RetroShare/libretroshare/src/gxs/rsgenexchange.cc

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/*
* libretroshare/src/gxs: rsgenexchange.cc
*
* RetroShare Gxs exchange interface.
*
* Copyright 2012-2012 by Christopher Evi-Parker, Robert Fernie
*
* 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@lunamutt.com".
*
*/
#include <unistd.h>
#include <openssl/err.h>
#include <openssl/ssl.h>
#include <openssl/evp.h>
#include <openssl/rsa.h>
#include "pqi/pqihash.h"
#include "rsgenexchange.h"
#include "gxssecurity.h"
#include "util/contentvalue.h"
#include "retroshare/rsgxsflags.h"
#include "rsgixs.h"
#define PUB_GRP_MASK 0x000f
#define RESTR_GRP_MASK 0x00f0
#define PRIV_GRP_MASK 0x0f00
#define GRP_OPTIONS_MASK 0xf000
#define PUB_GRP_OFFSET 0
#define RESTR_GRP_OFFSET 8
#define PRIV_GRP_OFFSET 16
#define GRP_OPTIONS_OFFSET 24
#define GXS_MASK "GXS_MASK_HACK"
#define GEN_EXCH_DEBUG 1
RsGenExchange::RsGenExchange(RsGeneralDataService *gds, RsNetworkExchangeService *ns,
RsSerialType *serviceSerialiser, uint16_t servType, RsGixs* gixs, uint32_t authenPolicy)
: mGenMtx("GenExchange"), mDataStore(gds), mNetService(ns), mSerialiser(serviceSerialiser),
mServType(servType), mGixs(gixs), mAuthenPolicy(authenPolicy)
{
mDataAccess = new RsGxsDataAccess(gds);
}
RsGenExchange::~RsGenExchange()
{
// need to destruct in a certain order (prob a bad thing!)
delete mNetService;
delete mDataAccess;
mDataAccess = NULL;
delete mDataStore;
mDataStore = NULL;
}
void RsGenExchange::run()
{
double timeDelta = 0.1; // slow tick
while(isRunning())
{
tick();
#ifndef WINDOWS_SYS
usleep((int) (timeDelta * 1000000));
#else
Sleep((int) (timeDelta * 1000));
#endif
}
}
void RsGenExchange::tick()
{
mDataAccess->processRequests();
publishGrps();
publishMsgs();
processGrpMetaChanges();
processMsgMetaChanges();
processRecvdData();
if(!mNotifications.empty())
{
notifyChanges(mNotifications);
mNotifications.clear();
}
// implemented service tick function
service_tick();
}
bool RsGenExchange::acknowledgeTokenMsg(const uint32_t& token,
RsGxsGrpMsgIdPair& msgId)
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, RsGxsGrpMsgIdPair >::iterator mit =
mMsgNotify.find(token);
if(mit == mMsgNotify.end())
{
return false;
}
msgId = mit->second;
// no dump token as client has ackowledged its completion
mDataAccess->disposeOfPublicToken(token);
return true;
}
bool RsGenExchange::acknowledgeTokenGrp(const uint32_t& token,
RsGxsGroupId& grpId)
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, RsGxsGroupId >::iterator mit =
mGrpNotify.find(token);
if(mit == mGrpNotify.end())
return false;
grpId = mit->second;
// no dump token as client has ackowledged its completion
mDataAccess->disposeOfPublicToken(token);
return true;
}
void RsGenExchange::generateGroupKeys(RsTlvSecurityKeySet& privatekeySet,
RsTlvSecurityKeySet& publickeySet, bool genPublishKeys)
{
/* create Keys */
// admin keys
RSA *rsa_admin = RSA_generate_key(2048, 65537, NULL, NULL);
RSA *rsa_admin_pub = RSAPublicKey_dup(rsa_admin);
/* set admin keys */
RsTlvSecurityKey adminKey, privAdminKey;
GxsSecurity::setRSAPublicKey(adminKey, rsa_admin_pub);
GxsSecurity::setRSAPrivateKey(privAdminKey, rsa_admin);
adminKey.startTS = time(NULL);
adminKey.endTS = adminKey.startTS + 60 * 60 * 24 * 365 * 5; /* approx 5 years */
privAdminKey.startTS = adminKey.startTS;
privAdminKey.endTS = 0; /* no end */
// for now all public
adminKey.keyFlags = RSTLV_KEY_DISTRIB_ADMIN | RSTLV_KEY_TYPE_PUBLIC_ONLY;
privAdminKey.keyFlags = RSTLV_KEY_DISTRIB_ADMIN | RSTLV_KEY_TYPE_FULL;
publickeySet.keys[adminKey.keyId] = adminKey;
privatekeySet.keys[privAdminKey.keyId] = privAdminKey;
// clean up
RSA_free(rsa_admin);
RSA_free(rsa_admin_pub);
if(genPublishKeys)
{
// publish keys
RSA *rsa_publish = RSA_generate_key(2048, 65537, NULL, NULL);
RSA *rsa_publish_pub = RSAPublicKey_dup(rsa_publish);
/* set publish keys */
RsTlvSecurityKey pubKey, privPubKey;
GxsSecurity::setRSAPublicKey(pubKey, rsa_publish_pub);
GxsSecurity::setRSAPrivateKey(privPubKey, rsa_publish);
pubKey.startTS = adminKey.startTS;
pubKey.endTS = pubKey.startTS + 60 * 60 * 24 * 365 * 5; /* approx 5 years */
privPubKey.startTS = adminKey.startTS;
privPubKey.endTS = 0; /* no end */
// for now all public
pubKey.keyFlags = RSTLV_KEY_DISTRIB_PUBLIC | RSTLV_KEY_TYPE_PUBLIC_ONLY;
privPubKey.keyFlags = RSTLV_KEY_DISTRIB_PRIVATE | RSTLV_KEY_TYPE_FULL;
publickeySet.keys[pubKey.keyId] = pubKey;
privatekeySet.keys[privPubKey.keyId] = privPubKey;
RSA_free(rsa_publish);
RSA_free(rsa_publish_pub);
}
}
bool RsGenExchange::createGroup(RsNxsGrp *grp, RsTlvSecurityKeySet& privateKeySet, RsTlvSecurityKeySet& publicKeySet)
{
std::cerr << "RsGenExchange::createGroup()";
std::cerr << std::endl;
RsGxsGrpMetaData* meta = grp->metaData;
/* add public admin and publish keys to grp */
