/* packet-cemi.c * Routines for cEMI (Common External Message Interface) dissection * By Jan Kessler * Copyright 2004, Jan Kessler * * Wireshark - Network traffic analyzer * By Gerald Combs * Copyright 1998 Gerald Combs * * SPDX-License-Identifier: GPL-2.0-or-later */ #include "config.h" #include #include "packet-knxip.h" void proto_register_cemi(void); void proto_reg_handoff_cemi(void); /* cEMI Message Codes */ #define CEMI_L_BUSMON_IND 0x2B #define CEMI_L_RAW_IND 0x2D #define CEMI_L_RAW_REQ 0x10 #define CEMI_L_RAW_CON 0x2F #define CEMI_L_DATA_REQ 0x11 #define CEMI_L_DATA_CON 0x2E #define CEMI_L_DATA_IND 0x29 #define CEMI_L_POLL_DATA_REQ 0x13 #define CEMI_L_POLL_DATA_CON 0x25 #define CEMI_T_DATA_INDIVIDUAL_REQ 0x4A #define CEMI_T_DATA_INDIVIDUAL_IND 0x94 #define CEMI_T_DATA_CONNECTED_REQ 0x41 #define CEMI_T_DATA_CONNECTED_IND 0x89 #define CEMI_M_PROPREAD_REQ 0xFC #define CEMI_M_PROPREAD_CON 0xFB #define CEMI_M_PROPWRITE_REQ 0xF6 #define CEMI_M_PROPWRITE_CON 0xF5 #define CEMI_M_PROPINFO_IND 0xF7 #define CEMI_M_FUNCPROPCMD_REQ 0xF8 #define CEMI_M_FUNCPROPREAD_REQ 0xF9 #define CEMI_M_FUNCPROP_CON 0xFA #define CEMI_M_RESET_REQ 0xF1 #define CEMI_M_RESET_IND 0xF0 /* Additional Information Types */ /* 0x00 Reserved. */ #define CEMI_PL_MEDIUM_INFORMATION 0x01 /*!< (2 octets) Domain Address used by PL medium; Client <-> Server */ #define CEMI_RF_MEDIUM_INFORMATION 0x02 /*!< (7 octet) RF-Control byte and serial number/DoA; Client <-> Server Busmonitor */ #define CEMI_STATUS_INFO 0x03 /*!< (1 octet) Busmonitor Error Flags; see clause 2.5.5.5; Client <- Server */ #define CEMI_TIMESTAMP_RELATIVE 0x04 /*!< (2 octets) Relative timestamp; e.g. for L_Raw.ind; Client <- Server */ #define CEMI_TIME_DELAY_UNTIL_SENDING 0x05 /*!< (4 octets) Time delay (L_Raw.req, see clause 2.5.5.3); Client <- Server */ /* 0x06-0xFE Not used. */ /* 0xFF For future system extension (ESC Code). */ /* Error Codes */ #define CEMI_UNSPECIFIED_ERROR 0x00 /*!< Unknown error (R/W). */ #define CEMI_OUT_OF_RANGE 0x01 /*!< Write value not allowed (general, if not error 2 or 3) (W). */ #define CEMI_OUT_OF_MAXRANGE 0x02 /*!< Write value to high (W). */ #define CEMI_OUT_OF_MINRANGE 0x03 /*!< Write value to low (W). */ #define CEMI_MEMORY_ERROR 0x04 /*!< Memory can not be written or only with fault(s) (W). */ #define CEMI_READ_ONLY 0x05 /*!< Write access to a 'read only' or a write protected property (W). */ #define CEMI_ILLEGAL_COMMAND 0x06 /*!< COMMAND not valid or not supported (W). */ #define CEMI_VOID_DP 0x07 /*!< Read or write access to an non existing property (R/W). */ #define CEMI_TYPE_CONFLICT 0x08 /*!< Write access with a wrong data type (datapoint length) (W). */ #define CEMI_PROP_INDEX_RANGE_ERROR 0x09 /* Read or write access to a non existing property array index (R/W). */ /* Common EMI specific device server properties */ #define CEMI_PID_DOMAIN_ADDRESS 0x70 /*!< Domain Address of a PL medium (cEMI server) device. PDT_UNSIGNED_INT O - r/w */ #define CEMI_PID_IO_LIST 0x71 /*!< List of Interface Objects in the (cEMI server) device. PDT_UNSIGNED_INT O - r/w */ #define CEMI_PID_MEDIUM_TYPE 0x51 /*!< Media Type(s) supported by cEMI server. DPT_Media M - read only */ #define CEMI_PID_COMM_MODE 0x52 /*!< Link Layer / Raw (Busmonitor) / Transport L. DPT_CommMode O - r/w */ #define CEMI_PID_MEDIUM_AVAILABILITY 0x53 /*!< Bus available (1) or not (0) ? DPT_Media O - read only */ #define CEMI_PID_ADD_INFO_TYPES 0x54 /*!< cEMI supported Additional Information Types. DPT_AddInfoTypes O - read only */ #define CEMI_PID_TRANSP_ENABLE 0x56 /*!< LL Transparency Mode of cEMI server. DPT_Enable O - r/w */ /* 0x57 Reserved for cEMI client's subnetwork address. PDT_UNSIGNED_CHAR O - r/w */ /* 0x58 Reserved for cEMI client's device address. PDT_UNSIGNED_CHAR O - r/w */ /* 0x59 t.b.d.*/ /* 0x60 t.b.d.*/ /* 0x61 DoA Filter. t.b.d. O - read only */ #define CEMI_PID_MEDIUM_TYPE_TP0 0x0001 /*!< TP 0 */ #define CEMI_PID_MEDIUM_TYPE_TP1 0x0002 /*!< TP 1 */ #define CEMI_PID_MEDIUM_TYPE_PL110 0x0004 /*!< PL 110 */ #define CEMI_PID_MEDIUM_TYPE_PL132 0x0008 /*!< PL 132 */ #define CEMI_PID_MEDIUM_TYPE_RF 0x0010 /*!< RF */ #define CEMI_PID_COMM_MODE_LL 0x00 /*!< Link Layer = default comm. mode. */ #define CEMI_PID_COMM_MODE_LLB 0x01 /*!< Link Layer Busmonitor. */ #define CEMI_PID_COMM_MODE_LLR 0x02 /*!< Link Layer Raw Frames. */ /* 0x03 Reserved for Network Layer. */ /* 0x04 Reserved for TL group oriented. */ /* 0x05 Reserved for TL connection oriented. */ /* 0x05-0xFF Reserved for other 'destination layers'. */ /* - - - - - - - T R E E V I E W I D E N T I F I E R - - - - - - - - */ /* Initialize the protocol identifier that is needed for the protocol hook and to register the fields in the protocol tree */ static gint proto_cemi; /* Initialize the registered fields identifiers. These fields will be registered with the protocol during initialization. Protocol fields are like type definitions. The protocol dissector later on adds items of these types to the protocol tree. */ static gint hf_bytes; static gint hf_folder; static gint hf_cemi_mc; static gint hf_cemi_error; static gint hf_cemi_ai_length; static gint hf_cemi_aie_type; static gint hf_cemi_aie_length; static gint hf_cemi_ot; static gint hf_cemi_oi; static gint hf_cemi_ox; static gint hf_cemi_px; static gint hf_cemi_pid; static gint hf_cemi_ne; static gint hf_cemi_sx; static gint hf_cemi_ft; static gint hf_cemi_rep; static gint hf_cemi_bt; static gint hf_cemi_prio; static gint hf_cemi_ack; static gint hf_cemi_ce; static gint hf_cemi_at; static gint hf_cemi_hc; static gint hf_cemi_eff; static gint hf_cemi_sa; static gint hf_cemi_da; static gint hf_cemi_len; static gint hf_cemi_tpt; static gint hf_cemi_tst; static gint hf_cemi_num; static gint hf_cemi_tc; static gint hf_cemi_ac; static gint hf_cemi_ad; static gint hf_cemi_ad_memory_length; static gint hf_cemi_ad_channel; static gint hf_cemi_ad_type; static gint hf_cemi_ax; static gint hf_cemi_pw; static gint hf_cemi_pdt; static gint hf_cemi_me; static gint hf_cemi_ra; static gint hf_cemi_wa; static gint hf_cemi_ext_oi; static gint hf_cemi_ext_pid; static gint hf_cemi_ext_ne; static gint hf_cemi_ext_sx; static gint hf_cemi_ext_dt; static gint hf_cemi_ext_px; static gint hf_cemi_ext_memory_length; static gint hf_cemi_ext_memory_address; static gint hf_cemi_memory_length; static gint hf_cemi_memory_address; static gint hf_cemi_memory_address_ext; static gint hf_cemi_level; static gint hf_cemi_snp_pid; static gint hf_cemi_snp_reserved; static gint hf_cemi_dpt_major; static gint hf_cemi_dpt_minor; static gint hf_cemi_scf; static gint hf_cemi_scf_t; static gint hf_cemi_scf_sai; static gint hf_cemi_scf_sbc; static gint hf_cemi_scf_svc; static gint hf_cemi_adc_count; /* Initialize the subtree pointers. These pointers are needed to display the protocol in a structured tree. Subtrees hook on already defined fields or (the topmost) on the protocol itself */ static gint ett_cemi; static gint ett_cemi_ai; static gint ett_cemi_aie; static gint ett_cemi_ctrl1; static gint ett_cemi_ctrl2; static gint ett_cemi_tpci; static gint ett_cemi_apci; static gint ett_cemi_range; static gint ett_cemi_pd; static gint ett_cemi_dpt; static gint ett_cemi_scf; static gint ett_cemi_decrypted; /* - - - - - - - - - - - V A L U E T A B L E S - - - - - - - - - - - - */ /* See following docs: "AN033 v03 cEMI.pdf", "AN057 v01 System B RfV.pdf", "KSG259 2004.02.03 Identifiers.pdf", "03_07_03 Standardized Identifier Tables.pdf" */ /* Message Code */ static const value_string mc_vals[] = { { CEMI_L_BUSMON_IND, "L_Busmon.ind" }, { CEMI_L_RAW_IND, "L_Raw.ind" }, { CEMI_L_RAW_REQ, "L_Raw.req" }, { CEMI_L_RAW_CON, "L_Raw.con" }, { CEMI_L_DATA_REQ, "L_Data.req" }, { CEMI_L_DATA_CON, "L_Data.con" }, { CEMI_L_DATA_IND, "L_Data.ind" }, { CEMI_L_POLL_DATA_REQ, "L_PollData.req" }, { CEMI_L_POLL_DATA_CON, "L_PollData.con" }, { CEMI_T_DATA_INDIVIDUAL_REQ, "T_Data_Individual.req" }, { CEMI_T_DATA_INDIVIDUAL_IND, "T_Data_Individual.ind" }, { CEMI_T_DATA_CONNECTED_REQ, "T_Data_Connected.req" }, { CEMI_T_DATA_CONNECTED_IND, "T_Data_Connected.ind" }, { CEMI_M_PROPREAD_REQ, "M_PropRead.req" }, { CEMI_M_PROPREAD_CON, "M_PropRead.con" }, { CEMI_M_PROPWRITE_REQ, "M_PropWrite.req" }, { CEMI_M_PROPWRITE_CON, "M_PropWrite.con" }, { CEMI_M_PROPINFO_IND, "M_PropInfo.ind" }, { CEMI_M_FUNCPROPCMD_REQ, "M_FuncPropCmd.req" }, { CEMI_M_FUNCPROPREAD_REQ, "M_FuncPropRead.req" }, { CEMI_M_FUNCPROP_CON, "M_FuncProp.con" }, { CEMI_M_RESET_REQ, "M_Reset.req" }, { CEMI_M_RESET_IND, "M_Reset.ind" }, { 0, NULL } }; /* Property access flags */ #define PA_RESPONSE 0x01 #define PA_DATA 0x02 /* Additional Info Element Type */ static const value_string aiet_vals[] = { { 1, "PL Medium Info" }, { 2, "RF Medium Info" }, { 3, "BusMonitor Status Info" }, { 4, "Timestamp Relative" }, { 5, "Time Delay Until Sending" }, { 6, "Extended Relative Timestamp" }, { 7, "BiBat Info" }, { 0, NULL } }; /* Frame Type */ static const value_string ft_vals[] = { { 0, "Extended" }, { 1, "Standard" }, { 0, NULL } }; /* Broadcast Type */ static const value_string bt_vals[] = { { 0, "System" }, { 1, "Domain" }, { 0, NULL } }; /* Priority */ static const value_string prio_vals[] = { { 0, "System" }, { 2, "Urgent" }, { 1, "Normal" }, { 3, "Low" }, { 0, NULL } }; /* Address Type */ static const value_string