// See the file "COPYING" in the main distribution directory for copyright. #include "zeek-config.h" #include "NFS.h" #include #include #include "BroString.h" #include "NetVar.h" #include "XDR.h" #include "Event.h" #include "events.bif.h" using namespace analyzer::rpc; int NFS_Interp::RPC_BuildCall(RPC_CallInfo* c, const u_char*& buf, int& n) { if ( c->Program() != 100003 ) Weird("bad_RPC_program", fmt("%d", c->Program())); uint32_t proc = c->Proc(); // The call arguments, depends on the call type obviously ... Val *callarg = 0; switch ( proc ) { case BifEnum::NFS3::PROC_NULL: break; case BifEnum::NFS3::PROC_GETATTR: callarg = nfs3_fh(buf, n); break; case BifEnum::NFS3::PROC_SETATTR: callarg = nfs3_sattrargs(buf, n); break; case BifEnum::NFS3::PROC_LOOKUP: callarg = nfs3_diropargs(buf, n); break; case BifEnum::NFS3::PROC_READ: callarg = nfs3_readargs(buf, n); break; case BifEnum::NFS3::PROC_READLINK: callarg = nfs3_fh(buf, n); break; case BifEnum::NFS3::PROC_SYMLINK: callarg = nfs3_symlinkargs(buf, n); break; case BifEnum::NFS3::PROC_LINK: callarg = nfs3_linkargs(buf, n); break; case BifEnum::NFS3::PROC_WRITE: callarg = nfs3_writeargs(buf, n); break; case BifEnum::NFS3::PROC_CREATE: callarg = nfs3_diropargs(buf, n); // TODO: implement create attributes. For now we just skip // over them. n = 0; break; case BifEnum::NFS3::PROC_MKDIR: callarg = nfs3_diropargs(buf, n); // TODO: implement mkdir attributes. For now we just skip // over them. n = 0; break; case BifEnum::NFS3::PROC_REMOVE: callarg = nfs3_diropargs(buf, n); break; case BifEnum::NFS3::PROC_RMDIR: callarg = nfs3_diropargs(buf, n); break; case BifEnum::NFS3::PROC_RENAME: callarg = nfs3_renameopargs(buf, n); break; case BifEnum::NFS3::PROC_READDIR: callarg = nfs3_readdirargs(false, buf, n); break; case BifEnum::NFS3::PROC_READDIRPLUS: callarg = nfs3_readdirargs(true, buf, n); break; default: callarg = 0; if ( proc < BifEnum::NFS3::PROC_END_OF_PROCS ) { // We know the procedure but haven't implemented it. // Otherwise DeliverRPC would complain about // excess_RPC. n = 0; } else Weird("unknown_NFS_request", fmt("%u", proc)); // Return 1 so that replies to unprocessed calls will still // be processed, and the return status extracted. return 1; } if ( ! buf ) { // There was a parse error while trying to extract the call // arguments. However, we don't know where exactly it // happened and whether Vals where already allocated (e.g., a // RecordVal was allocated but we failed to fill it). So we // Unref() the call arguments, and we are fine. Unref(callarg); callarg = 0; return 0; } c->AddVal(callarg); // It's save to AddVal(0). return 1; } int NFS_Interp::RPC_BuildReply(RPC_CallInfo* c, BifEnum::rpc_status rpc_status, const u_char*& buf, int& n, double start_time, double last_time, int reply_len) { EventHandlerPtr event = 0; Val *reply = 0; BifEnum::NFS3::status_t nfs_status = BifEnum::NFS3::NFS3ERR_OK; bool rpc_success = ( rpc_status == BifEnum::RPC_SUCCESS ); // Reply always starts with the NFS status. if ( rpc_success ) { if ( n >= 4 ) nfs_status = (BifEnum::NFS3::status_t)extract_XDR_uint32(buf, n); else nfs_status = BifEnum::NFS3::NFS3ERR_UNKNOWN; } if ( nfs_reply_status ) { auto vl = event_common_vl(c, rpc_status, nfs_status, start_time, last_time, reply_len, 0); analyzer->ConnectionEventFast(nfs_reply_status, std::move(vl)); } if ( ! rpc_success ) { // We set the buffer to NULL, the function that extract the // reply