// find private admin key
RsTlvSecurityKey privAdminKey;
std::map<std::string, RsTlvSecurityKey>::iterator mit = privateKeySet.keys.begin();
bool privKeyFound = false; // private admin key
for(; mit != privateKeySet.keys.end(); mit++)
{
RsTlvSecurityKey& key = mit->second;
if((key.keyFlags & RSTLV_KEY_DISTRIB_ADMIN) && (key.keyFlags & RSTLV_KEY_TYPE_FULL))
{
privAdminKey = key;
privKeyFound = true;
}
}
if(!privKeyFound)
{
std::cerr << "RsGenExchange::createGroup() Missing private ADMIN Key";
std::cerr << std::endl;
return false;
}
meta->keys = publicKeySet; // only public keys are included to be transported
// group is self signing
// for the creation of group signature
// only public admin and publish keys are present in meta
uint32_t metaDataLen = meta->serial_size();
uint32_t allGrpDataLen = metaDataLen + grp->grp.bin_len;
char* metaData = new char[metaDataLen];
char* allGrpData = new char[allGrpDataLen]; // msgData + metaData
meta->serialise(metaData, metaDataLen);
// copy msg data and meta in allMsgData buffer
memcpy(allGrpData, grp->grp.bin_data, grp->grp.bin_len);
memcpy(allGrpData+(grp->grp.bin_len), metaData, metaDataLen);
RsTlvKeySignature adminSign;
bool ok = GxsSecurity::getSignature(allGrpData, allGrpDataLen, &privAdminKey, adminSign);
// add admin sign to grpMeta
meta->signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_ADMIN] = adminSign;
// set meta to be transported as meta without private
// key components
grp->meta.setBinData(metaData, metaDataLen);
// but meta that is stored locally
// has private keys
// nxs net transports only bin data
meta->keys = privateKeySet;
// clean up
delete[] allGrpData;
delete[] metaData;
if (!ok)
{
std::cerr << "RsGenExchange::createGroup() ERROR !okay (getSignature error)";
std::cerr << std::endl;
}
return ok;
}
bool RsGenExchange::createMsgSignatures(RsTlvKeySignatureSet& signSet, RsTlvBinaryData& msgData,
const RsGxsMsgMetaData& msgMeta, RsGxsGrpMetaData& grpMeta)
{
bool isParent = false;
bool needPublishSign = false, needIdentitySign = false;
bool ok = true;
uint32_t grpFlag = grpMeta.mGroupFlags;
std::cerr << "RsGenExchange::createMsgSignatures() for Msg.mMsgName: " << msgMeta.mMsgName;
std::cerr << std::endl;
// publish signature is determined by whether group is public or not
// for private group signature is not needed as it needs decrypting with
// the private publish key anyways
// restricted is a special case which heeds whether publish sign needs to be checked or not
// one may or may not want
uint8_t author_flag = GXS_SERV::MSG_AUTHEN_ROOT_AUTHOR_SIGN;
uint8_t publish_flag = GXS_SERV::MSG_AUTHEN_ROOT_PUBLISH_SIGN;
if(!msgMeta.mParentId.empty())
{
// Child Message.
author_flag = GXS_SERV::MSG_AUTHEN_CHILD_AUTHOR_SIGN;
publish_flag = GXS_SERV::MSG_AUTHEN_CHILD_PUBLISH_SIGN;
}
PrivacyBitPos pos = PUBLIC_GRP_BITS;
if (grpFlag & GXS_SERV::FLAG_PRIVACY_RESTRICTED)
{
pos = RESTRICTED_GRP_BITS;
}
else if (grpFlag & GXS_SERV::FLAG_PRIVACY_PRIVATE)
{
pos = PRIVATE_GRP_BITS;
}
needIdentitySign = false;
needPublishSign = false;
if (checkMsgAuthenFlag(pos, publish_flag))
{
needPublishSign = true;
std::cerr << "Needs Publish sign! (Service Flags)";
std::cerr << std::endl;
}
// Check required permissions, and allow them to sign it - if they want too - as well!
if (checkMsgAuthenFlag(pos, author_flag))
{
needIdentitySign = true;
std::cerr << "Needs Identity sign! (Service Flags)";
std::cerr << std::endl;
}
if (!msgMeta.mAuthorId.empty())
{
needIdentitySign = true;
std::cerr << "Needs Identity sign! (AuthorId Exists)";
std::cerr << std::endl;
}
if(needPublishSign)
{
// public and shared is publish key
RsTlvSecurityKeySet& keys = grpMeta.keys;
RsTlvSecurityKey* pubKey;
std::map<std::string, RsTlvSecurityKey>::iterator mit =
keys.keys.begin(), mit_end = keys.keys.end();
bool pub_key_found = false;
for(; mit != mit_end; mit++)
{
pub_key_found = mit->second.keyFlags == (RSTLV_KEY_DISTRIB_PRIVATE | RSTLV_KEY_TYPE_FULL);
if(pub_key_found)
break;
}
if (!pub_key_found)
{
std::cerr << "RsGenExchange::createMsgSignatures()";
std::cerr << " ERROR Cannot find PUBLISH KEY for Message Signing";
std::cerr << std::endl;
return false;
}
// private publish key
pubKey = &(mit->second);
RsTlvKeySignature pubSign = signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_PUBLISH];
ok &= GxsSecurity::getSignature((char*)msgData.bin_data, msgData.bin_len, pubKey, pubSign);
//place signature in msg meta
signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_PUBLISH] = pubSign;
}
if (needIdentitySign)
{
if(mGixs)
{
/***************************************************************
* NOTE: The logic below is wrong.
* mGixs->havePrivateKey(msgMeta.mAuthorId) can return False if the Key isn't cached.
*
* This Operation should be retried again - later.