at_vals[] = { { 0, "Individual" }, { 1, "Group" }, { 0, NULL } }; /* Packet Type */ static const value_string pt_vals[] = { { 0, "Data" }, { 1, "Control" }, { 0, NULL } }; /* Sequence Type */ static const value_string st_vals[] = { { 0, "Unnumbered" }, { 1, "Numbered" }, { 0, NULL } }; /* Transport Layer Code */ static const value_string tc_vals[] = { { 0, "Connect" }, { 1, "Disconnect" }, { 2, "ACK" }, { 3, "NAK" }, { 0, NULL } }; /* Application Layer Code */ #define AC_GroupValueRead 0 #define AC_GroupValueResp 1 #define AC_GroupValueWrite 2 #define AC_IndAddrWrite 3 #define AC_IndAddrRead 4 #define AC_IndAddrResp 5 #define AC_AdcRead 6 #define AC_AdcResp 7 #define AC_MemRead 8 #define AC_MemResp 9 #define AC_MemWrite 10 #define AC_UserMsg 11 #define AC_DevDescrRead 12 #define AC_DevDescrResp 13 #define AC_Restart 14 #define AC_Escape 15 static const value_string ac_vals[] = { { AC_GroupValueRead, "GroupValueRead" }, { AC_GroupValueResp, "GroupValueResp" }, { AC_GroupValueWrite, "GroupValueWrite" }, { AC_IndAddrWrite, "IndAddrWrite" }, { AC_IndAddrRead, "IndAddrRead" }, { AC_IndAddrResp, "IndAddrResp" }, { AC_AdcRead, "AdcRead" }, { AC_AdcResp, "AdcResp" }, { AC_MemRead, "MemRead" }, { AC_MemResp, "MemResp" }, { AC_MemWrite, "MemWrite" }, { AC_UserMsg, "UserMsg" }, { AC_DevDescrRead, "DevDescrRead" }, { AC_DevDescrResp, "DevDescrResp" }, { AC_Restart, "Restart" }, { AC_Escape, "Escape" }, { 0, NULL } }; /* Extended AL codes */ #define AX_SysNwkParamRead 0x1C8 #define AX_SysNwkParamResp 0x1C9 #define AX_SysNwkParamWrite 0x1CA #define AX_PropExtValueRead 0x1CC #define AX_PropExtValueResp 0x1CD #define AX_PropExtValueWriteCon 0x1CE #define AX_PropExtValueWriteConRes 0x1CF #define AX_PropExtValueWriteUnCon 0x1D0 #define AX_PropExtValueInfoReport 0x1D1 #define AX_PropExtDescrRead 0x1D2 #define AX_PropExtDescrResp 0x1D3 #define AX_FuncPropExtCmd 0x1D4 #define AX_FuncPropExtRead 0x1D5 #define AX_FuncPropExtResp 0x1D6 #define AX_MemExtWrite 0x1FB #define AX_MemExtWriteResp 0x1FC #define AX_MemExtRead 0x1FD #define AX_MemExtReadResp 0x1FE #define AX_UserMemRead 0x2C0 #define AX_UserMemResp 0x2C1 #define AX_UserMemWrite 0x2C2 #define AX_UserMemBitWrite 0x2C4 #define AX_UserMfrInfoRead 0x2C5 #define AX_UserMfrInfoResp 0x2C6 #define AX_FuncPropCmd 0x2C7 #define AX_FuncPropRead 0x2C8 #define AX_FuncPropResp 0x2C9 #define AX_Restart 0x380 #define AX_RestartReq 0x381 #define AX_RestartResp 0x3A1 #define AX_RoutingTableOpen 0x3C0 #define AX_RoutingTableRead 0x3C1 #define AX_RoutingTableResp 0x3C2 #define AX_RoutingTableWrite 0x3C3 #define AX_RouterMemRead 0x3C8 #define AX_RouterMemResp 0x3C9 #define AX_RouterMemWrite 0x3CA #define AX_RouterStatusRead 0x3CD #define AX_RouterStatusResp 0x3CE #define AX_RouterStatusWrite 0x3CF #define AX_MemBitWrite 0x3D0 #define AX_AuthReq 0x3D1 #define AX_AuthResp 0x3D2 #define AX_KeyWrite 0x3D3 #define AX_KeyResp 0x3D4 #define AX_PropValueRead 0x3D5 #define AX_PropValueResp 0x3D6 #define AX_PropValueWrite 0x3D7 #define AX_PropDescrRead 0x3D8 #define AX_PropDescrResp 0x3D9 #define AX_NwkParamRead 0x3DA #define AX_NwkParamResp 0x3DB #define AX_IndAddrSerNumRead 0x3DC #define AX_IndAddrSerNumResp 0x3DD #define AX_IndAddrSerNumWrite 0x3DE #define AX_DomAddrWrite 0x3E0 #define AX_DomAddrRead 0x3E1 #define AX_DomAddrResp 0x3E2 #define AX_DomAddrSelRead 0x3E3 #define AX_NwkParamWrite 0x3E4 #define AX_LinkRead 0x3E5 #define AX_LinkResp 0x3E6 #define AX_LinkWrite 0x3E7 #define AX_GroupPropValueRead 0x3E8 #define AX_GroupPropValueResp 0x3E9 #define AX_GroupPropValueWrite 0x3EA #define AX_GroupPropValueInfo 0x3EB #define AX_DomAddrSerNumRead 0x3EC #define AX_DomAddrSerNumResp 0x3ED #define AX_DomAddrSerNumWrite 0x3EE #define AX_FileStreamInfo 0x3F0 #define AX_DataSec 0x3F1 static const value_string ax_vals[] = { { AX_SysNwkParamRead, "SysNwkParamRead" }, { AX_SysNwkParamResp, "SysNwkParamResp" }, { AX_SysNwkParamWrite, "SysNwkParamWrite" }, { AX_PropExtValueRead, "PropExtValueRead" }, { AX_PropExtValueResp, "PropExtValueResp" }, { AX_PropExtValueWriteCon, "PropExtValueWriteCon" }, { AX_PropExtValueWriteConRes, "PropExtValueWriteConRes" }, { AX_PropExtValueWriteUnCon, "PropExtValueWriteUnCon" }, { AX_PropExtDescrRead, "PropExtDescrRead" }, { AX_PropExtDescrResp, "PropExtDescrResp" }, { AX_FuncPropExtCmd, "FuncPropExtCmd" }, { AX_FuncPropExtRead, "FuncPropExtRead" }, { AX_FuncPropExtResp, "FuncPropExtResp" }, { AX_MemExtWrite, "MemExtWrite" }, { AX_MemExtWriteResp, "MemExtWriteResp" }, { AX_MemExtRead, "MemExtRead" }, { AX_MemExtReadResp, "MemExtReadResp" }, { AX_UserMemRead, "UserMemRead" }, { AX_UserMemResp, "UserMemResp" }, { AX_UserMemWrite, "UserMemWrite" }, { AX_UserMemBitWrite, "UserMemBitWrite" }, { AX_UserMfrInfoRead, "UserMfrInfoRead" }, { AX_UserMfrInfoResp, "UserMfrInfoResp" }, { AX_FuncPropCmd, "FuncPropCmd" }, { AX_FuncPropRead, "FuncPropRead" }, { AX_FuncPropResp, "FuncPropResp" }, { AX_Restart, "Restart" }, { AX_RestartReq, "RestartReq" }, { AX_RestartResp, "RestartResp" }, { AX_RoutingTableOpen, "RoutingTableOpen" }, { AX_RoutingTableRead, "RoutingTableRead" }, { AX_RoutingTableResp, "RoutingTableResp" }, { AX_RoutingTableWrite, "RoutingTableWrite" }, { AX_RouterMemRead, "RouterMemRead" }, { AX_RouterMemResp, "RouterMemResp" }, { AX_RouterMemWrite, "RouterMemWrite" }, { AX_RouterStatusRead, "RouterStatusRead" }, { AX_RouterStatusResp, "RouterStatusResp" }, { AX_RouterStatusWrite, "RouterStatusWrite" }, { AX_MemBitWrite, "MemBitWrite" }, { AX_AuthReq, "AuthReq" }, { AX_AuthResp, "AuthResp" }, { AX_KeyWrite, "KeyWrite" }, { AX_KeyResp, "KeyResp" }, { AX_PropValueRead, "PropValueRead" }, { AX_PropValueResp, "PropValueResp" }, { AX_PropValueWrite, "PropValueWrite" }, { AX_PropDescrRead, "PropDescrRead" }, { AX_PropDescrResp, "PropDescrResp" }, { AX_NwkParamRead, "NwkParamRead" }, { AX_NwkParamResp, "NwkParamResp" }, { AX_IndAddrSerNumRead, "IndAddrSerNumRead" }, { AX_IndAddrSerNumResp, "IndAddrSerNumResp" }, { AX_IndAddrSerNumWrite, "IndAddrSerNumWrite" }, { AX_DomAddrWrite, "DomAddrWrite" }, { AX_DomAddrRead, "DomAddrRead" }, { AX_DomAddrResp, "DomAddrResp" }, { AX_DomAddrSelRead, "DomAddrSelRead" }, { AX_NwkParamWrite, "NwkParamWrite" }, { AX_LinkRead, "LinkRead" }, { AX_LinkResp, "LinkResp" }, { AX_LinkWrite, "LinkWrite" }, { AX_GroupPropValueRead, "GroupPropValueRead" }, { AX_GroupPropValueResp, "GroupPropValueResp" }, { AX_GroupPropValueWrite, "GroupPropValueWrite" }, { AX_GroupPropValueInfo, "GroupPropValueInfo" }, { AX_DomAddrSerNumRead, "DomAddrSerNumRead" }, { AX_DomAddrSerNumResp, "DomAddrSerNumResp" }, { AX_DomAddrSerNumWrite, "DomAddrSerNumWrite" }, { AX_FileStreamInfo, "FileStreamInfo" }, { AX_DataSec, "DataSec" }, { 0, NULL } }; /* SCF (Security Control Field) */ static const value_string scf_vals[] = { { 0x00, "CCM S-A_Data with Authentication-only" }, { 0x10, "CCM S-A_Data with Authentication+Confidentiality" }, { 0x12, "CCM S-A_Sync_Req with Authentication+Confidentiality" }, { 0x13, "CCM S-A_Sync_Res with Authentication+Confidentiality" }, { 0x08, "CCM S-A_Data with Authentication-only, System Broadcast" }, { 0x18, "CCM S-A_Data with Authentication+Confidentiality, System Broadcast" }, { 0x1a, "CCM S-A_Sync_Req with Authentication+Confidentiality, System Broadcast" }, { 0x1b, "CCM S-A_Sync_Res with Authentication+Confidentiality, System Broadcast" }, { 0x80, "CCM S-A_Data with Authentication-only, Tool Access" }, { 0x90, "CCM S-A_Data with Authentication+Confidentiality, Tool Access" }, { 0x92, "CCM S-A_Sync_Req with Authentication+Confidentiality, Tool Access" }, { 0x93, "CCM S-A_Sync_Res with Authentication+Confidentiality, Tool Access" }, { 0x88, "CCM S-A_Data with Authentication-only, System Broadcast, Tool Access" }, { 0x98, "CCM S-A_Data with Authentication+Confidentiality, Tool Access, System Broadcast" }, { 0x9a, "CCM S-A_Sync_Req with Authentication+Confidentiality, Tool Access, System Broadcast" }, { 0x9b, "CCM S-A_Sync_Res with Authentication+Confidentiality, Tool Access, System Broadcast" }, { 0, NULL } }; /* SCF (Security Control Field). */ static const value_string scf_short_vals[] = { { 0x00, "Data+A" }, { 0x10, "Data+A+C" }, { 0x12, "SyncReq" }, { 0x13, "SyncRes" }, { 0x08, "Data+A+SBC" }, { 0x18, "Data+A+C+SBC" }, { 0x1a, "SyncReq+SBC" }, { 0x1b, "SyncRes+SBC" }, { 0x80, "Data+A+T" }, { 0x90, "Data+A+C+T" }, { 0x92, "SyncReq+T" }, { 0x93, "SyncRes+T" }, { 0x88, "Data+A+T+SBC" }, { 0x98, "Data+A+C+T+SBC" }, { 0x9a, "SyncReq+T+SBC" }, { 0x9b, "SyncRes+T+SBC" }, { 0, NULL } }; /* SCF.SAI (Security Algorithm Identifier) */ static const value_string scf_sai_vals[] = { { 0, "CCM A" }, { 1, "CCM A+S" }, { 0, NULL } }; /* SCF.Service */ static const value_string scf_svc_vals[] = { { 0, "Data" }, { 2, "Sync_Req" }, { 3, "Sync_Res" }, { 0, NULL } }; /* See KNX documents: * "03_07_03 Standardized Identifier Tables v01.03.01 AS" * "03_05_01 Resources v01.09.03 AS" */ /* Property Data Types * See "4 Property Datatypes Identifiers" in "03_07_03 Standardized Identifier Tables v01.03.01 AS" */ static const value_string pdt_vals[] = { { 0x00, "PDT_CONTROL" }, { 0x01, "PDT_CHAR" }, { 0x02, "PDT_UNSIGNED_CHAR" }, { 0x03, "PDT_INT" }, { 0x04, "PDT_UNSIGNED_INT" }, { 0x05, "PDT_KNX_FLOAT" }, { 0x06, "PDT_DATE" }, { 0x07, "PDT_TIME" }, { 0x08, "PDT_LONG" }, { 0x09, "PDT_UNSIGNED_LONG" }, { 