from the data stream will then return empty records. // buf = NULL; n = 0; } switch ( c->Proc() ) { case BifEnum::NFS3::PROC_NULL: event = nfs_proc_null; break; case BifEnum::NFS3::PROC_GETATTR: reply = nfs3_fattr(buf, n); event = nfs_proc_getattr; break; case BifEnum::NFS3::PROC_SETATTR: reply = nfs3_sattr_reply(buf, n, nfs_status); event = nfs_proc_sattr; break; case BifEnum::NFS3::PROC_LOOKUP: reply = nfs3_lookup_reply(buf, n, nfs_status); event = nfs_proc_lookup; break; case BifEnum::NFS3::PROC_READ: bro_uint_t offset; offset = c->RequestVal()->AsRecordVal()->Lookup(1)->AsCount(); reply = nfs3_read_reply(buf, n, nfs_status, offset); event = nfs_proc_read; break; case BifEnum::NFS3::PROC_READLINK: reply = nfs3_readlink_reply(buf, n, nfs_status); event = nfs_proc_readlink; break; case BifEnum::NFS3::PROC_SYMLINK: reply = nfs3_newobj_reply(buf, n, nfs_status); event = nfs_proc_symlink; break; case BifEnum::NFS3::PROC_LINK: reply = nfs3_link_reply(buf, n, nfs_status); event = nfs_proc_link; break; case BifEnum::NFS3::PROC_WRITE: reply = nfs3_write_reply(buf, n, nfs_status); event = nfs_proc_write; break; case BifEnum::NFS3::PROC_CREATE: reply = nfs3_newobj_reply(buf, n, nfs_status); event = nfs_proc_create; break; case BifEnum::NFS3::PROC_MKDIR: reply = nfs3_newobj_reply(buf, n, nfs_status); event = nfs_proc_mkdir; break; case BifEnum::NFS3::PROC_REMOVE: reply = nfs3_delobj_reply(buf, n); event = nfs_proc_remove; break; case BifEnum::NFS3::PROC_RMDIR: reply = nfs3_delobj_reply(buf, n); event = nfs_proc_rmdir; break; case BifEnum::NFS3::PROC_RENAME: reply = nfs3_renameobj_reply(buf, n); event = nfs_proc_rename; break; case BifEnum::NFS3::PROC_READDIR: reply = nfs3_readdir_reply(false, buf, n, nfs_status); event = nfs_proc_readdir; break; case BifEnum::NFS3::PROC_READDIRPLUS: reply = nfs3_readdir_reply(true, buf, n, nfs_status); event = nfs_proc_readdir; break; default: if ( c->Proc() < BifEnum::NFS3::PROC_END_OF_PROCS ) { // We know the procedure but haven't implemented it. // Otherwise DeliverRPC would complain about // excess_RPC. n = 0; reply = BifType::Enum::NFS3::proc_t->GetVal(c->Proc()); event = nfs_proc_not_implemented; } else return 0; } if ( rpc_success && ! buf ) { // There was a parse error. We have to unref the reply. (see // also comments in RPC_BuildCall. Unref(reply); reply = 0; return 0; } // Note: if reply == 0, it won't be added to the val_list for the // event. While we can check for that on the policy layer it's kinda // ugly, because it's contrary to the event prototype. But having // this optional argument to the event is really helpful. Otherwise I // have to let reply point to a RecordVal where all fields are // optional and all are set to 0 ... if ( event ) { Val *request = c->TakeRequestVal(); auto vl = event_common_vl(c, rpc_status, nfs_status, start_time, last_time, reply_len, (bool)request + (bool)reply); if ( request ) vl.push_back(request); if ( reply ) vl.push_back(reply); analyzer->ConnectionEventFast(event, std::move(vl)); } else Unref(reply); return 1; } StringVal* NFS_Interp::nfs3_file_data(const u_char*& buf, int& n, uint64_t offset, int size) { int data_n; // extract the data, move buf and n const u_char *data = extract_XDR_opaque(buf, n, data_n, 1 << 30, true); // check whether we have to deliver data to the event if ( ! BifConst::NFS3::return_data ) return 0; if ( BifConst::NFS3::return_data_first_only && offset != 0 ) return 0; // Ok, so