*
**************************************************************/
bool haveKey = mGixs->havePrivateKey(msgMeta.mAuthorId);
if(haveKey)
{
mGixs->requestPrivateKey(msgMeta.mAuthorId);
RsTlvSecurityKey authorKey;
double timeDelta = 0.002; // fast polling
time_t now = time(NULL);
bool auth_key_fetched = false;
// poll immediately but, don't spend more than a second polling
while((!auth_key_fetched) && ((now + 5) > time(NULL)))
{
auth_key_fetched = (mGixs->getPrivateKey(msgMeta.mAuthorId, authorKey) == 1);
#ifndef WINDOWS_SYS
usleep((int) (timeDelta * 1000000));
#else
Sleep((int) (timeDelta * 1000));
#endif
}
if (!auth_key_fetched)
{
std::cerr << "RsGenExchange::createMsgSignatures()";
std::cerr << " ERROR Cannot find AUTHOR KEY for Message Signing";
std::cerr << std::endl;
return false;
}
RsTlvKeySignature sign;
ok &= GxsSecurity::getSignature((char*)msgData.bin_data, msgData.bin_len,
&authorKey, sign);
signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_IDENTITY] = sign;
}
else
{
std::cerr << "RsGenExchange::createMsgSignatures()";
std::cerr << " ERROR AUTHOR KEY is not Cached / available for Message Signing";
std::cerr << std::endl;
ok = false;
}
}
else
{
std::cerr << "RsGenExchange::createMsgSignatures()";
std::cerr << "Gixs not enabled while request identity signature validation!" << std::endl;
ok = false;
}
}
return ok;
}
bool RsGenExchange::createMessage(RsNxsMsg* msg)
{
const RsGxsGroupId& id = msg->grpId;
std::map<RsGxsGroupId, RsGxsGrpMetaData*> metaMap;
metaMap.insert(std::make_pair(id, (RsGxsGrpMetaData*)(NULL)));
mDataStore->retrieveGxsGrpMetaData(metaMap);
bool ok = true;
RsGxsMsgMetaData &meta = *(msg->metaData);
if(!metaMap[id])
{
return false;
}
else
{
// get publish key
RsGxsGrpMetaData* grpMeta = metaMap[id];
uint32_t metaDataLen = meta.serial_size();
uint32_t allMsgDataLen = metaDataLen + msg->msg.bin_len;
char* metaData = new char[metaDataLen];
char* allMsgData = new char[allMsgDataLen]; // msgData + metaData
meta.serialise(metaData, &metaDataLen);
// copy msg data and meta in allmsgData buffer
memcpy(allMsgData, msg->msg.bin_data, msg->msg.bin_len);
memcpy(allMsgData+(msg->msg.bin_len), metaData, metaDataLen);
RsTlvBinaryData msgData(0);
msgData.setBinData(allMsgData, allMsgDataLen);
// create signatures
ok &= createMsgSignatures(meta.signSet, msgData, meta, *grpMeta);
// get hash of msg data to create msg id
pqihash hash;
hash.addData(allMsgData, allMsgDataLen);
hash.Complete(msg->msgId);
// assign msg id to msg meta
msg->metaData->mMsgId = msg->msgId;
delete[] metaData;
delete[] allMsgData;
delete grpMeta;
}
return ok;
}
bool RsGenExchange::validateMsg(RsNxsMsg *msg, const uint32_t& grpFlag, RsTlvSecurityKeySet& grpKeySet)
{
bool needIdentitySign = false;
bool needPublishSign = false;
bool valid = true;
uint8_t author_flag = GXS_SERV::MSG_AUTHEN_ROOT_AUTHOR_SIGN;
uint8_t publish_flag = GXS_SERV::MSG_AUTHEN_ROOT_PUBLISH_SIGN;
if(!msg->metaData->mParentId.empty())
{
// Child Message.
author_flag = GXS_SERV::MSG_AUTHEN_CHILD_AUTHOR_SIGN;
publish_flag = GXS_SERV::MSG_AUTHEN_CHILD_PUBLISH_SIGN;
}
PrivacyBitPos pos = PUBLIC_GRP_BITS;
if (grpFlag & GXS_SERV::FLAG_PRIVACY_RESTRICTED)
{
pos = RESTRICTED_GRP_BITS;
}
else if (grpFlag & GXS_SERV::FLAG_PRIVACY_PRIVATE)
{
pos = PRIVATE_GRP_BITS;
}
if (checkMsgAuthenFlag(pos, publish_flag))
needPublishSign = true;
// Check required permissions, if they have signed it anyway - we need to validate it.
if ((checkMsgAuthenFlag(pos, author_flag)) || (!msg->metaData->mAuthorId.empty()))
needIdentitySign = true;
RsGxsMsgMetaData& metaData = *(msg->metaData);
if(needPublishSign)
{
RsTlvKeySignature sign = metaData.signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_PUBLISH];
std::map<std::string, RsTlvSecurityKey>& keys = grpKeySet.keys;
std::map<std::string, RsTlvSecurityKey>::iterator mit = keys.begin();
std::string keyId;
for(; mit != keys.end() ; mit++)
{
RsTlvSecurityKey& key = mit->second;
if((key.keyFlags & RSTLV_KEY_DISTRIB_PUBLIC) &&
(key.keyFlags & RSTLV_KEY_TYPE_PUBLIC_ONLY))
{
keyId = key.keyId;
}
}
if(!keyId.empty())
{
RsTlvSecurityKey& key = keys[keyId];
valid &= GxsSecurity::validateNxsMsg(*msg, sign, key);
}
else
{
valid = false;
}
}
if(needIdentitySign)
{
if(mGixs)
{
bool haveKey = mGixs->haveKey(metaData.mAuthorId);
if(haveKey)
{
RsTlvSecurityKey authorKey;
double timeDelta = 0.002; // fast polling
time_t now = time(NULL);
bool auth_key_fetched = false;
// poll immediately but, don't spend more than a second polling
while((!auth_key_fetched) && ((now + 1) > time(NULL)))
{
auth_key_fetched = (mGixs->getKey(metaData.mAuthorId, authorKey) == 1);
#ifndef WINDOWS_SYS
usleep((int) (timeDelta * 1000000));
#else
Sleep((int) (timeDelta * 1000));
#endif
}
if (!auth_key_fetched)
{
std::cerr << "RsGenExchange::validateMsg()";
std::cerr << " ERROR Cannot find AUTHOR KEY for Message Validation";
std::cerr << std::endl;
return false;
}
RsTlvKeySignature sign = metaData.signSet.keySignSet[GXS_SERV::FLAG_AUTHEN_IDENTITY];
valid &= GxsSecurity::validateNxsMsg(*msg, sign, authorKey);
}else
{
std::list<std::string> peers;
mGixs->requestKey(metaData.mAuthorId, peers);
valid = false;
}
}
else
{
#ifdef GEN_EXHANGE_DEBUG
std::cerr << "Gixs not enabled while request identity signature validation!" << std::endl;
#endif
valid = false;
}
}
return valid;
}
bool RsGenExchange::checkMsgAuthenFlag(const PrivacyBitPos& pos, const uint8_t& flag) const
{
std::cerr << "RsGenExchange::checkMsgAuthenFlag(pos: " << pos << " flag: ";
std::cerr << (int) flag << " mAuthenPolicy: " << mAuthenPolicy << ")";
std::cerr << std::endl;
switch(pos)
{
case PUBLIC_GRP_BITS:
return mAuthenPolicy & flag;
break;
case RESTRICTED_GRP_BITS:
return flag & (mAuthenPolicy >> RESTR_GRP_OFFSET);
break;
case PRIVATE_GRP_BITS:
return flag & (mAuthenPolicy >> PRIV_GRP_OFFSET);
break;
case GRP_OPTION_BITS:
return flag & (mAuthenPolicy >> GRP_OPTIONS_OFFSET);
break;
default:
std::cerr << "pos option not recognised";
return false;
}
}
void RsGenExchange::receiveChanges(std::vector<RsGxsNotify*>& changes)
{
RsStackMutex stack(mGenMtx);
std::vector<RsGxsNotify*>::iterator vit = changes.begin();
for(; vit != changes.end(); vit++)
{
RsGxsNotify* n = *vit;
RsGxsGroupChange* gc;
RsGxsMsgChange* mc;
if((mc = dynamic_cast<RsGxsMsgChange*>(n)) != NULL)
{
mMsgChange.push_back(mc);
}
else if((gc = dynamic_cast<RsGxsGroupChange*>(n)) != NULL)
{
mGroupChange.push_back(gc);
}
else
{
delete n;
}
}
}
void RsGenExchange::msgsChanged(std::map<RsGxsGroupId,
std::vector<RsGxsMessageId> >& msgs)
{
RsStackMutex stack(mGenMtx);
while(!mMsgChange.empty())
{
RsGxsMsgChange* mc = mMsgChange.back();
msgs = mc->msgChangeMap;
mMsgChange.pop_back();
delete mc;
}
}
void RsGenExchange::groupsChanged(std::list<RsGxsGroupId>& grpIds)
{
RsStackMutex stack(mGenMtx);
while(!mGroupChange.empty())
{
RsGxsGroupChange* gc = mGroupChange.back();
std::list<RsGxsGroupId>& gList = gc->mGrpIdList;
std::list<RsGxsGroupId>::iterator lit = gList.begin();
for(; lit != gList.end(); lit++)
grpIds.push_back(*lit);
mGroupChange.pop_back();
delete gc;
}
}
bool RsGenExchange::subscribeToGroup(uint32_t& token, const RsGxsGroupId& grpId, bool subscribe)
{
if(subscribe)
setGroupSubscribeFlags(token, grpId, GXS_SERV::GROUP_SUBSCRIBE_SUBSCRIBED, GXS_SERV::GROUP_SUBSCRIBE_MASK);
else
setGroupSubscribeFlags(token, grpId, 0, GXS_SERV::GROUP_SUBSCRIBE_MASK);
return true;
}
bool RsGenExchange::updated(bool willCallGrpChanged, bool willCallMsgChanged)
{
bool changed = false;
{
RsStackMutex stack(mGenMtx);
changed = (!mGroupChange.empty() || !mMsgChange.empty());
}
if(!willCallGrpChanged)
{
std::list<RsGxsGroupId> grpIds;
groupsChanged(grpIds);
}
if(!willCallMsgChanged)
{
std::map<RsGxsGroupId, std::vector<RsGxsMessageId> > msgs;
msgsChanged(msgs);
}
return changed;
}
bool RsGenExchange::getGroupList(const uint32_t &token, std::list<RsGxsGroupId> &groupIds)
{
return mDataAccess->getGroupList(token, groupIds);
}
bool RsGenExchange::getMsgList(const uint32_t &token,
GxsMsgIdResult &msgIds)
{
return mDataAccess->getMsgList(token, msgIds);
}
bool RsGenExchange::getMsgRelatedList(const uint32_t &token, MsgRelatedIdResult &msgIds)
{
return mDataAccess->getMsgRelatedList(token, msgIds);
}
bool RsGenExchange::getGroupMeta(const uint32_t &token, std::list<RsGroupMetaData> &groupInfo)
{
std::list<RsGxsGrpMetaData*> metaL;
bool ok = mDataAccess->getGroupSummary(token, metaL);
std::list<RsGxsGrpMetaData*>::iterator lit = metaL.begin();
RsGroupMetaData m;
for(; lit != metaL.end(); lit++)
{
RsGxsGrpMetaData& gMeta = *(*lit);
m = gMeta;
groupInfo.push_back(m);
delete (*lit);
}
return ok;
}
bool RsGenExchange::getMsgMeta(const uint32_t &token,
GxsMsgMetaMap &msgInfo)
{
std::list<RsGxsMsgMetaData*> metaL;
GxsMsgMetaResult result;
bool ok = mDataAccess->getMsgSummary(token, result);
GxsMsgMetaResult::iterator mit = result.begin();
for(; mit != result.end(); mit++)
{
std::vector<RsGxsMsgMetaData*>& metaV = mit->second;
msgInfo[mit->first] = std::vector<RsMsgMetaData>();
std::vector<RsMsgMetaData>& msgInfoV = msgInfo[mit->first];
std::vector<RsGxsMsgMetaData*>::iterator vit = metaV.begin();
RsMsgMetaData meta;
for(; vit != metaV.end(); vit++)
{
RsGxsMsgMetaData& m = *(*vit);
meta = m;
msgInfoV.push_back(meta);
delete *vit;
}
metaV.clear();
}
return ok;
}
bool RsGenExchange::getMsgRelatedMeta(const uint32_t &token, GxsMsgRelatedMetaMap &msgMeta)
{
MsgRelatedMetaResult result;
bool ok = mDataAccess->getMsgRelatedSummary(token, result);
MsgRelatedMetaResult::iterator mit = result.begin();
for(; mit != result.end(); mit++)
{
std::vector<RsGxsMsgMetaData*>& metaV = mit->second;
msgMeta[mit->first] = std::vector<RsMsgMetaData>();
std::vector<RsMsgMetaData>& msgInfoV = msgMeta[mit->first];
std::vector<RsGxsMsgMetaData*>::iterator vit = metaV.begin();
RsMsgMetaData meta;
for(; vit != metaV.end(); vit++)
{
RsGxsMsgMetaData& m = *(*vit);
meta = m;
msgInfoV.push_back(meta);
delete *vit;
}
metaV.clear();
}
return ok;
}
bool RsGenExchange::getGroupData(const uint32_t &token, std::vector<RsGxsGrpItem *>& grpItem)
{
std::list<RsNxsGrp*> nxsGrps;
bool ok = mDataAccess->getGroupData(token, nxsGrps);
std::list<RsNxsGrp*>::iterator lit = nxsGrps.begin();
std::cerr << "RsGenExchange::getGroupData() RsNxsGrp::len: " << nxsGrps.size();
std::cerr << std::endl;
if(ok)
{
for(; lit != nxsGrps.end(); lit++)
{
RsTlvBinaryData& data = (*lit)->grp;
RsItem* item = mSerialiser->deserialise(data.bin_data, &data.bin_len);
if(item)
{
RsGxsGrpItem* gItem = dynamic_cast<RsGxsGrpItem*>(item);
if (gItem)
{
gItem->meta = *((*lit)->metaData);
grpItem.push_back(gItem);
}
else
{
std::cerr << "RsGenExchange::getGroupData() deserialisation/dynamic_cast ERROR";
std::cerr << std::endl;
delete item;
}
}
else
{
std::cerr << "RsGenExchange::getGroupData() ERROR deserialising item";
std::cerr << std::endl;
}
delete *lit;
}
}
return ok;
}
bool RsGenExchange::getMsgData(const uint32_t &token,
GxsMsgDataMap &msgItems)
{
RsStackMutex stack(mGenMtx);
NxsMsgDataResult msgResult;
bool ok = mDataAccess->getMsgData(token, msgResult);
NxsMsgDataResult::iterator mit = msgResult.begin();
if(ok)
{
for(; mit != msgResult.end(); mit++)
{
std::vector<RsGxsMsgItem*> gxsMsgItems;
const RsGxsGroupId& grpId = mit->first;
std::vector<RsNxsMsg*>& nxsMsgsV = mit->second;
std::vector<RsNxsMsg*>::iterator vit
= nxsMsgsV.begin();
for(; vit != nxsMsgsV.end(); vit++)
{
RsNxsMsg*& msg = *vit;
RsItem* item = mSerialiser->deserialise(msg->msg.bin_data,
&msg->msg.bin_len);
if (item)
{
RsGxsMsgItem* mItem = dynamic_cast<RsGxsMsgItem*>(item);