0x0A, "PDT_FLOAT" }, { 0x0B, "PDT_DOUBLE" }, { 0x0C, "PDT_CHAR_BLOCK" }, { 0x0D, "PDT_POLL_GROUP_SETTINGS" }, { 0x0E, "PDT_SHORT_CHAR_BLOCK" }, { 0x0F, "PDT_DATE_TIME" }, { 0x10, "PDT_VARIABLE_LENGTH" }, { 0x11, "PDT_GENERIC_01" }, { 0x12, "PDT_GENERIC_02" }, { 0x13, "PDT_GENERIC_03" }, { 0x14, "PDT_GENERIC_04" }, { 0x15, "PDT_GENERIC_05" }, { 0x16, "PDT_GENERIC_06" }, { 0x17, "PDT_GENERIC_07" }, { 0x18, "PDT_GENERIC_08" }, { 0x19, "PDT_GENERIC_09" }, { 0x1A, "PDT_GENERIC_10" }, { 0x1B, "PDT_GENERIC_11" }, { 0x1C, "PDT_GENERIC_12" }, { 0x1D, "PDT_GENERIC_13" }, { 0x1E, "PDT_GENERIC_14" }, { 0x1F, "PDT_GENERIC_15" }, { 0x20, "PDT_GENERIC_16" }, { 0x21, "PDT_GENERIC_17" }, { 0x22, "PDT_GENERIC_18" }, { 0x23, "PDT_GENERIC_19" }, { 0x24, "PDT_GENERIC_20" }, { 0x2F, "PDT_UTF-8" }, { 0x30, "PDT_VERSION" }, { 0x31, "PDT_ALARM_INFO" }, { 0x32, "PDT_BINARY_INFORMATION" }, { 0x33, "PDT_BITSET8" }, { 0x34, "PDT_BITSET16" }, { 0x35, "PDT_ENUM8" }, { 0x36, "PDT_SCALING" }, { 0x3C, "PDT_NE_VL" }, { 0x3D, "PDT_NE_FL" }, { 0x3E, "PDT_FUNCTION" }, { 0x3F, "PDT_ESCAPE" }, { 0, NULL } }; /* Interface Object Types * See "2 Interface Object Types" in "03_07_03 Standardized Identifier Tables v01.03.01 AS" */ static const value_string ot_vals[] = { { 0, "Device" }, { 1, "Address Table" }, { 2, "Association Table" }, { 3, "Application Program" }, { 4, "Interface Program" }, { 5, "KNX-Object Association Table" }, { 6, "Router" }, { 7, "LTE Address Routing Table" }, { 8, "cEMI Server" }, { 9, "Group Object Table" }, { 10, "Polling Master" }, { 11, "KNXnet/IP Parameter" }, { 13, "File Server" }, { 17, "Data Security" }, { 0, NULL } }; /* IOT independent PIDs * See "3.2 Interface Object Type independent standard Properties" in "03_07_03 Standardized Identifier Tables v01.03.01 AS" * See "4.2 Interface Object Type independent Properties" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid_vals[] = { { 1, "PID_OBJECT_TYPE" }, { 2, "PID_OBJECT_NAME" }, { 3, "PID_SEMAPHOR" }, { 4, "PID_GROUP_OBJECT_REFERENCE" }, { 5, "PID_LOAD_STATE_CONTROL" }, { 6, "PID_RUN_STATE_CONTROL" }, { 7, "PID_TABLE_REFERENCE" }, { 8, "PID_SERVICE_CONTROL" }, { 9, "PID_FIRMWARE_REVISION" }, { 10, "PID_SERVICES_SUPPORTED" }, { 11, "PID_SERIAL_NUMBER" }, { 12, "PID_MANUFACTURER_ID" }, { 13, "PID_PROGRAM_VERSION" }, { 14, "PID_DEVICE_CONTROL" }, { 15, "PID_ORDER_INFO" }, { 16, "PID_PEI_TYPE" }, { 17, "PID_PORT_CONFIGURATION" }, { 18, "PID_POLL_GROUP_SETTINGS" }, { 19, "PID_MANUFACTURER_DATA" }, { 21, "PID_DESCRIPTION" }, { 23, "PID_TABLE" }, { 24, "PID_ENROL" }, { 25, "PID_VERSION" }, { 26, "PID_GROUP_OBJECT_LINK" }, { 27, "PID_MCB_TABLE" }, { 28, "PID_ERROR_CODE" }, { 29, "PID_OBJECT_INDEX" }, { 30, "PID_DOWNLOAD_COUNTER" }, { 0, NULL } }; /* PIDs for IOT = 0 (Device) * See "3.3.1 Device Object Interface Object (Object Type = 0)" in "03_07_03 Standardized Identifier Tables v01.03.01 AS" * See "4.3 Device Object (Object Type 0)" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid0_vals[] = { { 51, "PID_ROUTING_COUNT" }, { 52, "PID_MAX_RETRY_COUNT" }, { 53, "PID_ERROR_FLAGS" }, { 54, "PID_PROGMODE" }, { 55, "PID_PRODUCT_ID" }, { 56, "PID_MAX_APDULENGTH" }, { 57, "PID_SUBNET_ADDR" }, { 58, "PID_DEVICE_ADDR" }, { 59, "PID_PB_CONFIG" }, { 60, "PID_ADDR_REPORT" }, { 61, "PID_ADDR_CHECK" }, { 62, "PID_OBJECT_VALUE" }, { 63, "PID_OBJECTLINK" }, { 64, "PID_APPLICATION" }, { 65, "PID_PARAMETER" }, { 66, "PID_OBJECTADDRESS" }, { 67, "PID_PSU_TYPE" }, { 68, "PID_PSU_STATUS" }, { 69, "PID_PSU_ENABLE" }, { 70, "PID_DOMAIN_ADDRESS" }, { 71, "PID_IO_LIST" }, { 72, "PID_MGT_DESCRIPTOR_01" }, { 73, "PID_PL110_PARAM" }, { 74, "PID_RF_REPEAT_COUNTER" }, { 75, "PID_RECEIVE_BLOCK_TABLE" }, { 76, "PID_RANDOM_PAUSE_TABLE" }, { 77, "PID_RECEIVE_BLOCK_NR" }, { 78, "PID_HARDWARE_TYPE" }, { 79, "PID_RETRANSMITTER_NUMBER" }, { 80, "PID_SERIAL_NR_TABLE" }, { 81, "PID_BIBATMASTER_ADDRESS" }, { 82, "PID_RF_DOMAIN_ADDRESS" }, { 83, "PID_DEVICE_DESCRIPTOR" }, { 84, "PID_METERING_FILTER_TABLE" }, { 85, "PID_GROUP_TELEGR_RATE_LIMIT_TIME_BASE" }, { 86, "PID_GROUP_TELEGR_RATE_LIMIT_NO_OF_TELEGR" }, { 0, NULL } }; /* PIDs for IOT = 1 (Address Table) * See "4.10.6 Group Address Table - Realisation Type 6" in "03_05_01 Resources v01.09.03 AS" * See "4.10.7 Group Address Table - Realisation Type 7" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid1_vals[] = { { 51, "PID_EXT_FRAMEFORMAT" }, { 52, "PID_ADDRTAB1" }, { 53, "PID_GROUP_RESPONSER_TABLE" }, { 0, NULL } }; /* PIDs for IOT = 6 (Router) * See "4.4 Router Object (Object Type 6)" in "03_05_01 Resources v01.09.03 AS" * See "2.4.4 Router Object" in "AN161 v05 Coupler Model 2.0 AS" */ static const value_string pid6_vals[] = { { 51, "PID_MEDIUM_STATUS" }, /* alias "PID_LINE_STATUS" */ { 52, "PID_MAIN_LCCONFIG" }, { 53, "PID_SUB_LCCONFIG" }, { 54, "PID_MAIN_LCGRPCONFIG" }, { 55, "PID_SUB_LCGRPCONFIG" }, { 56, "PID_ROUTETABLE_CONTROL" }, { 57, "PID_COUPL_SERV_CONTROL" }, { 58, "PID_MAX_APDU_LENGTH" }, { 59, "PID_L2_COUPLER_TYPE" }, { 61, "PID_HOP_COUNT" }, { 63, "PID_MEDIUM" }, { 67, "PID_FILTER_TABLE_USE" }, { 104, "PID_PL110_SBC_CONTROL" }, { 105, "PID_PL110_DOA" }, { 112, "PID_RF_SBC_CONTROL" }, { 0, NULL } }; /* PIDs for IOT = 7 (LTE Address Routing Table) * See "4.5 LTE Address Routing Table Object (Object Type 7)" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid7_vals[] = { { 51, "PID_LTE_ROUTESELECT" }, { 52, "PID_LTE_ROUTETABLE" }, { 0, NULL } }; /* PIDs for IOT = 8 (cEMI Server) * See "4.6 cEMI Server Object (Object Type 8)" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid8_vals[] = { { 51, "PID_MEDIUM_TYPE" }, { 52, "PID_COMM_MODE" }, { 53, "PID_MEDIUM_AVAILABILITY" }, { 54, "PID_ADD_INFO_TYPES" }, { 55, "PID_TIME_BASE" }, { 56, "PID_TRANSP_ENABLE" }, { 59, "PID_BIBAT_NEXTBLOCK" }, { 60, "PID_RF_MODE_SELECT" }, { 61, "PID_RF_MODE_SUPPORT" }, { 62, "PID_RF_FILTERING_MODE_SELECT" }, { 63, "PID_RF_FILTERING_MODE_SUPPORT" }, { 0, NULL } }; /* PIDs for IOT = 9 (Group Object Table) * See "4.12.4 Group Object Table - Realisation Type 6" in "03_05_01 Resources v01.09.03 AS" */ static const value_string pid9_vals[] = { { 51, "PID_GRPOBJTABLE" }, { 52, "PID_EXT_GRPOBJREFERENCE" }, { 0, NULL } }; /* PIDs for IOT = 11 (KNXnet/IP Parameter), * See "2.5 KNXnet/IP Parameter Object" in "03_08_03 Management v01.06.02 AS" * See "2.3.1 KNXnet/IP Parameter Object" in "AN159 v06 KNXnet-IP Secure AS" */ static const value_string pid11_vals[] = { { 51, "PID_PROJECT_INSTALLATION_ID" }, { 52, "PID_KNX_INDIVIDUAL_ADDRESS" }, { 53, "PID_ADDITIONAL_INDIVIDUAL_ADDRESSES" }, { 54, "PID_CURRENT_IP_ASSIGNMENT_METHOD" }, { 55, "PID_IP_ASSIGNMENT_METHOD" }, { 56, "PID_IP_CAPABILITIES" }, { 57, "PID_CURRENT_IP_ADDRESS" }, { 58, "PID_CURRENT_SUBNET_MASK" }, { 59, "PID_CURRENT_DEFAULT_GATEWAY" }, { 60, "PID_IP_ADDRESS" }, { 61, "PID_SUBNET_MASK" }, { 62, "PID_DEFAULT_GATEWAY" }, { 63, "PID_DHCP_BOOTP_SERVER" }, { 64, "PID_MAC_ADDRESS" }, { 65, "PID_SYSTEM_SETUP_MULTICAST_ADDRESS" }, { 66, "PID_ROUTING_MULTICAST_ADDRESS" }, { 67, "PID_TTL" }, { 68, "PID_KNXNETIP_DEVICE_CAPABILITIES" }, { 69, "PID_KNXNETIP_DEVICE_STATE" }, { 70, "PID_KNXNETIP_ROUTING_CAPABILITIES" }, { 71, "PID_PRIORITY_FIFO_ENABLED" }, { 72, "PID_QUEUE_OVERFLOW_TO_IP" }, { 73, "PID_QUEUE_OVERFLOW_TO_KNX" }, { 74, "PID_MSG_TRANSMIT_TO_IP" }, { 75, "PID_MSG_TRANSMIT_TO_KNX" }, { 76, "PID_FRIENDLY_NAME" }, { 78, "PID_ROUTING_BUSY_WAIT_TIME" }, { 91, "PID_BACKBONE_KEY" }, { 92, "PID_DEVICE_AUTHENTICATION_CODE" }, { 93, "PID_PASSWORD_HASHES" }, { 94, "PID_SECURED_SERVICE_FAMILIES" }, { 95, "PID_MULTICAST_LATENCY_TOLERANCE" }, { 96, "PID_SYNC_LATENCY_FRACTION" }, { 97, "PID_TUNNELLING_USERS" }, { 0, NULL } }; /* PIDs for IOT = 17 (Security) * See "2.3.5 Security Interface Object" in "KSG638-26.03 KNX Data Security" */ static const value_string pid17_vals[] = { { 51, "PID_SECURITY_MODE" }, { 52, "PID_P2P_KEY_TABLE" }, { 53, "PID_GRP_KEY_TABLE" }, { 54, "PID_SECURITY_INDIVIDUAL_ADDRESS_TABLE" }, { 55, "PID_SECURITY_FAILURES_LOG" }, { 56, "PID_TOOL_KEY" }, { 57, "PID_SECURITY_REPORT" }, { 58, "PID_SECURITY_REPORT_CONTROL" }, { 59, "PID_SEQUENCE_NUMBER_SENDING" }, { 60, "PID_ZONE_KEY_TABLE" }, { 61, "PID_GO_SECURITY_FLAGS" }, { 62, "PID_ROLE_TABLE" }, { 0, NULL } }; /* - - - - - - - - - H E L P E R F U N C T I O N S - - - - - - - - - - */ /* Add raw data to list view, tree view, and parent folder */ static proto_item* proto_tree_add_data( proto_tree* tree, tvbuff_t* tvb, gint offset, gint length, column_info* cinfo, proto_item* item, const gchar* name, const gchar* text1, const gchar* text2 ) { proto_item* new_item = proto_tree_add_bytes_format( tree, hf_bytes, tvb, offset, length, NULL, "%s: $", name ); if( text1 ) col_append_str( cinfo, COL_INFO, text1 ); if( text2 ) proto_item_append_text( item, "%s", text2 ); while( length > 0 ) { guint8 value = tvb_get_guint8( tvb, offset ); if( text1 ) col_append_fstr( cinfo, COL_INFO, "%02X", value ); if( text2 ) proto_item_append_text( item, "%02X", value ); proto_item_append_text( new_item, " %02X", value ); offset++; length--; } return new_item; } static const gchar* get_pid_name( gint ot, gint pid ) { if( pid <= 50 ) { return try_val_to_str( pid, pid_vals ); } { const value_string* vals = NULL; switch( ot ) { case 0: vals = pid0_vals; break; case 1: vals = pid1_vals; break; case 6: vals = pid6_vals; break; case 7: vals = pid7_vals; break; case 8: vals = pid8_vals; break; case 9: vals = pid9_vals; break; case 11: vals = pid11_vals; break; case 17: vals = pid17_vals; break; } if( vals ) { return try_val_to_str( pid, vals ); } } return NULL; } /* Decrypt data security APDU with a specific key. */ static const guint8* decrypt_data_security_data_with_key( wmem_allocator_t *pool, const guint8* key, const guint8* encrypted, gint encrypted_size, const guint8* cemi, gint cemi_size ) { guint8 ctr_0[ KNX_KEY_LENGTH ]; guint8 b_0[ KNX_KEY_LENGTH ]; guint8 mac[ KNX_KEY_LENGTH ]; guint8* a_bytes = 0; const guint8* p_bytes = NULL; gint a_length = 0; gint p_length = 0; guint8* decrypted = NULL; if( encrypted_size > 4 ) // contains 4 bytes MAC { if( cemi_size >= 2 ) { gint additionalInfoLength = cemi[ 1 ]; gint offsetToData = additionalInfoLength + 11; if( offsetToData + 6 <= cemi_size ) { /* 1 byte Security Control Field */ guint8 scf = cemi[ offsetToData ]; // Get A and P. if( (scf & 0x30) == 0x10 ) // A+C { p_bytes = encrypted; p_length = encrypted_size - 4; } // Build b_0. b_0[ 0 ] = cemi[ offsetToData + 1 ]; // SeqNr b_0[ 1 ] = cemi[ offsetToData + 2 ]; b_0[ 2 ] = cemi[ offsetToData + 3 ]; b_0[ 3 ] = cemi[ offsetToData + 4 ]; b_0[ 4 ] = cemi[ offsetToData + 5 ]; b_0[ 5 ] = cemi[ offsetToData + 6 ]; b_0[ 6 ] = cemi[ additionalInfoLength + 4 ]; // SA b_0[ 7 ] = cemi[ additionalInfoLength + 5 ]; b_0[ 8 ] = cemi[ additionalInfoLength + 6 ]; // DA b_0[ 9 ] = cemi[ additionalInfoLength + 7 ]; b_0[ 10 ] = 0; // cemi[additionalInfoLength + 2] & 0x80; // FT b_0[ 11 ] = cemi[ additionalInfoLength + 3 ] & 0x8F; // AT (AT+EFF) b_0[ 12 ] = cemi[ additionalInfoLength + 9 ]; // TPCI + ApciSec b_0[ 13 ] = cemi[ additionalInfoLength + 10 ]; b_0[ 14 ] = 0; b_0[ 15 ] = (guint8) p_length; // Build ctr_0. ctr_0[ 0 ] = cemi[ offsetToData + 1 ]; // SeqNr ctr_0[ 1 ] = cemi[ offsetToData + 2 ]; ctr_0[ 2 ] = cemi[ offsetToData + 3 ]; ctr_0[ 3 ] = cemi[ offsetToData + 4 ]; ctr_0[ 4 ] = cemi[ offsetToData + 5 ]; ctr_0[ 5 ] = cemi[ offsetToData + 6 ]; ctr_0[ 6 ] = cemi[ additionalInfoLength + 4 ]; // SA ctr_0[ 7 ] = cemi[ additionalInfoLength + 5 ]; ctr_0[ 8 ] = cemi[ additionalInfoLength + 6 ]; // DA ctr_0[ 9 ] = cemi[ additionalInfoLength + 7 ]; ctr_0[ 10 ] = 0; ctr_0[ 11 ] = 0; ctr_0[ 12 ] = 0; ctr_0[ 13 ] = 0; ctr_0[ 14 ] = 0x01; ctr_0[ 15 ] = 0; decrypted = knx_ccm_encrypt( 0, key, p_bytes, p_length, encrypted + encrypted_size - 4, 4, ctr_0, 4 ); a_bytes = (guint8*) wmem_alloc( pool, encrypted_size ); if( (scf & 0x30) == 0x10 ) // A+C { a_bytes[ 0 ] = scf; a_length = 1; p_bytes = decrypted; p_length = encrypted_size - 4; } else if( (scf & 0x30) == 0x00 ) // A { a_bytes[ 0 ] = scf; memcpy( a_bytes + 1, decrypted, encrypted_size - 4 ); a_length = encrypted_size - 3; } knx_ccm_calc_cbc_mac( mac, key, a_bytes, a_length, p_bytes, p_length, b_0 ); wmem_free( pool, a_bytes ); if( memcmp( mac, decrypted + p_length, 4 ) != 0 ) { // Wrong mac. Return 0. wmem_free( pool, decrypted ); decrypted = NULL; } } } } return decrypted; } /* Context info for decrypt_data_security_data */ struct data_security_info { guint16 source; // KNX source address guint16 dest; // KNX source address guint8 multicast; // KNX multicast (group addressed)? guint64 seq_nr; // 6-byte data security sequence number gchar output_text[ 128 ]; // buffer for diagnostic output text }; /* Decrypt data security APDU. */ static const guint8* decrypt_data_security_data( wmem_allocator_t *pool, const guint8* encrypted, gint encrypted_size, const guint8* cemi, gint cemi_size, struct data_security_info* info ) { const guint8* key = NULL; const guint8* decrypted = NULL; guint8 keys_found = 0; // Get context info guint16 source = info->source; guint16 dest = info->dest; guint8 multicast = info->multicast; gchar* output = info->output_text; gint output_max = sizeof info->output_text; snprintf( output, output_max, "with " ); while( *output ) { ++output; --output_max; } // Try keys from keyring.XML if( multicast ) { // Try keys associated with GA struct knx_keyring_ga_keys* ga_key; for( ga_key = knx_keyring_ga_keys; ga_key; ga_key = ga_key->next ) { if( ga_key->ga == dest ) { keys_found = 1; key = ga_key->key; decrypted = decrypt_data_security_data_with_key( pool, key, encrypted, encrypted_size, cemi, cemi_size ); if( decrypted ) { snprintf( output, output_max, "GA " ); while( *output ) { ++output; --output_max; } break; } } } } else { // Try keys associated with dest IA struct knx_keyring_ia_keys* ia_key; for( ia_key = knx_keyring_ia_keys; ia_key; ia_key = ia_key->next ) { if( ia_key->ia == dest ) { keys_found = 1; key = ia_key->key; decrypted = decrypt_data_security_data_with_key( pool, key, encrypted, encrypted_size, cemi, cemi_size ); if( decrypted ) { snprintf( output, output_max, "dest IA " ); while( *output ) { ++output; --output_max; } break; } } } } if( !decrypted ) { // Try keys associated with source IA struct knx_keyring_ia_keys* ia_key; for( ia_key = knx_keyring_ia_keys; ia_key; ia_key = ia_key->next ) { if( ia_key->ia == source ) { keys_found = 1; key = ia_key->key; decrypted = decrypt_data_security_data_with_key( pool, key, encrypted, encrypted_size, cemi, cemi_size ); if( decrypted ) { snprintf( output, output_max, "source IA " ); while( *output ) { ++output; --output_max; } break; } } } } if( !decrypted && knx_decryption_key_count ) { // Try all explicitly specified keys guint8 key_index; for( key_index = 0; key_index < knx_decryption_key_count; ++key_index ) { keys_found = 1; key = knx_decryption_keys[ key_index ]; decrypted = decrypt_data_security_data_with_key( pool, key, encrypted, encrypted_size, cemi, cemi_size ); if( decrypted ) { break; } } } if( decrypted ) { guint8 count; snprintf( output, output_max, "key" ); for( count = 16; count; --count ) { while( *output ) { ++output; --output_max; } snprintf( output, output_max, " %02X", *key++ ); } } else { snprintf( info->output_text, sizeof info->output_text, keys_found ? "failed" : "no keys found" ); } return decrypted; } /* Dissect Object Index (1 byte) */ static guint8 dissect_ox( tvbuff_t *tvb, packet_info *pinfo, proto_item *node, proto_tree *list, gint *p_offset, gint end_pos, guint8 *p_error ) { gint offset = *p_offset; if( offset < end_pos ) { guint8 ox = tvb_get_guint8( tvb, offset ); column_info *cinfo = pinfo->cinfo; col_append_fstr( cinfo, COL_INFO, " OX=%u", ox ); proto_item_append_text( node, ", OX=%u", ox ); proto_tree_add_item( list, hf_cemi_ox, tvb, offset, 1, ENC_BIG_ENDIAN ); *p_offset = ++offset; return ox; } proto_tree_add_expert_format( list, pinfo, KIP_ERROR, tvb, offset, 0, "? Object Index: expected 1 byte" ); if( p_error ) { *p_error = 1; } return 0; } /* Dissect Object Type (2 bytes) */ static guint16 dissect_ot( tvbuff_t *tvb, packet_info *pinfo, proto_item *node, proto_tree *list, gint *p_offset, gint end_pos, guint8 *p_error ) { gint offset = *p_offset; if( offset + 1 < end_pos ) { guint16 ot = tvb_get_ntohs( tvb, offset ); column_info *cinfo = pinfo->cinfo; col_append_fstr( cinfo, COL_INFO, " OT=%u", ot ); proto_item_append_text( node, ", OT=%u", ot ); proto_tree_add_item( list, hf_cemi_ot, tvb, offset, 2, ENC_BIG_ENDIAN ); offset += 2; *p_offset = offset; return ot; } node = proto_tree_add_bytes_format( list, hf_bytes, tvb, offset, end_pos - offset, NULL, "? Object Type" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); if( p_error ) { *p_error = 1; } *p_offset = end_pos; return 0; } /* Dissect Property Identifier (1 byte) */ static guint8 dissect_pid( tvbuff_t *tvb, packet_info *pinfo, proto_item *node, proto_tree *list, gint *p_offset, gint end_pos, gint ot, guint8 show, guint8 *p_error ) { gint offset = *p_offset; if( offset < end_pos ) { guint8 pid = tvb_get_guint8( tvb, offset ); column_info *cinfo = pinfo->cinfo; const gchar* name; if( pid || show ) { col_append_fstr( cinfo, COL_INFO, " P=%u", pid ); proto_item_append_text( node, ", PID=%u", pid ); } if( list ) { node = proto_tree_add_item( list, hf_cemi_pid, tvb, offset, 1, ENC_BIG_ENDIAN ); name = get_pid_name( ot, pid ); if( name ) { proto_item_append_text( node, " = %s", name ); } } *p_offset = ++offset; return pid; } proto_tree_add_expert_format( list, pinfo, KIP_ERROR, tvb, offset, 0, "? Property ID: expected 1 byte" ); if( p_error ) { *p_error = 1; } return 0; } /* Dissect Property Index (1 byte) */ static guint8 dissect_px( tvbuff_t *tvb, packet_info *pinfo, proto_item *node, proto_tree *list, gint *p_offset, gint end_pos, guint8 show, guint8 *p_error ) { gint offset = *p_offset; if( offset < end_pos ) { guint8 px = tvb_get_guint8( tvb, offset ); if( show ) { column_info *cinfo = pinfo->cinfo; col_append_fstr( cinfo, COL_INFO, " PX=%u", px ); proto_item_append_text( node, ", PX=%u", px ); } proto_tree_add_item( list, hf_cemi_px, tvb, offset, 1, ENC_BIG_ENDIAN ); *p_offset = ++offset; return px; } proto_tree_add_expert_format( list, pinfo, KIP_ERROR, tvb, offset, 0, "? Property Index: expected 1 byte" ); if( p_error ) { *p_error = 1; } return 0; } /* Dissect Property Range (2 bytes: Number Of Elements (4 bits), Start Index (12 bits)) and subsequent Data */ static void dissect_range( tvbuff_t *tvb, packet_info *pinfo, proto_item *node, proto_tree *list, gint *p_offset, gint end_pos, guint8 pa_flags, guint8 *p_error ) { gint offset = *p_offset; guint8 error = 0; if( offset + 1 >= end_pos ) { node = proto_tree_add_bytes_format( list, hf_bytes, tvb, offset, end_pos - offset, NULL, "? Range" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); *p_offset = end_pos; error = 1; } else { column_info *cinfo = pinfo->cinfo; proto_item *cemi_node = node; guint16 sx = tvb_get_ntohs( tvb, offset ); guint8 ne = sx >> 12; sx &= 0x0FFF; /* 4 bits Number Of Elements */ if( ne != 1 ) { col_append_fstr( cinfo, COL_INFO, " N=%u", ne ); proto_item_append_text( node, ", N=%u", ne ); if( ne == 0 && !