we want to return some data data_n = min(data_n, size); data_n = min(data_n, int(BifConst::NFS3::return_data_max)); if ( data && data_n > 0 ) return new StringVal(new BroString(data, data_n, 0)); return 0; } val_list NFS_Interp::event_common_vl(RPC_CallInfo *c, BifEnum::rpc_status rpc_status, BifEnum::NFS3::status_t nfs_status, double rep_start_time, double rep_last_time, int reply_len, int extra_elements) { // Returns a new val_list that already has a conn_val, and nfs3_info. // These are the first parameters for each nfs_* event ... val_list vl(2 + extra_elements); vl.push_back(analyzer->BuildConnVal()); VectorVal* auxgids = new VectorVal(internal_type("index_vec")->AsVectorType()); for ( size_t i = 0; i < c->AuxGIDs().size(); ++i ) auxgids->Assign(i, val_mgr->GetCount(c->AuxGIDs()[i])); RecordVal *info = new RecordVal(BifType::Record::NFS3::info_t); info->Assign(0, BifType::Enum::rpc_status->GetVal(rpc_status)); info->Assign(1, BifType::Enum::NFS3::status_t->GetVal(nfs_status)); info->Assign(2, make_intrusive(c->StartTime(), TYPE_TIME)); info->Assign(3, make_intrusive(c->LastTime()-c->StartTime(), TYPE_INTERVAL)); info->Assign(4, val_mgr->GetCount(c->RPCLen())); info->Assign(5, make_intrusive(rep_start_time, TYPE_TIME)); info->Assign(6, make_intrusive(rep_last_time-rep_start_time, TYPE_INTERVAL)); info->Assign(7, val_mgr->GetCount(reply_len)); info->Assign(8, val_mgr->GetCount(c->Uid())); info->Assign(9, val_mgr->GetCount(c->Gid())); info->Assign(10, val_mgr->GetCount(c->Stamp())); info->Assign(11, make_intrusive(c->MachineName())); info->Assign(12, auxgids); vl.push_back(info); return vl; } StringVal* NFS_Interp::nfs3_fh(const u_char*& buf, int& n) { int fh_n; const u_char* fh = extract_XDR_opaque(buf, n, fh_n, 64); if ( ! fh ) return 0; return new StringVal(new BroString(fh, fh_n, 0)); } RecordVal* NFS_Interp::nfs3_sattr(const u_char*& buf, int& n) { RecordVal* attrs = new RecordVal(BifType::Record::NFS3::sattr_t); attrs->Assign(0, 0); // mode int mode_set_it = extract_XDR_uint32(buf, n); if ( mode_set_it ) attrs->Assign(0, ExtractUint32(buf, n)); // mode attrs->Assign(1, 0); // uid int uid_set_it = extract_XDR_uint32(buf, n); if ( uid_set_it ) attrs->Assign(1, ExtractUint32(buf, n)); // uid attrs->Assign(2, 0); // gid int gid_set_it = extract_XDR_uint32(buf, n); if ( gid_set_it ) attrs->Assign(2, ExtractUint32(buf, n)); // gid attrs->Assign(3, 0); // size int size_set_it = extract_XDR_uint32(buf, n); if ( size_set_it ) attrs->Assign(3, ExtractTime(buf, n)); // size attrs->Assign(4, nfs3_time_how(buf, n)); // time_how attrs->Assign(5, nfs3_time_how(buf, n)); // time_how return attrs; } RecordVal* NFS_Interp::nfs3_sattr_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal* rep = new RecordVal(BifType::Record::NFS3::sattr_reply_t); if ( status == BifEnum::NFS3::NFS3ERR_OK ) { rep->Assign(0, nfs3_pre_op_attr(buf, n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); } else { rep->Assign(1, 0); rep->Assign(2, 0); } return rep; } RecordVal* NFS_Interp::nfs3_fattr(const u_char*& buf, int& n) { RecordVal* attrs = new RecordVal(BifType::Record::NFS3::fattr_t); attrs->Assign(0, nfs3_ftype(buf, n)); // file type attrs->Assign(1, ExtractUint32(buf, n)); // mode attrs->Assign(2, ExtractUint32(buf, n)); // nlink attrs->Assign(3, ExtractUint32(buf, n)); // uid attrs->Assign(4, ExtractUint32(buf, n)); // gid attrs->Assign(5, ExtractUint64(buf, n)); // size