if (mItem)
{
mItem->meta = *((*vit)->metaData); // get meta info from nxs msg
gxsMsgItems.push_back(mItem);
}
else
{
std::cerr << "RsGenExchange::getMsgData() deserialisation/dynamic_cast ERROR";
std::cerr << std::endl;
delete item;
}
}
else
{
std::cerr << "RsGenExchange::getMsgData() deserialisation ERROR";
std::cerr << std::endl;
}
delete msg;
}
msgItems[grpId] = gxsMsgItems;
}
}
return ok;
}
bool RsGenExchange::getMsgRelatedData(const uint32_t &token, GxsMsgRelatedDataMap &msgItems)
{
RsStackMutex stack(mGenMtx);
NxsMsgRelatedDataResult msgResult;
bool ok = mDataAccess->getMsgRelatedData(token, msgResult);
NxsMsgRelatedDataResult::iterator mit = msgResult.begin();
if(ok)
{
for(; mit != msgResult.end(); mit++)
{
std::vector<RsGxsMsgItem*> gxsMsgItems;
const RsGxsGrpMsgIdPair& msgId = mit->first;
std::vector<RsNxsMsg*>& nxsMsgsV = mit->second;
std::vector<RsNxsMsg*>::iterator vit
= nxsMsgsV.begin();
for(; vit != nxsMsgsV.end(); vit++)
{
RsNxsMsg*& msg = *vit;
RsItem* item = mSerialiser->deserialise(msg->msg.bin_data,
&msg->msg.bin_len);
if (item)
{
RsGxsMsgItem* mItem = dynamic_cast<RsGxsMsgItem*>(item);
if (mItem)
{
mItem->meta = *((*vit)->metaData); // get meta info from nxs msg
gxsMsgItems.push_back(mItem);
}
else
{
std::cerr << "RsGenExchange::getMsgRelatedData() deserialisation/dynamic_cast ERROR";
std::cerr << std::endl;
delete item;
}
}
else
{
std::cerr << "RsGenExchange::getMsgRelatedData() deserialisation ERROR";
std::cerr << std::endl;
}
delete msg;
}
msgItems[msgId] = gxsMsgItems;
}
}
return ok;
}
RsTokenService* RsGenExchange::getTokenService()
{
return mDataAccess;
}
bool RsGenExchange::setAuthenPolicyFlag(const uint8_t &msgFlag, uint32_t& authenFlag, const PrivacyBitPos &pos)
{
uint32_t temp = 0;
temp = msgFlag;
switch(pos)
{
case PUBLIC_GRP_BITS:
//authenFlag &= ~PUB_GRP_MASK;
authenFlag |= temp;
break;
case RESTRICTED_GRP_BITS:
//authenFlag &= ~RESTR_GRP_MASK;
authenFlag |= (temp << RESTR_GRP_OFFSET);
break;
case PRIVATE_GRP_BITS:
//authenFlag &= ~PRIV_GRP_MASK;
authenFlag |= (temp << PRIV_GRP_OFFSET);
break;
case GRP_OPTION_BITS:
//authenFlag &= ~GRP_OPTIONS_MASK;
authenFlag |= (temp << GRP_OPTIONS_OFFSET);
break;
default:
std::cerr << "pos option not recognised";
return false;
}
return true;
}
void RsGenExchange::notifyNewGroups(std::vector<RsNxsGrp *> &groups)
{
RsStackMutex stack(mGenMtx);
std::vector<RsNxsGrp*>::iterator vit = groups.begin();
// store these for tick() to pick them up
for(; vit != groups.end(); vit++)
mReceivedGrps.push_back(*vit);
}
void RsGenExchange::notifyNewMessages(std::vector<RsNxsMsg *>& messages)
{
RsStackMutex stack(mGenMtx);
std::vector<RsNxsMsg*>::iterator vit = messages.begin();
// store these for tick() to pick them up
for(; vit != messages.end(); vit++)
mReceivedMsgs.push_back(*vit);
}
void RsGenExchange::publishGroup(uint32_t& token, RsGxsGrpItem *grpItem)
{
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
mGrpsToPublish.insert(std::make_pair(token, grpItem));
#ifdef GEN_EXCH_DEBUG
std::cerr << "RsGenExchange::publishGroup() token: " << token;
std::cerr << std::endl;
#endif
}
void RsGenExchange::publishMsg(uint32_t& token, RsGxsMsgItem *msgItem)
{
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
mMsgsToPublish.insert(std::make_pair(token, msgItem));
#ifdef GEN_EXCH_DEBUG
std::cerr << "RsGenExchange::publishMsg() token: " << token;
std::cerr << std::endl;
#endif
}
void RsGenExchange::setGroupSubscribeFlags(uint32_t& token, const RsGxsGroupId& grpId, const uint32_t& flag, const uint32_t& mask)
{
/* TODO APPLY MASK TO FLAGS */
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
GrpLocMetaData g;
g.grpId = grpId;
g.val.put(RsGeneralDataService::GRP_META_SUBSCRIBE_FLAG, (int32_t)flag);
g.val.put(RsGeneralDataService::GRP_META_SUBSCRIBE_FLAG+GXS_MASK, (int32_t)mask); // HACK, need to perform mask operation in a non-blocking location
mGrpLocMetaMap.insert(std::make_pair(token, g));
}
void RsGenExchange::setGroupStatusFlags(uint32_t& token, const RsGxsGroupId& grpId, const uint32_t& status, const uint32_t& mask)
{
/* TODO APPLY MASK TO FLAGS */
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
GrpLocMetaData g;
g.grpId = grpId;
g.val.put(RsGeneralDataService::GRP_META_STATUS, (int32_t)status);
g.val.put(RsGeneralDataService::GRP_META_STATUS+GXS_MASK, (int32_t)mask); // HACK, need to perform mask operation in a non-blocking location
mGrpLocMetaMap.insert(std::make_pair(token, g));
}
void RsGenExchange::setGroupServiceString(uint32_t& token, const RsGxsGroupId& grpId, const std::string& servString)
{
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
GrpLocMetaData g;
g.grpId = grpId;
g.val.put(RsGeneralDataService::GRP_META_SERV_STRING, servString);
mGrpLocMetaMap.insert(std::make_pair(token, g));
}
void RsGenExchange::setMsgStatusFlags(uint32_t& token, const RsGxsGrpMsgIdPair& msgId, const uint32_t& status, const uint32_t& mask)
{
/* TODO APPLY MASK TO FLAGS */
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
MsgLocMetaData m;
m.val.put(RsGeneralDataService::MSG_META_STATUS, (int32_t)status);
m.val.put(RsGeneralDataService::MSG_META_STATUS+GXS_MASK, (int32_t)mask); // HACK, need to perform mask operation in a non-blocking location
m.msgId = msgId;
mMsgLocMetaMap.insert(std::make_pair(token, m));
}
void RsGenExchange::setMsgServiceString(uint32_t& token, const RsGxsGrpMsgIdPair& msgId, const std::string& servString )
{
RsStackMutex stack(mGenMtx);
token = mDataAccess->generatePublicToken();
MsgLocMetaData m;
m.val.put(RsGeneralDataService::MSG_META_SERV_STRING, servString);
m.msgId = msgId;
mMsgLocMetaMap.insert(std::make_pair(token, m));
}
void RsGenExchange::processMsgMetaChanges()
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, MsgLocMetaData>::iterator mit = mMsgLocMetaMap.begin(),