(pa_flags & PA_RESPONSE) ) { error = 1; } else if( sx == 0 ) { error = 2; } } /* 12 bits Start Index */ if( sx != 1 ) { col_append_fstr( cinfo, COL_INFO, " X=%u", sx ); proto_item_append_text( node, ", X=%u", sx ); } if( list ) { proto_item *range_node = proto_tree_add_none_format( list, hf_folder, tvb, offset, 2, "Range: %u element%s at position %u", ne, (ne == 1) ? "" : "s", sx ); proto_tree *range_list = proto_item_add_subtree( range_node, ett_cemi_range ); /* 4 bits Number Of Elements */ node = proto_tree_add_item( range_list, hf_cemi_ne, tvb, offset, 1, ENC_BIG_ENDIAN ); if( error ) { proto_item_prepend_text( range_node, "? " ); proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, (error == 1) ? "Expected: >= 1 element(s)" : "Expected: 1 element" ); } /* 12 bits Start Index */ proto_tree_add_item( range_list, hf_cemi_sx, tvb, offset, 2, ENC_BIG_ENDIAN ); } offset += 2; /* Data */ { gint length = end_pos - offset; if( length > 0 ) { node = proto_tree_add_data( list, tvb, offset, length, cinfo, cemi_node, "Data", " $", ", $" ); if( !pa_flags ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Unexpected" ); error = 1; } else if( (pa_flags & PA_RESPONSE) && (!(pa_flags & PA_DATA) || ne == 0) && length != 1 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: max 1 byte" ); error = 1; } else if( pa_flags & PA_DATA ) { if( ne == 1 && sx == 0 && length != 2 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; } else if( ne >= 2 && (length % ne) != 0 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: multiple of %u bytes", ne ); error = 1; } } } } *p_offset = end_pos; } if( error && p_error ) { *p_error = 1; } } /* Dissect Property Description: PDT (1 byte), Max Count (2 bytes), Access Levels (1 byte) */ static void dissect_prop_descr( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_error ) { gint offset = *p_offset; column_info* cinfo = pinfo->cinfo; guint8 error = 0; /* 4 bytes Property Description */ if( offset + 4 > size ) { proto_item* node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Property Description" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 4 bytes" ); error = 1; offset = size; } else { /* 1 bit Writability, 1 bit reserved, 6 bits Property Data Type */ guint8 pdt = tvb_get_guint8( tvb, offset ); guint8 writable = (pdt & 0x80) != 0; pdt &= 0x3F; col_append_fstr( cinfo, COL_INFO, " T=%u", pdt ); proto_item_append_text( cemi_node, ", T=%u", pdt ); /* 4 bits reserved, 12 bits Max Elements */ guint16 me = tvb_get_ntohs( tvb, offset + 1) & 0x0FFF; if( me != 1 ) { col_append_fstr( cinfo, COL_INFO, " N=%u", me ); proto_item_append_text( cemi_node, ", N=%u", me ); } /* 4 bits Read Access, 4 bits Write Access */ guint8 wa = tvb_get_guint8( tvb, offset + 3 ); guint8 ra = (wa & 0xF0) >> 4; wa &= 0x0F; col_append_fstr( cinfo, COL_INFO, " R=%u", ra ); if( writable ) col_append_fstr( cinfo, COL_INFO, " W=%u", wa ); proto_item_append_text( cemi_node, ", R=%u", ra ); if( writable ) proto_item_append_text( cemi_node, ", W=%u", wa ); if( cemi_list ) { proto_item *pd_node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 4, "Property Description: " ); proto_tree *pd_list = proto_item_add_subtree( pd_node, ett_cemi_pd ); const gchar* pdt_name = try_val_to_str( pdt, pdt_vals ); if( pdt_name ) proto_item_append_text( pd_node, "%s", pdt_name ); else proto_item_append_text( pd_node, "PDT = 0x%02X", pdt ); if( me != 1 ) proto_item_append_text( pd_node, ", Max Elements = %u", me ); proto_item_append_text( pd_node, ", Read = %u", ra ); if( writable ) proto_item_append_text( pd_node, ", Write = %u", wa ); proto_tree_add_item( pd_list, hf_cemi_pw, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( pd_list, hf_cemi_pdt, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( pd_list, hf_cemi_me, tvb, offset + 1, 2, ENC_BIG_ENDIAN ); proto_tree_add_item( pd_list, hf_cemi_ra, tvb, offset + 3, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( pd_list, hf_cemi_wa, tvb, offset + 3, 1, ENC_BIG_ENDIAN ); } offset += 4; } if( error && p_error ) { *p_error = 1; } *p_offset = offset; } /* Dissect OT (2 bytes), OI (12 bits), and PID (12 bits) for PropertyExt services */ static void dissect_pid_ext( tvbuff_t *tvb, packet_info *pinfo, proto_item *cemi_node, proto_tree *cemi_list, gint *p_offset, gint size, guint8 *p_error ) { gint offset = *p_offset; column_info* cinfo = pinfo->cinfo; guint8 error = 0; /* 2 bytes Object Type */ guint16 ot = dissect_ot( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); if( offset + 3 > size ) { proto_item* node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Object Instance, PID" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 3 bytes" ); error = 1; offset = size; } else { /* 12 bits Object Instance */ guint16 cc = tvb_get_ntohs( tvb, offset ) >> 4; col_append_fstr( cinfo, COL_INFO, " OI=%u", cc ); proto_item_append_text( cemi_node, ", OI=%u", cc ); proto_tree_add_item( cemi_list, hf_cemi_ext_oi, tvb, offset, 2, ENC_BIG_ENDIAN ); ++offset; /* 12 bits Property ID */ cc = tvb_get_ntohs( tvb, offset ) & 0x0FFF; col_append_fstr( cinfo, COL_INFO, " P=%u", cc ); proto_item_append_text( cemi_node, ", PID=%u", cc ); if( cemi_list ) { proto_item* node = proto_tree_add_item( cemi_list, hf_cemi_ext_pid, tvb, offset, 2, ENC_BIG_ENDIAN ); const gchar* name = get_pid_name( ot, cc ); if( name ) { proto_item_append_text( node, " = %s", name ); } } offset += 2; } if( error && p_error ) { *p_error = 1; } *p_offset = offset; } /* Dissect cEMI Management packet (M_PropRead.req, M_PropRead.con, M_PropWrite.req, M_PropWrite.con, M_PropInfo.ind, M_Reset.req, M_Reset.ind) */ static void dissect_cemi_mgmt_packet( tvbuff_t* tvb, packet_info* pinfo, proto_item *cemi_node, proto_tree *cemi_list, guint8 mc, gint *p_offset, gint size, guint8* p_pa_flags, guint8 *p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; guint8 min_size = 1; switch( mc ) { case CEMI_M_PROPREAD_REQ: pa_flags = 0; goto case_CEMI_M_PROP; case CEMI_M_PROPWRITE_CON: pa_flags = PA_RESPONSE; goto case_CEMI_M_PROP; case CEMI_M_PROPREAD_CON: pa_flags = PA_RESPONSE | PA_DATA; goto case_CEMI_M_PROP; case CEMI_M_PROPWRITE_REQ: case CEMI_M_PROPINFO_IND: //pa_flags = PA_DATA; case_CEMI_M_PROP: min_size = 7; break; case CEMI_M_FUNCPROPCMD_REQ: case CEMI_M_FUNCPROPREAD_REQ: case CEMI_M_FUNCPROP_CON: //pa_flags = PA_DATA; min_size = 5; break; case CEMI_M_RESET_REQ: case CEMI_M_RESET_IND: pa_flags = 0; break; } if( min_size >= 5 ) { /* 2 bytes Object Type */ guint16 ot = dissect_ot( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); /* 1 byte Object Instance */ if( size < 4 ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Object Instance: expected 1 byte" ); error = 1; } else { guint8 oi = tvb_get_guint8( tvb, 3 ); if( oi != 1 ) { col_append_fstr( cinfo, COL_INFO, " OI=%u", oi ); proto_item_append_text( cemi_node, ", OI=%u", oi ); } proto_tree_add_item( cemi_list, hf_cemi_oi, tvb, 3, 1, ENC_BIG_ENDIAN ); offset = 4; } /* 1 byte Property ID */ dissect_pid( tvb, pinfo, cemi_node, cemi_list, &offset, size, ot, 1, &error ); if( min_size >= 7 ) { /* Range (Start Index, Number Of Elements) and Data */ dissect_range( tvb, pinfo, cemi_node, cemi_list, &offset, size, pa_flags, &error ); pa_flags = 0; } } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_MemoryExt service */ static void dissect_memory_ext_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, guint16 ax, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; /* 4 bytes Range (1 byte Memory Length, 3 bytes Memory Address) */ if( offset + 4 > size ) { proto_item* node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Range" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 4 bytes" ); error = 1; offset = size; } else { /* 1 byte Memory Length or Error Code */ guint8 is_response = (ax == AX_MemExtReadResp || ax == AX_MemExtWriteResp); guint8 n = tvb_get_guint8( tvb, offset ); if( is_response ) { if( n != 0 ) { col_append_fstr( cinfo, COL_INFO, " E=$%02X", n ); proto_item_append_text( cemi_node, ", E=$%02X", n ); } } else { if( n != 1 ) { col_append_fstr( cinfo, COL_INFO, " N=%u", n ); proto_item_append_text( cemi_node, ", N=%u", n ); } } /* 3 bytes Memory Address */ guint32 x = tvb_get_guint24( tvb, offset + 1, ENC_BIG_ENDIAN ); col_append_fstr( cinfo, COL_INFO, " X=$%06" PRIX32, x ); proto_item_append_text( cemi_node, ", X=$%06" PRIX32, x ); if( is_response ) { proto_tree_add_item( cemi_list, hf_cemi_error, tvb, offset, 1, ENC_BIG_ENDIAN ); } else { proto_tree_add_item( cemi_list, hf_cemi_ext_memory_length, tvb, offset, 1, ENC_BIG_ENDIAN ); } proto_tree_add_item( cemi_list, hf_cemi_ext_memory_address, tvb, offset + 1, 3, ENC_BIG_ENDIAN ); offset += 4; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_UserMemory service */ static void dissect_user_memory_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; proto_tree* list; /* 3 bytes Range (Memory Length, Memory Address) */ if( offset + 3 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Range" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 3 bytes" ); error = 1; offset = size; } else { guint8 c2 = tvb_get_guint8( tvb, offset ); guint8 c1 = c2 >> 4; guint32 c3 = tvb_get_ntohs( tvb, offset + 1 ); c2 &= 0x0F; c3 |= c1 << 16UL; if( c2 != 1 ) col_append_fstr( cinfo, COL_INFO, " N=%u", c2 ); col_append_fstr( cinfo, COL_INFO, " X=$%05X", c3 ); if( tree ) { if( c2 != 1 ) proto_item_append_text( cemi_node, ", N=%u", c2 ); proto_item_append_text( cemi_node, ", X=$%05X", c3 ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Range: %u byte%s at address $%05X", c2, (c2 == 1) ? "" : "s", c3 ); list = proto_item_add_subtree( node, ett_cemi_range ); proto_tree_add_item( list, hf_cemi_memory_address_ext, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_memory_length, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_memory_address, tvb, offset + 1, 2, ENC_BIG_ENDIAN ); } offset += 3; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_FunctionProperty service */ static void dissect_function_property_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_error ) { /* 1 byte Object Index */ dissect_ox( tvb, pinfo, cemi_node, cemi_list, p_offset, size, p_error ); /* 1 byte Property ID */ dissect_pid( tvb, pinfo, cemi_node, cemi_list, p_offset, size, -1, 1, p_error ); } /* Dissect (obsolete) A_Router service */ static void dissect_router_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; proto_tree* list; /* 3 bytes Range (1 byte Memory Length, 2 bytes Memory Address) */ if( offset + 3 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Range" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 3 bytes" ); error = 1; offset = size; } else { guint8 c = tvb_get_guint8( tvb, offset ); guint16 cc = tvb_get_ntohs( tvb, offset + 1 ); if( c != 1 ) col_append_fstr( cinfo, COL_INFO, " N=%u", c ); col_append_fstr( cinfo, COL_INFO, " X=$%04X", cc ); if( tree ) { proto_item_append_text( cemi_node, ", N=%u, X=$%04X", c, cc ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 3, "Range: %u byte%s at address $%04X", c, (c == 1) ? "" : "s", cc ); list = proto_item_add_subtree( node, ett_cemi_range ); proto_tree_add_item( list, hf_cemi_ext_memory_length, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_ext_memory_address, tvb, offset + 1, 2, ENC_BIG_ENDIAN ); } offset += 3; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_Authenticate or A_Key service */ static void dissect_authenticate_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint16 ax, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; /* 1 byte Level */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Level: expected 1 byte" ); error = 1; } else { guint8 c = tvb_get_guint8( tvb, offset ); if( ax != AX_AuthReq || c != 0 ) { col_append_fstr( cinfo, COL_INFO, " L=%u", c ); if( tree ) { proto_item_append_text( cemi_node, ", L=%u", c ); } } if( tree ) { proto_tree_add_item( cemi_list, hf_cemi_level, tvb, offset, 1, ENC_BIG_ENDIAN ); } offset++; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_PropertyValue service */ static void dissect_property_value_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { /* 1 byte Object Index */ dissect_ox( tvb, pinfo, cemi_node, cemi_list, p_offset, size, p_error ); /* 1 byte Property ID */ dissect_pid( tvb, pinfo, cemi_node, cemi_list, p_offset, size, -1, 1, p_error ); /* 2 bytes Range */ dissect_range( tvb, pinfo, cemi_node, cemi_list, p_offset, size, *p_pa_flags, p_error ); } /* Dissect A_PropertyDescription service */ static void dissect_property_description_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { /* 1 byte Object Index */ dissect_ox( tvb, pinfo, cemi_node, cemi_list, p_offset, size, p_error ); /* 1 byte Property ID */ { guint8 pa_flags = *p_pa_flags; guint8 pid = dissect_pid( tvb, pinfo, cemi_node, cemi_list, p_offset, size, -1, pa_flags, p_error ); /* 1 byte Property Index */ dissect_px( tvb, pinfo, cemi_node, cemi_list, p_offset, size, pa_flags || !pid, p_error ); if( pa_flags ) /* A_PropertyDescription_Response */ { /* 1 byte PDT, 2 bytes Max Elements, 1 byte Access Levels */ dissect_prop_descr( tvb, pinfo, cemi_node, cemi_list, p_offset, size, p_error ); /* No further trailing data */ *p_pa_flags = 0; } } } /* Dissect A_NetworkParameter or A_GroupPropertyValue service */ static void dissect_network_parameter_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_error ) { /* 2 bytes Object Type */ guint16 ot = dissect_ot( tvb, pinfo, cemi_node, cemi_list, p_offset, size, p_error ); /* 1 byte Property ID */ dissect_pid( tvb, pinfo, cemi_node, cemi_list, p_offset, size, ot, 1, p_error ); } /* Dissect A_IndividualAddressSerialNumber or A_DomainAddressSerialNumber service */ static void dissect_ia_serial_number_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; /* 6 bytes Serial Nr */ if( offset + 6 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Serial Number" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 6 bytes" ); error = 1; offset = size; } else { proto_tree_add_data( cemi_list, tvb, offset, 6, cinfo, cemi_node, "Serial Number", " SN=$", ", SerNr=$" ); offset += 6; } if( pa_flags ) { if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Data: missing" ); error = 1; } } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_SystemNetworkParameter service */ static void dissect_system_network_parameter_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; const gchar* name; guint16 ot; guint16 cc; guint8 c; /* 2 bytes Object Type */ if( offset + 1 >= size ) { ot = 0; node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Object Type" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size; } else { ot = cc = tvb_get_ntohs( tvb, offset ); if( cc ) { col_append_fstr( cinfo, COL_INFO, " OT=%u", cc ); proto_item_append_text( cemi_node, ", OT=%u", cc ); } if( cemi_list ) { node = proto_tree_add_item( cemi_list, hf_cemi_ot, tvb, offset, 2, ENC_BIG_ENDIAN ); name = try_val_to_str( cc, ot_vals ); if( name ) { proto_item_append_text( node, " = %s", name ); } } offset += 2; } /* 2 bytes Property ID (12 bits) and Reserved (4 bits) */ if( offset + 1 >= size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Property ID" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size; } else { /* 12 bits Property ID */ cc = tvb_get_ntohs( tvb, offset ); c = cc & 0x000F; cc >>= 4; col_append_fstr( cinfo, COL_INFO, " P=%u", cc ); proto_item_append_text( cemi_node, ", PID=%u", cc ); if( cemi_list ) { node = proto_tree_add_item( cemi_list, hf_cemi_snp_pid, tvb, offset, 2, ENC_BIG_ENDIAN ); name = get_pid_name( ot, cc ); if( name ) { proto_item_append_text( node, " = %s", name ); } } ++offset; /* 4 bits Reserved */ if( c ) { col_append_fstr( cinfo, COL_INFO, " $%X", c ); proto_item_append_text( cemi_node, ", $%X", c ); node = proto_tree_add_item( cemi_list, hf_cemi_snp_reserved, tvb, offset, 1, ENC_BIG_ENDIAN ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: zero" ); error = 1; } ++offset; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_PropertyExtValue service */ static void dissect_property_ext_value_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; /* 2 bytes OT, 12 bits OI, 12 bits PID */ dissect_pid_ext( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); /* 3 bytes Range (1 byte Count, 2 bytes Index) */ if( offset + 3 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Range" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 3 bytes" ); error = 1; offset = size; } else { /* 1 byte Count */ guint8 ne = tvb_get_guint8( tvb, offset ); if( ne != 1 ) { col_append_fstr( cinfo, COL_INFO, " N=%u", ne ); proto_item_append_text( cemi_node, ", N=%u", ne ); } /* 2 bytes Index */ guint16 sx = tvb_get_ntohs( tvb, offset + 1 ); if( sx != 1 ) { col_append_fstr( cinfo, COL_INFO, " X=%u", sx ); proto_item_append_text( cemi_node, ", X=%u", sx ); } if( cemi_list ) { proto_item *range_node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 3, "Range: %u element%s at position %u", ne, (ne == 1) ? "" : "s", sx ); proto_tree *range_list = proto_item_add_subtree( range_node, ett_cemi_range ); proto_tree_add_item( range_list, hf_cemi_ext_ne, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( range_list, hf_cemi_ext_sx, tvb, offset + 1, 2, ENC_BIG_ENDIAN ); } offset += 3; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_PropertyExtDescription service */ static void dissect_property_ext_description_service( tvbuff_t* tvb, packet_info* pinfo, proto_item* cemi_node, proto_tree* cemi_list, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; guint16 cc; guint8 c; /* 2 bytes OT, 12 bits OI, 12 bits PID */ dissect_pid_ext( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); /* 4 bits Description Type */ if( offset >= size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Description Type" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 4 bits" ); error = 1; } else { c = tvb_get_guint8( tvb, offset ) >> 4; col_append_fstr( cinfo, COL_INFO, " D=%u", c ); proto_item_append_text( cemi_node, ", D=%u", c ); proto_tree_add_item( cemi_list, hf_cemi_ext_dt, tvb, offset, 1, ENC_BIG_ENDIAN ); } /* 12 bits Property Index */ if( offset + 2 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Property Index" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 12 bits" ); error = 1; offset = size; } else { cc = tvb_get_ntohs( tvb, offset ) & 0x0FFF; col_append_fstr( cinfo, COL_INFO, " PX=%u", cc ); proto_item_append_text( cemi_node, ", PX=%u", cc ); proto_tree_add_item( cemi_list, hf_cemi_ext_px, tvb, offset, 2, ENC_BIG_ENDIAN ); offset += 2; } if( pa_flags ) /* AX_PropExtDescrResp */ { /* 4 bytes DPT (2 bytes DPT Major, 2 bytes DPT Minor) */ if( offset + 4 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Data Point Type" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 4 bytes" ); error = 1; offset = size; } else { guint16 dpt_major = tvb_get_ntohs( tvb, offset ); guint16 dpt_minor = tvb_get_ntohs( tvb, offset + 2 ); if( cemi_list ) { proto_item *dpt_node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 2, "Data Point Type: %u.