,info.filename )) return false ;
if(!FileListIO::writeField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_SIZE ,info.size )) return false ;
if(!FileListIO::writeField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_UPDATE_TS ,info.time_stamp)) return false ;
if(!FileListIO::writeField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_MODIF_TS ,info.modf_stamp)) return false ;
if(!FileListIO::writeField(section_data,section_size,section_offset,FILE_LIST_IO_TAG_FILE_SHA1_HASH,info.hash )) return false ;
// now write the whole string into a single section in the file
if(!FileListIO::writeField(data,total_size,offset,FILE_LIST_IO_TAG_HASH_STORAGE_ENTRY,section_data,section_offset)) return false ;
std::cerr << "Writing hash storage section " << RsUtil::BinToHex(section_data,section_offset) << std::endl;
std::cerr << "Info.filename = " << info.filename << std::endl;
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free(section_data) ;
return true;
}
std::ostream& operator<<(std::ostream& o,const HashStorage::HashStorageInfo& info)
{
return o << info.hash << " " << info.size << " " << info.filename ;
}