mit_end = mMsgLocMetaMap.end();
for(; mit != mit_end; mit++)
{
MsgLocMetaData& m = mit->second;
int32_t value, mask;
bool ok = true;
// for meta flag changes get flag to apply mask
if(m.val.getAsInt32(RsGeneralDataService::MSG_META_STATUS, value))
{
ok = false;
if(m.val.getAsInt32(RsGeneralDataService::MSG_META_STATUS+GXS_MASK, mask))
{
GxsMsgReq req;
std::vector<RsGxsMessageId> msgIdV;
msgIdV.push_back(m.msgId.second);
req.insert(std::make_pair(m.msgId.first, msgIdV));
GxsMsgMetaResult result;
mDataStore->retrieveGxsMsgMetaData(req, result);
GxsMsgMetaResult::iterator mit = result.find(m.msgId.first);
if(mit != result.end())
{
std::vector<RsGxsMsgMetaData*>& msgMetaV = mit->second;
if(!msgMetaV.empty())
{
RsGxsMsgMetaData* meta = *(msgMetaV.begin());
value = (meta->mMsgStatus & ~mask) | (mask & value);
m.val.put(RsGeneralDataService::MSG_META_STATUS, value);
delete meta;
ok = true;
}
}
m.val.removeKeyValue(RsGeneralDataService::MSG_META_STATUS+GXS_MASK);
}
}
ok &= mDataStore->updateMessageMetaData(m) == 1;
uint32_t token = mit->first;
if(ok)
{
mDataAccess->updatePublicRequestStatus(token, RsTokenService::GXS_REQUEST_V2_STATUS_COMPLETE);
}else
{
mDataAccess->updatePublicRequestStatus(token, RsTokenService::GXS_REQUEST_V2_STATUS_FAILED);
}
mMsgNotify.insert(std::make_pair(token, m.msgId));
}
mMsgLocMetaMap.clear();
}
void RsGenExchange::processGrpMetaChanges()
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, GrpLocMetaData>::iterator mit = mGrpLocMetaMap.begin(),
mit_end = mGrpLocMetaMap.end();
for(; mit != mit_end; mit++)
{
GrpLocMetaData& g = mit->second;
uint32_t token = mit->first;
// process mask
bool ok = processGrpMask(g.grpId, g.val);
ok &= mDataStore->updateGroupMetaData(g) == 1;
if(ok)
{
mDataAccess->updatePublicRequestStatus(token, RsTokenService::GXS_REQUEST_V2_STATUS_COMPLETE);
}else
{
mDataAccess->updatePublicRequestStatus(token, RsTokenService::GXS_REQUEST_V2_STATUS_FAILED);
}
mGrpNotify.insert(std::make_pair(token, g.grpId));
}
mGrpLocMetaMap.clear();
}
bool RsGenExchange::processGrpMask(const RsGxsGroupId& grpId, ContentValue &grpCv)
{
// first find out which mask is involved
int32_t value, mask, currValue;
std::string key;
RsGxsGrpMetaData* grpMeta = NULL;
bool ok = false;
std::map<RsGxsGroupId, RsGxsGrpMetaData* > grpMetaMap;
std::map<RsGxsGroupId, RsGxsGrpMetaData* >::iterator mit;
grpMetaMap.insert(std::make_pair(grpId, (RsGxsGrpMetaData*)(NULL)));
mDataStore->retrieveGxsGrpMetaData(grpMetaMap);
if((mit = grpMetaMap.find(grpId)) != grpMetaMap.end())
{
grpMeta = mit->second;
ok = true;
}
if(grpCv.getAsInt32(RsGeneralDataService::GRP_META_STATUS, value))
{
key = RsGeneralDataService::GRP_META_STATUS;
currValue = grpMeta->mGroupStatus;
}
else if(grpCv.getAsInt32(RsGeneralDataService::GRP_META_SUBSCRIBE_FLAG, value))
{
key = RsGeneralDataService::GRP_META_SUBSCRIBE_FLAG;
currValue = grpMeta->mSubscribeFlags;
}else
{
if(grpMeta)
delete grpMeta;
return true;
}
ok &= grpCv.getAsInt32(key+GXS_MASK, mask);
// remove mask entry so it doesn't affect
grpCv.removeKeyValue(key+GXS_MASK);
// apply mask to current value
value = (currValue & ~mask) | (value & mask);
grpCv.put(key, value);
if(grpMeta)
delete grpMeta;
return ok;
}
void RsGenExchange::publishMsgs()
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, RsGxsMsgItem*>::iterator mit = mMsgsToPublish.begin();
for(; mit != mMsgsToPublish.end(); mit++)
{
std::cerr << "RsGenExchange::publishMsgs() Publishing a Message";
std::cerr << std::endl;
RsNxsMsg* msg = new RsNxsMsg(mServType);
RsGxsMsgItem* msgItem = mit->second;
msg->grpId = msgItem->meta.mGroupId;
uint32_t size = mSerialiser->size(msgItem);
char* mData = new char[size];
bool serialOk = false;
bool createOk = false;
serialOk = mSerialiser->serialise(msgItem, mData, &size);
if(serialOk)
{
msg->msg.setBinData(mData, size);
// now create meta
msg->metaData = new RsGxsMsgMetaData();
*(msg->metaData) = msgItem->meta;
// assign time stamp
msg->metaData->mPublishTs = time(NULL);
// now intialise msg (sign it)
createOk = createMessage(msg);
RsGxsMessageId msgId;
RsGxsGroupId grpId = msgItem->meta.mGroupId;
bool msgDoesnExist = false, validSize = false;
if(createOk)
{
GxsMsgReq req;
std::vector<RsGxsMessageId> msgV;
msgV.push_back(msg->msgId);
GxsMsgMetaResult res;
req.insert(std::make_pair(msg->grpId, msgV));
mDataStore->retrieveGxsMsgMetaData(req, res);
msgDoesnExist = res[grpId].empty();
#ifdef GEN_EXCH_DEBUG
if (!msgDoesnExist)
{
std::cerr << "RsGenExchange::publishMsgs() msg exists already :( " << std::endl;
}
#endif
}
if(createOk && msgDoesnExist)
{
validSize = mDataStore->validSize(msg);
}
if(createOk && msgDoesnExist && validSize)
{
// empty orig msg id means this is the original
// msg
// TODO: a non empty msgid means one should at least
// have the msg on disk, after which this msg is signed
// based on the security settings
// public grp (sign by grp public pub key, private/id: signed by
// id
if(msg->metaData->mOrigMsgId.empty())
{
msg->metaData->mOrigMsgId = msg->metaData->mMsgId;
}
// now serialise meta data
size = msg->metaData->serial_size();
char metaDataBuff[size];
msg->metaData->serialise(metaDataBuff, &size);
msg->meta.setBinData(metaDataBuff, size);
msg->metaData->mMsgStatus = GXS_SERV::GXS_MSG_STATUS_UNPROCESSED | GXS_SERV::GXS_MSG_STATUS_UNREAD;
msgId = msg->msgId;
grpId = msg->grpId;
mDataAccess->addMsgData(msg);
// add to published to allow acknowledgement
mMsgNotify.insert(std::make_pair(mit->first, std::make_pair(grpId, msgId)));
mDataAccess->updatePublicRequestStatus(mit->first, RsTokenService::GXS_REQUEST_V2_STATUS_COMPLETE);
}
else
{
// delete msg if created wasn't ok
/*******************************************************************************
* NOTE: THIS LOGIC IS WRONG.