attrs->Assign(6, ExtractUint64(buf, n)); // used attrs->Assign(7, ExtractUint32(buf, n)); // rdev1 attrs->Assign(8, ExtractUint32(buf, n)); // rdev2 attrs->Assign(9, ExtractUint64(buf, n)); // fsid attrs->Assign(10, ExtractUint64(buf, n)); // fileid attrs->Assign(11, ExtractTime(buf, n)); // atime attrs->Assign(12, ExtractTime(buf, n)); // mtime attrs->Assign(13, ExtractTime(buf, n)); // ctime return attrs; } EnumVal* NFS_Interp::nfs3_time_how(const u_char*& buf, int& n) { BifEnum::NFS3::time_how_t t = (BifEnum::NFS3::time_how_t)extract_XDR_uint32(buf, n); return BifType::Enum::NFS3::time_how_t->GetVal(t); } EnumVal* NFS_Interp::nfs3_ftype(const u_char*& buf, int& n) { BifEnum::NFS3::file_type_t t = (BifEnum::NFS3::file_type_t)extract_XDR_uint32(buf, n); return BifType::Enum::NFS3::file_type_t->GetVal(t); } RecordVal* NFS_Interp::nfs3_wcc_attr(const u_char*& buf, int& n) { RecordVal* attrs = new RecordVal(BifType::Record::NFS3::wcc_attr_t); attrs->Assign(0, ExtractUint64(buf, n)); // size attrs->Assign(1, ExtractTime(buf, n)); // mtime attrs->Assign(2, ExtractTime(buf, n)); // ctime return attrs; } StringVal *NFS_Interp::nfs3_filename(const u_char*& buf, int& n) { int name_len; const u_char* name = extract_XDR_opaque(buf, n, name_len); if ( ! name ) return 0; return new StringVal(new BroString(name, name_len, 0)); } RecordVal *NFS_Interp::nfs3_diropargs(const u_char*& buf, int& n) { RecordVal *diropargs = new RecordVal(BifType::Record::NFS3::diropargs_t); diropargs->Assign(0, nfs3_fh(buf, n)); diropargs->Assign(1, nfs3_filename(buf, n)); return diropargs; } RecordVal* NFS_Interp::nfs3_symlinkdata(const u_char*& buf, int& n) { RecordVal* symlinkdata = new RecordVal(BifType::Record::NFS3::symlinkdata_t); symlinkdata->Assign(0, nfs3_sattr(buf, n)); symlinkdata->Assign(1, nfs3_nfspath(buf, n)); return symlinkdata; } RecordVal *NFS_Interp::nfs3_renameopargs(const u_char*& buf, int& n) { RecordVal *renameopargs = new RecordVal(BifType::Record::NFS3::renameopargs_t); renameopargs->Assign(0, nfs3_fh(buf, n)); renameopargs->Assign(1, nfs3_filename(buf, n)); renameopargs->Assign(2, nfs3_fh(buf, n)); renameopargs->Assign(3, nfs3_filename(buf, n)); return renameopargs; } RecordVal* NFS_Interp::nfs3_post_op_attr(const u_char*& buf, int& n) { int have_attrs = extract_XDR_uint32(buf, n); if ( have_attrs ) return nfs3_fattr(buf, n); return 0; } StringVal* NFS_Interp::nfs3_post_op_fh(const u_char*& buf, int& n) { int have_fh = extract_XDR_uint32(buf, n); if ( have_fh ) return nfs3_fh(buf, n); return 0; } RecordVal* NFS_Interp::nfs3_pre_op_attr(const u_char*& buf, int& n) { int have_attrs = extract_XDR_uint32(buf, n); if ( have_attrs ) return nfs3_wcc_attr(buf, n); return 0; } EnumVal *NFS_Interp::nfs3_stable_how(const u_char*& buf, int& n) { BifEnum::NFS3::stable_how_t stable = (BifEnum::NFS3::stable_how_t)extract_XDR_uint32(buf, n); return BifType::Enum::NFS3::stable_how_t->GetVal(stable); } RecordVal* NFS_Interp::nfs3_lookup_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::lookup_reply_t); if ( status == BifEnum::NFS3::NFS3ERR_OK ) { rep->Assign(0, nfs3_fh(buf,n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); rep->Assign(2, nfs3_post_op_attr(buf, n)); } else { rep->Assign(0, 0); rep->Assign(1, 0); rep->Assign(2, nfs3_post_op_attr(buf, n)); } return rep; } RecordVal *NFS_Interp::nfs3_readargs(const u_char*& buf, int& n) { RecordVal *readargs = new