* It is possible, that message creation failed because Author Keys
* were not cached... If this is the case - it should be re-tried
* in a few seconds - when the cache has been loaded.
******************************************************************************/
delete msg;
mDataAccess->updatePublicRequestStatus(mit->first, RsTokenService::GXS_REQUEST_V2_STATUS_FAILED);
#ifdef GEN_EXCH_DEBUG
std::cerr << "RsGenExchange::publishMsgs() failed to publish msg " << std::endl;
#endif
}
}
else
{
#ifdef GEN_EXCH_DEBUG
std::cerr << "RsGenExchange::publishMsgs() failed to serialise msg " << std::endl;
#endif
}
delete[] mData;
delete msgItem;
}
// clear msg list as we're done publishing them and entries
// are invalid
mMsgsToPublish.clear();
}
void RsGenExchange::service_CreateGroup(RsGxsGrpItem* grpItem, RsTlvSecurityKeySet& keySet)
{
#ifdef GEN_EXCH_DEBUG
std::cerr << "RsGenExchange::service_CreateGroup(): Does nothing"
<< std::endl;
#endif
return;
}
#define GEN_EXCH_GRP_CHUNK 3
void RsGenExchange::publishGrps()
{
RsStackMutex stack(mGenMtx);
std::map<uint32_t, RsGxsGrpItem*>::iterator mit = mGrpsToPublish.begin();
std::vector<uint32_t> toRemove;
int i = 0;
for(; mit != mGrpsToPublish.end(); mit++)
{
if(i > GEN_EXCH_GRP_CHUNK-1) break;
toRemove.push_back(mit->first);
i++;
RsNxsGrp* grp = new RsNxsGrp(mServType);
RsGxsGrpItem* grpItem = mit->second;
RsTlvSecurityKeySet privatekeySet, publicKeySet, tempKeySet;
generateGroupKeys(privatekeySet, publicKeySet,
!(grpItem->meta.mGroupFlags & GXS_SERV::FLAG_PRIVACY_PUBLIC));
// find private admin key
RsTlvSecurityKey privAdminKey;
std::map<std::string, RsTlvSecurityKey>::iterator mit_keys = privatekeySet.keys.begin();
bool privKeyFound = false;
for(; mit_keys != privatekeySet.keys.end(); mit_keys++)
{
RsTlvSecurityKey& key = mit_keys->second;
if(key.keyFlags == (RSTLV_KEY_DISTRIB_ADMIN | RSTLV_KEY_TYPE_FULL))
{
privAdminKey = key;
privKeyFound = true;
}
}
bool ok = true;
if(privKeyFound)
{
// get group id from private admin key id
grpItem->meta.mGroupId = grp->grpId = privAdminKey.keyId;
}
else
{
ok = false;
}
//tempKeySet = privatekeySet;
privatekeySet.keys.insert(publicKeySet.keys.begin(),
publicKeySet.keys.end());
service_CreateGroup(grpItem, privatekeySet);
//privatekeySet = tempKeySet;
uint32_t size = mSerialiser->size(grpItem);
char gData[size];
ok = mSerialiser->serialise(grpItem, gData, &size);
if (!ok)
{
std::cerr << "RsGenExchange::publishGrps() !ok ERROR After First Serialise" << std::endl;
}
grp->grp.setBinData(gData, size);
if(ok)
{
grp->metaData = new RsGxsGrpMetaData();
grpItem->meta.mPublishTs = time(NULL);
*(grp->metaData) = grpItem->meta;
grp->metaData->mSubscribeFlags = GXS_SERV::GROUP_SUBSCRIBE_ADMIN;
if (!createGroup(grp, privatekeySet, publicKeySet))
{
std::cerr << "RsGenExchange::publishGrps() !ok ERROR After createGroup" << std::endl;
}
else
{
// ensure group size is not too large
ok &= mDataStore->validSize(grp);
if(ok)
{
RsGxsGroupId grpId = grp->grpId;
mDataAccess->addGroupData(grp);
std::cerr << "RsGenExchange::publishGrps() ok -> pushing to notifies" << std::endl;
// add to published to allow acknowledgement
mGrpNotify.insert(std::make_pair(mit->first, grpId));
mDataAccess->updatePublicRequestStatus(mit->first, RsTokenService::GXS_REQUEST_V2_STATUS_COMPLETE);
}
}
}
if(!ok)
{
#ifdef GEN_EXCH_DEBUG
#endif
std::cerr << "RsGenExchange::publishGrps() failed to publish grp " << std::endl;
delete grp;
// add to published to allow acknowledgement, grpid is empty as grp creation failed
mGrpNotify.insert(std::make_pair(mit->first, RsGxsGroupId("")));
mDataAccess->updatePublicRequestStatus(mit->first, RsTokenService::GXS_REQUEST_V2_STATUS_FAILED);
continue;
}
delete grpItem;
}
// clear grp list as we're done publishing them and entries
// are invalid
for(int i = 0; i < toRemove.size(); i++)
mGrpsToPublish.erase(toRemove[i]);
}
uint32_t RsGenExchange::generatePublicToken()
{
return mDataAccess->generatePublicToken();
}
bool RsGenExchange::updatePublicRequestStatus(const uint32_t &token, const uint32_t &status)
{
return mDataAccess->updatePublicRequestStatus(token, status);
}
bool RsGenExchange::disposeOfPublicToken(const uint32_t &token)
{
return mDataAccess->disposeOfPublicToken(token);
}
RsGeneralDataService* RsGenExchange::getDataStore()
{
return mDataStore;
}
bool RsGenExchange::getGroupKeys(const RsGxsGroupId &grpId, RsTlvSecurityKeySet &keySet)
{
if(grpId.empty())
return false;
RsStackMutex stack(mGenMtx);
std::map<RsGxsGroupId, RsGxsGrpMetaData*> grpMeta;
grpMeta[grpId] = NULL;
mDataStore->retrieveGxsGrpMetaData(grpMeta);
if(grpMeta.empty())
return false;
RsGxsGrpMetaData* meta = grpMeta[grpId];
if(meta == NULL)
return false;
keySet = meta->keys;
return true;
}
void RsGenExchange::createDummyGroup(RsGxsGrpItem *grpItem)
{
RsStackMutex stack(mGenMtx);
RsNxsGrp* grp = new RsNxsGrp(mServType);
uint32_t size = mSerialiser->size(grpItem);
char gData[size];
bool ok = mSerialiser->serialise(grpItem, gData, &size);
grp->grp.setBinData(gData, size);
RsTlvSecurityKeySet privateKeySet, publicKeySet;
generateGroupKeys(privateKeySet, publicKeySet,
!(grpItem->meta.mGroupFlags & GXS_SERV::FLAG_PRIVACY_PUBLIC));
// find private admin key
RsTlvSecurityKey privAdminKey;
std::map<std::string, RsTlvSecurityKey>::iterator mit_keys = privateKeySet.keys.begin();
bool privKeyFound = false;
for(; mit_keys != privateKeySet.keys.end(); mit_keys++)
{
RsTlvSecurityKey& key = mit_keys->second;
if(key.keyFlags == (RSTLV_KEY_DISTRIB_ADMIN | RSTLV_KEY_TYPE_FULL))
{
privAdminKey = key;
privKeyFound = true;
}
}
if(privKeyFound)
{
// get group id from private admin key id
grpItem->meta.mGroupId = grp->grpId = privAdminKey.keyId;
}
else
{
ok = false;
}
service_CreateGroup(grpItem, privateKeySet);
if(ok)
{
grp->metaData = new RsGxsGrpMetaData();
grpItem->meta.mPublishTs = time(NULL);
*(grp->metaData) = grpItem->meta;
grp->metaData->mSubscribeFlags = GXS_SERV::GROUP_SUBSCRIBE_ADMIN;
createGroup(grp, privateKeySet, publicKeySet);
mDataAccess->addGroupData(grp);
}
if(!ok)
{
#ifdef GEN_EXCH_DEBUG
#endif
std::cerr << "RsGenExchange::createDummyGroup(); failed to publish grp " << std::endl;
delete grp;
}
delete grpItem;
}
void RsGenExchange::processRecvdData()
{
processRecvdGroups();
processRecvdMessages();
}
void RsGenExchange::processRecvdMessages()
{
RsStackMutex stack(mGenMtx);
std::vector<RsNxsMsg*>::iterator vit = mReceivedMsgs.begin();
GxsMsgReq msgIds;
std::map<RsNxsMsg*, RsGxsMsgMetaData*> msgs;
std::map<RsGxsGroupId, RsGxsGrpMetaData*> grpMetas;
// coalesce group meta retrieval for performance
for(; vit != mReceivedMsgs.end(); vit++)
{
RsNxsMsg* msg = *vit;
grpMetas.insert(std::make_pair(msg->grpId, (RsGxsGrpMetaData*)NULL));
}
mDataStore->retrieveGxsGrpMetaData(grpMetas);
for(vit = mReceivedMsgs.begin(); vit != mReceivedMsgs.end(); vit++)
{
RsNxsMsg* msg = *vit;
RsGxsMsgMetaData* meta = new RsGxsMsgMetaData();
bool ok = meta->deserialise(msg->meta.bin_data, &(msg->meta.bin_len));
if(ok)
{
std::map<RsGxsGroupId, RsGxsGrpMetaData*>::iterator mit = grpMetas.find(msg->grpId);
// validate msg
if(mit != grpMetas.end()){
RsGxsGrpMetaData* grpMeta = mit->second;
ok = true;
msg->metaData = meta;
ok &= validateMsg(msg, grpMeta->mGroupFlags, grpMeta->keys);
msg->metaData = NULL;
}
else
ok = false;
if(ok)
{
meta->mMsgStatus = GXS_SERV::GXS_MSG_STATUS_UNPROCESSED | GXS_SERV::GXS_MSG_STATUS_UNREAD;
msgs.insert(std::make_pair(msg, meta));
msgIds[msg->grpId].push_back(msg->msgId);
}
}
if(!ok)
{
/*********************************************************************
* ONCE AGAIN - You fail to handle the case where the Key is not in the Cache.
* When this happens -- and it will happen frequently!
* You MUST retry.
*
* Suggested approach:
* 1) Change validateMsg() and createMsgSignatures to return INT instead of BOOL.
* 2) return -1 for fail , 0 for missing keys, 1 for success.
* 3) if missing keys, put on queue and retry in 1 or 2 seconds.
*
************************************************************************/
#ifdef GXS_GENX_DEBUG
std::cerr << "failed to deserialise incoming meta, grpId: "
<< msg->grpId << ", msgId: " << msg->msgId << std::endl;
#endif
delete msg;
delete meta;
}
}
std::map<RsGxsGroupId, RsGxsGrpMetaData*>::iterator mit = grpMetas.begin();
// clean up resources
for(; mit != grpMetas.end(); mit++)
{
delete mit->second;
}
if(!msgIds.empty())
{
mDataStore->storeMessage(msgs);
RsGxsMsgChange* c = new RsGxsMsgChange();
c->msgChangeMap = msgIds;
mNotifications.push_back(c);
}
mReceivedMsgs.clear();
}
void RsGenExchange::processRecvdGroups()
{
RsStackMutex stack(mGenMtx);
std::vector<RsNxsGrp*>::iterator vit = mReceivedGrps.begin();
std::map<RsNxsGrp*, RsGxsGrpMetaData*> grps;
std::list<RsGxsGroupId> grpIds;
for(; vit != mReceivedGrps.end(); vit++)
{
RsNxsGrp* grp = *vit;
RsGxsGrpMetaData* meta = new RsGxsGrpMetaData();
bool ok = meta->deserialise(grp->meta.bin_data, grp->meta.bin_len);
if(ok)
{
meta->mGroupStatus = GXS_SERV::GXS_GRP_STATUS_UNPROCESSED | GXS_SERV::GXS_GRP_STATUS_UNREAD;
grps.insert(std::make_pair(grp, meta));
grpIds.push_back(grp->grpId);
}
else
{
#ifdef GXS_GENX_DEBUG
std::cerr << "failed to deserialise incoming meta, grpId: "
<< grp->grpId << std::endl;
#endif
delete grp;
delete meta;
}
}
if(!grpIds.empty())
{
RsGxsGroupChange* c = new RsGxsGroupChange();
c->mGrpIdList = grpIds;
mNotifications.push_back(c);
mDataStore->storeGroup(grps);
}
mReceivedGrps.clear();
}