RecordVal(BifType::Record::NFS3::readargs_t); readargs->Assign(0, nfs3_fh(buf, n)); readargs->Assign(1, ExtractUint64(buf, n)); // offset readargs->Assign(2, ExtractUint32(buf,n)); // size return readargs; } RecordVal* NFS_Interp::nfs3_read_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status, bro_uint_t offset) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::read_reply_t); if (status == BifEnum::NFS3::NFS3ERR_OK) { uint32_t bytes_read; rep->Assign(0, nfs3_post_op_attr(buf, n)); bytes_read = extract_XDR_uint32(buf, n); rep->Assign(1, val_mgr->GetCount(bytes_read)); rep->Assign(2, ExtractBool(buf, n)); rep->Assign(3, nfs3_file_data(buf, n, offset, bytes_read)); } else { rep->Assign(0, nfs3_post_op_attr(buf, n)); } return rep; } RecordVal* NFS_Interp::nfs3_readlink_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::readlink_reply_t); if (status == BifEnum::NFS3::NFS3ERR_OK) { rep->Assign(0, nfs3_post_op_attr(buf, n)); rep->Assign(1, nfs3_nfspath(buf,n)); } else { rep->Assign(0, nfs3_post_op_attr(buf, n)); } return rep; } RecordVal* NFS_Interp::nfs3_link_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal* rep = new RecordVal(BifType::Record::NFS3::link_reply_t); if ( status == BifEnum::NFS3::NFS3ERR_OK ) { rep->Assign(0, nfs3_post_op_attr(buf, n)); // wcc_data rep->Assign(1, nfs3_pre_op_attr(buf, n)); rep->Assign(2, nfs3_post_op_attr(buf, n)); } return rep; } RecordVal* NFS_Interp::nfs3_symlinkargs(const u_char*& buf, int& n) { RecordVal* symlinkargs = new RecordVal(BifType::Record::NFS3::symlinkargs_t); symlinkargs->Assign(0, nfs3_diropargs(buf, n)); symlinkargs->Assign(1, nfs3_symlinkdata(buf, n)); return symlinkargs; } RecordVal* NFS_Interp::nfs3_sattrargs(const u_char*& buf, int& n) { RecordVal* sattrargs = new RecordVal(BifType::Record::NFS3::sattrargs_t); sattrargs->Assign(0, nfs3_fh(buf, n)); sattrargs->Assign(1, nfs3_sattr(buf, n)); return sattrargs; } RecordVal* NFS_Interp::nfs3_linkargs(const u_char*& buf, int& n) { RecordVal* linkargs = new RecordVal(BifType::Record::NFS3::linkargs_t); linkargs->Assign(0, nfs3_fh(buf, n)); linkargs->Assign(1, nfs3_diropargs(buf, n)); return linkargs; } RecordVal *NFS_Interp::nfs3_writeargs(const u_char*& buf, int& n) { uint32_t bytes; uint64_t offset; RecordVal *writeargs = new RecordVal(BifType::Record::NFS3::writeargs_t); writeargs->Assign(0, nfs3_fh(buf, n)); offset = extract_XDR_uint64(buf, n); writeargs->Assign(1, val_mgr->GetCount(offset)); // offset bytes = extract_XDR_uint32(buf, n); writeargs->Assign(2, val_mgr->GetCount(bytes)); // size writeargs->Assign(3, nfs3_stable_how(buf, n)); writeargs->Assign(4, nfs3_file_data(buf, n, offset, bytes)); return writeargs; } RecordVal *NFS_Interp::nfs3_write_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::write_reply_t); if ( status == BifEnum::NFS3::NFS3ERR_OK ) { rep->Assign(0, nfs3_pre_op_attr(buf, n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); rep->Assign(2, ExtractUint32(buf, n)); rep->Assign(3, nfs3_stable_how(buf, n)); // Writeverf. While the RFC says that this should be a fixed // length opaque, it specifies the lenght as 8 bytes, so we // can also just as easily extract a uint64. rep->Assign(4, ExtractUint64(buf, n)); } else { rep->Assign(0, nfs3_post_op_attr(buf, n)); rep->Assign(1, nfs3_pre_op_attr(buf, n)); } return rep; } RecordVal* NFS_Interp::nfs3_newobj_reply(const u_char*& buf, int& n, BifEnum::NFS3::status_t status) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::newobj_reply_t); if (status == BifEnum::NFS3::NFS3ERR_OK) { int i = 0; rep->Assign(0, nfs3_post_op_fh(buf,n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); // wcc_data rep->Assign(2, nfs3_pre_op_attr(buf, n)); rep->Assign(3, nfs3_post_op_attr(buf, n)); } else { rep->Assign(0, 0); rep->Assign(1, 0); rep->Assign(2, nfs3_pre_op_attr(buf, n)); rep->Assign(3, nfs3_post_op_attr(buf, n)); } return rep; } RecordVal* NFS_Interp::nfs3_delobj_reply(const u_char*& buf, int& n) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::delobj_reply_t); // wcc_data rep->Assign(0, nfs3_pre_op_attr(buf, n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); return rep; } RecordVal* NFS_Interp::nfs3_renameobj_reply(const u_char*& buf, int& n) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::renameobj_reply_t); // wcc_data rep->Assign(0, nfs3_pre_op_attr(buf, n)); rep->Assign(1, nfs3_post_op_attr(buf, n)); rep->Assign(2, nfs3_pre_op_attr(buf, n)); rep->Assign(3, nfs3_post_op_attr(buf, n)); return rep; } RecordVal* NFS_Interp::nfs3_readdirargs(bool isplus, const u_char*& buf, int&n) { RecordVal *args = new RecordVal(BifType::Record::NFS3::readdirargs_t); args->Assign(0, val_mgr->GetBool(isplus)); args->Assign(1, nfs3_fh(buf, n)); args->Assign(2, ExtractUint64(buf,n)); // cookie args->Assign(3, ExtractUint64(buf,n)); // cookieverf args->Assign(4, ExtractUint32(buf,n)); // dircount if ( isplus ) args->Assign(5, ExtractUint32(buf,n)); return args; } RecordVal* NFS_Interp::nfs3_readdir_reply(bool isplus, const u_char*& buf, int&n, BifEnum::NFS3::status_t status) { RecordVal *rep = new RecordVal(BifType::Record::NFS3::readdir_reply_t); rep->Assign(0, val_mgr->GetBool(isplus)); if ( status == BifEnum::NFS3::NFS3ERR_OK ) { unsigned pos; VectorVal *entries = new VectorVal(BifType::Vector::NFS3::direntry_vec_t); rep->Assign(1, nfs3_post_op_attr(buf,n)); // dir_attr rep->Assign(2, ExtractUint64(buf,n)); // cookieverf pos = 1; while ( extract_XDR_uint32(buf,n) ) { RecordVal *entry = new RecordVal(BifType::Record::NFS3::direntry_t); entry->Assign(0, ExtractUint64(buf,n)); // fileid entry->Assign(1, nfs3_filename(buf,n)); // fname entry->Assign(2, ExtractUint64(buf,n)); // cookie if ( isplus ) { entry->Assign(3, nfs3_post_op_attr(buf,n)); entry->Assign(4, nfs3_post_op_fh(buf,n)); } entries->Assign(pos, entry); pos++; } rep->Assign(3, entries); rep->Assign(4, ExtractBool(buf,n)); // eof } else { rep->Assign(1, nfs3_post_op_attr(buf,n)); } return rep; } Val* NFS_Interp::ExtractUint32(const u_char*& buf, int& n) { return val_mgr->GetCount(extract_XDR_uint32(buf, n)); } Val* NFS_Interp::ExtractUint64(const u_char*& buf, int& n) { return val_mgr->GetCount(extract_XDR_uint64(buf, n)); } Val* NFS_Interp::ExtractTime(const u_char*& buf, int& n) { return new Val(extract_XDR_time(buf, n), TYPE_TIME); } Val* NFS_Interp::ExtractInterval(const u_char*& buf, int& n) { return new IntervalVal(double(extract_XDR_uint32(buf, n)), 1.0); } Val* NFS_Interp::ExtractBool(const u_char*& buf, int& n) { return val_mgr->GetBool(extract_XDR_uint32(buf, n)); } NFS_Analyzer::NFS_Analyzer(Connection* conn) : RPC_Analyzer("NFS", conn, new NFS_Interp(this)) { orig_rpc = resp_rpc = 0; } void NFS_Analyzer::Init() { RPC_Analyzer::Init(); if ( Conn()->ConnTransport() == TRANSPORT_TCP ) { orig_rpc = new Contents_RPC(Conn(), true, interp); resp_rpc = new Contents_RPC(Conn(), false, interp); AddSupportAnalyzer(orig_rpc); AddSupportAnalyzer(resp_rpc); } }