%u", dpt_major, dpt_minor ); proto_tree *dpt_list = proto_item_add_subtree( dpt_node, ett_cemi_dpt ); proto_tree_add_item( dpt_list, hf_cemi_dpt_major, tvb, offset, 2, ENC_BIG_ENDIAN ); proto_tree_add_item( dpt_list, hf_cemi_dpt_minor, tvb, offset + 2, 2, ENC_BIG_ENDIAN ); } offset += 4; if( dpt_major || dpt_minor ) { col_append_fstr( cinfo, COL_INFO, " DPT=%u.%u", dpt_major, dpt_minor ); proto_item_append_text( cemi_node, ", DPT=%u.%u", dpt_major, dpt_minor ); } } /* 1 byte PDT, 2 bytes Max Elements, 1 byte Access Levels */ dissect_prop_descr( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); /* No further trailing data */ pa_flags = 0; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect A_DataSecurity service */ static void dissect_data_security_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint16 source_addr, proto_item* source_node, guint16 dest_addr, proto_item* dest_node, guint8 unicast, const gchar* name, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; proto_tree* root_tree = tree; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; proto_tree* list; // 1 byte SCF, 6 bytes SeqNr, ... // and either another SeqNr for sync or Apci+Mac (2+4 bytes) for data. if( offset + 13 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? SCF, SeqNr, ..." ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: min 13 bytes" ); error = 1; offset = size; } else { /* 1 byte SCF */ guint8 scf = tvb_get_guint8( tvb, offset ); guint8 is_sync = (scf & 6) == 0x02; guint8 is_sync_req = is_sync && (scf & 1) == 0; guint8 is_sync_res = is_sync && !is_sync_req; guint64 seq_nr; name = try_val_to_str( scf, scf_short_vals ); if( !name ) name = "?"; col_append_fstr( cinfo, COL_INFO, " %s", name ); proto_item_append_text( cemi_node, ", %s", name ); node = proto_tree_add_item( cemi_list, hf_cemi_scf, tvb, offset, 1, ENC_BIG_ENDIAN ); list = proto_item_add_subtree( node, ett_cemi_scf ); proto_tree_add_item( list, hf_cemi_scf_t, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_scf_sai, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_scf_sbc, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_scf_svc, tvb, offset, 1, ENC_BIG_ENDIAN ); ++offset; /* 6 bytes SeqNr */ name = is_sync_req ? "SeqNrLocal" : is_sync_res ? "Challenge" : "SeqNr"; seq_nr = tvb_get_ntoh48( tvb, offset ); proto_tree_add_data( cemi_list, tvb, offset, 6, cinfo, cemi_node, name, NULL, is_sync_res ? NULL : ", SeqNrLocal=$" ); offset += 6; if( is_sync ) { /* 6 bytes SyncReq SerNr or SyncRes SeqNrRemote */ name = is_sync_req ? "SerNr" : "SeqNrRemote"; proto_tree_add_data( cemi_list, tvb, offset, 6, cinfo, cemi_node, name, NULL, is_sync_res ? ", SeqNrRemote=$" : NULL ); offset += 6; /* 6 bytes SyncReq Challenge or SyncRes SeqNrLocal */ name = is_sync_req ? "Challenge" : "SeqNrLocal"; if( offset + 6 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "%s", name ); proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 6 bytes" ); error = 1; offset = size; } else { proto_tree_add_data( cemi_list, tvb, offset, 6, NULL, NULL, name, NULL, NULL ); offset += 6; if( offset < size ) { /* 4 bytes MAC */ node = proto_tree_add_data( cemi_list, tvb, offset, size - offset, NULL, NULL, "Message Authentication Code", NULL, NULL ); if( offset + 4 != size ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 4 bytes" ); error = 1; } offset = size; } } } else // Data { struct data_security_info info; struct knx_keyring_ia_seqs* ia_seq; const guint8* cemi; const guint8* encrypted; gint encrypted_size; const guint8* decrypted; proto_item* item; info.source = source_addr; info.dest = dest_addr; info.multicast = !unicast; info.seq_nr = seq_nr; *info.output_text = '\0'; if( !unicast ) // multicast or broadcast { // Check sending IA guint8 ga_found = 0; guint8 ia_ok = 0; struct knx_keyring_ga_senders* ga_sender = knx_keyring_ga_senders; for( ; ga_sender; ga_sender = ga_sender->next ) { if( ga_sender->ga == dest_addr ) { ga_found = 1; if( ga_sender->ia == source_addr ) { ia_ok = 1; break; } } } if( !ia_ok ) { if( ga_found ) { expert_add_info_format( pinfo, source_node, KIP_ERROR, "Unknown sender" ); error = 1; } else { expert_add_info_format( pinfo, dest_node, KIP_WARNING, "Unknown group address" ); } } } // Check SeqNr for( ia_seq = knx_keyring_ia_seqs; ia_seq; ia_seq = ia_seq->next ) { if( ia_seq->ia == source_addr ) { if( ia_seq->seq > seq_nr ) { expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: min $%012" PRIX64, ia_seq->seq ); break; } } } // Get encrypted data. cemi = tvb_get_ptr( tvb, 0, size ); encrypted = cemi + offset; encrypted_size = size - offset; // Decrypt. decrypted = decrypt_data_security_data( pinfo->pool, encrypted, encrypted_size, cemi, size, &info ); if( decrypted ) { tvbuff_t* tvb2 = tvb_new_child_real_data( tvb, decrypted, encrypted_size, encrypted_size ); gint size2 = encrypted_size - 4; // > 0, guaranteed by decrypt_data_security_data proto_item_append_text( cemi_node, ", MAC OK" ); //tvb_set_free_cb(tvb2, wmem_free); add_new_data_source( pinfo, tvb2, "Decrypted" ); item = proto_tree_add_none_format( cemi_list, hf_folder, tvb2, 0, encrypted_size, "Decrypted" ); tree = proto_item_add_subtree( item, ett_cemi_decrypted ); if( *info.output_text ) { proto_item_append_text( item, " (%s)", info.output_text ); } proto_tree_add_data( tree, tvb2, 0, size2, NULL, NULL, "Embedded APDU", NULL, NULL ); proto_tree_add_data( tree, tvb2, size2, 4, NULL, NULL, "Message Authentication Code", NULL, NULL ); /* Dissect embedded APDU */ { // Hack: To save us from splitting another sub dissector which only // dissects the Apci+Apdu // we synthesize a telegram from the outer ApciSec telegram fields and the inner // decrypted apci+apdu and then we dissect this as a new cEMI frame. gint innerTelegramSize = size - 13; // > 0, already checked above gint additionalInfoLength = cemi[ 1 ]; // cemi size > 13, already checked above gint offsetToApci = additionalInfoLength + 9; if( offsetToApci < size ) { if( offsetToApci + size2 <= innerTelegramSize ) { guint8* innerTelegram = (guint8*) wmem_alloc( pinfo->pool, innerTelegramSize ); memcpy( innerTelegram, cemi, offsetToApci ); memcpy( innerTelegram + offsetToApci, decrypted, size2 ); innerTelegram[ additionalInfoLength + 8 ] = (guint8) (size2 - 1); tvbuff_t* tvb3 = tvb_new_child_real_data( tvb, innerTelegram, innerTelegramSize, innerTelegramSize ); //tvb_set_free_cb(tvb3, wmem_free); add_new_data_source( pinfo, tvb3, "Inner Decrypted Telegram" ); dissector_handle_t cemi_handle = find_dissector( "cemi" ); if( cemi_handle ) { call_dissector( cemi_handle, tvb3, pinfo, root_tree ); } } } } } else { // Could not be decrypted. proto_item_append_text( cemi_node, ", Could not be decrypted" ); if( *info.output_text ) { proto_item_append_text( cemi_node, " (%s)", info.output_text ); } } offset = size; } } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect extended AL service (10 bit AL service code) */ static void dissect_extended_app_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint16 source_addr, proto_item* source_node, guint16 dest_addr, proto_item* dest_node, guint8 unicast, guint16 ax, const gchar* name, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node = NULL; proto_tree* list = NULL; col_append_fstr( cinfo, COL_INFO, " %s", name ); if( tree ) { proto_item_append_text( cemi_node, ", %s", name ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 2, "APCI: %s", name ); list = proto_item_add_subtree( node, ett_cemi_apci ); proto_tree_add_item( list, hf_cemi_ax, tvb, offset, 2, ENC_BIG_ENDIAN ); } offset += 2; pa_flags = PA_RESPONSE | PA_DATA; switch( ax ) { case AX_UserMemRead: case AX_MemExtRead: case AX_RoutingTableRead: case AX_RouterMemRead: case AX_PropValueRead: case AX_PropDescrRead: case AX_IndAddrSerNumRead: case AX_DomAddrSerNumRead: case AX_PropExtValueRead: case AX_PropExtDescrRead: pa_flags = 0; break; } switch( ax ) { case AX_MemExtRead: case AX_MemExtReadResp: case AX_MemExtWrite: case AX_MemExtWriteResp: dissect_memory_ext_service( tvb, pinfo, cemi_node, cemi_list, ax, &offset, size, &pa_flags, &error ); break; case AX_UserMemRead: case AX_UserMemResp: case AX_UserMemWrite: case AX_UserMemBitWrite: dissect_user_memory_service( tvb, pinfo, tree, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_FuncPropCmd: case AX_FuncPropRead: case AX_FuncPropResp: dissect_function_property_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); break; case AX_RoutingTableRead: case AX_RouterMemRead: case AX_RoutingTableResp: case AX_RoutingTableWrite: case AX_RouterMemResp: case AX_RouterMemWrite: case AX_MemBitWrite: dissect_router_service( tvb, pinfo, tree, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_AuthReq: case AX_AuthResp: case AX_KeyWrite: case AX_KeyResp: dissect_authenticate_service( tvb, pinfo, tree, cemi_node, cemi_list, ax, &offset, size, &pa_flags, &error ); break; case AX_PropValueRead: case AX_PropValueResp: case AX_PropValueWrite: dissect_property_value_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_PropDescrRead: case AX_PropDescrResp: dissect_property_description_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_NwkParamRead: case AX_NwkParamResp: case AX_NwkParamWrite: case AX_GroupPropValueRead: case AX_GroupPropValueResp: case AX_GroupPropValueWrite: case AX_GroupPropValueInfo: dissect_network_parameter_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); break; case AX_IndAddrSerNumRead: case AX_DomAddrSerNumRead: case AX_IndAddrSerNumResp: case AX_IndAddrSerNumWrite: case AX_DomAddrSerNumResp: case AX_DomAddrSerNumWrite: dissect_ia_serial_number_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_SysNwkParamRead: case AX_SysNwkParamResp: case AX_SysNwkParamWrite: dissect_system_network_parameter_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_PropExtValueRead: case AX_PropExtValueResp: case AX_PropExtValueWriteCon: case AX_PropExtValueWriteConRes: case AX_PropExtValueWriteUnCon: dissect_property_ext_value_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_PropExtDescrRead: case AX_PropExtDescrResp: dissect_property_ext_description_service( tvb, pinfo, cemi_node, cemi_list, &offset, size, &pa_flags, &error ); break; case AX_FuncPropExtCmd: case AX_FuncPropExtRead: case AX_FuncPropExtResp: /* 2 bytes OT, 12 bits OI, 12 bits PID */ dissect_pid_ext( tvb, pinfo, cemi_node, cemi_list, &offset, size, &error ); break; case AX_DataSec: dissect_data_security_service( tvb, pinfo, tree, cemi_node, cemi_list, source_addr, source_node, dest_addr, dest_node, unicast, name, &offset, size, &pa_flags, &error ); break; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect simple AL service (4 bit AL service code) */ static void dissect_simple_app_service( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint8 ac, guint8 ad, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node = NULL; proto_tree* list = NULL; guint8 c; guint16 cc; const gchar* name = val_to_str( ac, ac_vals, "AC=%u" ); col_append_fstr( cinfo, COL_INFO, " %s", name ); if( tree ) { proto_item_append_text( cemi_node, ", %s", name ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 2, "APCI: %s", name ); list = proto_item_add_subtree( node, ett_cemi_apci ); proto_tree_add_item( list, hf_cemi_ac, tvb, offset, 2, ENC_BIG_ENDIAN ); } offset++; switch( ac ) { case AC_GroupValueRead: case AC_MemRead: case AC_AdcRead: case AC_DevDescrRead: pa_flags = 0; break; } switch( ac ) { case AC_GroupValueRead: case AC_GroupValueResp: case AC_GroupValueWrite: case AC_Restart: { guint8 expected = ((pa_flags && offset + 1 >= size) || ac == AC_Restart); if( expected || ad != 0 ) { /* Show APCI 6-bit data */ if( !expected ) { error = 1; } else if( ad != 0 || ac != AC_Restart || offset + 1 < size ) { col_append_fstr( cinfo, COL_INFO, " $%02X", ad ); proto_item_append_text( cemi_node, " $%02X", ad ); } if( tree ) { node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Data: %02X", ad ); list = proto_item_add_subtree( node, ett_cemi_apci ); proto_tree_add_item( list, hf_cemi_ad, tvb, offset, 1, ENC_BIG_ENDIAN ); if( !expected ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 0x00" ); } } } } break; case AC_MemRead: case AC_MemResp: case AC_MemWrite: /* 6 bits Memory Length, 2 bytes Memory Address */ if( offset + 3 > size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset + 1, size - offset - 1, NULL, "? Memory Address" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size - 1; } else { cc = tvb_get_ntohs( tvb, offset + 1 ); if( ad != 1 ) col_append_fstr( cinfo, COL_INFO, " N=%u", ad ); col_append_fstr( cinfo, COL_INFO, " X=$%04X", cc ); if( tree ) { if( ad != 1 ) proto_item_append_text( cemi_node, ", N=%u", ad ); proto_item_append_text( cemi_node, ", X=$%04X", cc ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 3, "Range: %u byte%s at address $%04X", ad, (ad == 1) ? "" : "s", cc ); list = proto_item_add_subtree( node, ett_cemi_range ); proto_tree_add_item( list, hf_cemi_ad_memory_length, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_memory_address, tvb, offset + 1, 2, ENC_BIG_ENDIAN ); } offset += 2; } break; case AC_AdcRead: case AC_AdcResp: /* 6 bits Channel */ col_append_fstr( cinfo, COL_INFO, " #%u", ad ); if( tree ) { proto_item_append_text( cemi_node, " #%u", ad ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Channel: %u", ad ); list = proto_item_add_subtree( node, ett_cemi_apci ); proto_tree_add_item( list, hf_cemi_ad_channel, tvb, offset, 1, ENC_BIG_ENDIAN ); } ++offset; /* 1 byte Count */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Count: expected 1 byte" ); error = 1; --offset; } else { c = tvb_get_guint8( tvb, offset ); if( c != 1 ) { col_append_fstr( cinfo, COL_INFO, " N=%u", c ); proto_item_append_text( cemi_node, ", N=%u", c ); } proto_tree_add_item( cemi_list, hf_cemi_adc_count, tvb, offset, 1, ENC_BIG_ENDIAN ); } break; case AC_DevDescrRead: case AC_DevDescrResp: /* 6 bits Descriptor Type */ if( ad != 0 ) col_append_fstr( cinfo, COL_INFO, " #%u", ad ); if( tree ) { if( ad != 0 ) proto_item_append_text( cemi_node, " #%u", ad ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Descriptor Type: %u", ad ); list = proto_item_add_subtree( node, ett_cemi_apci ); proto_tree_add_item( list, hf_cemi_ad_type, tvb, offset, 1, ENC_BIG_ENDIAN ); } break; case AC_UserMsg: case AC_Escape: /* 6 bits Data */ col_append_fstr( cinfo, COL_INFO, " #%u", ad ); if( tree ) { proto_item_append_text( cemi_node, " #%u", ad ); proto_item_append_text( node, " $%02X", ad ); proto_tree_add_item( list, hf_cemi_ad, tvb, offset, 1, ENC_BIG_ENDIAN ); } break; } offset++; *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect cEMI Application Layer */ static void dissect_cemi_app_layer( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint16 source_addr, proto_item* source_node, guint16 dest_addr, proto_item* dest_node, guint8 unicast, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; /* 10 bits APCI */ if( offset + 1 >= size ) { proto_item* node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? APCI" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size; } else { /* Extract and split AL service code */ guint8 tb = tvb_get_guint8( tvb, offset ); guint8 ab = tvb_get_guint8( tvb, offset + 1 ); /* 4 bits simple AL service code */ guint8 ac = ((tb & 0x03) << 2) | ((ab & 0xC0) >> 6); /* 6 bits data */ guint8 ad = ab & 0x3F; /* 10 = 4 + 6 bits extended AL service code */ guint16 ax = (ac << 6) | ad; const gchar* name = try_val_to_str( ax, ax_vals ); if( name ) /* Extended AL code (10 bits) */ { dissect_extended_app_service( tvb, pinfo, tree, cemi_node, cemi_list, source_addr, source_node, dest_addr, dest_node, unicast, ax, name, &offset, size, &pa_flags, &error ); } else /* Simple AL code (4 bits) followed by data (6 bits) */ { dissect_simple_app_service( tvb, pinfo, tree, cemi_node, cemi_list, ac, ad, &offset, size, &pa_flags, &error ); } } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect cEMI Transport Layer */ static void dissect_cemi_transport_layer( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint8 is_tdata, guint16 source_addr, proto_item* source_node, guint16 dest_addr, proto_item* dest_node, guint8 unicast, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node; const gchar* name; gchar text[ 128 ]; guint8 c; /* 6 bits TPCI */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? TPCI: expected 1 byte" ); error = 1; } else { guint8 tb = tvb_get_guint8( tvb, offset ); proto_item *tpci_node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "TPCI" ); proto_tree *tpci_list = proto_item_add_subtree( tpci_node, ett_cemi_tpci ); guint8 tpci_error = 0; node = proto_tree_add_item( tpci_list, hf_cemi_tpt, tvb, offset, 1, ENC_BIG_ENDIAN ); if( is_tdata && (tb & 0x80) ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: zero" ); tpci_error = 1; } node = proto_tree_add_item( tpci_list, hf_cemi_tst, tvb, offset, 1, ENC_BIG_ENDIAN ); if( is_tdata && (tb & 0x40) ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: zero" ); tpci_error = 1; } c = (tb & 0x3C) >> 2; if( c || tb & 0x40 ) /* Numbered Packet? */ { node = proto_tree_add_item( tpci_list, hf_cemi_num, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_item_append_text( tpci_node, ", SeqNum = %u", c ); if( !(tb & 0x40) ) { expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: zero" ); tpci_error = 1; } } if( tb & 0x80 ) /* Control Packet */ { /* 2 bits TPCI Code */ guint8 tc = tb & 0x03; name = try_val_to_str( tc, tc_vals ); if( !name ) { snprintf( text, sizeof text, "TC=%u", tc ); name = text; } col_append_fstr( cinfo, COL_INFO, " %s", name ); if( tree ) { proto_item_append_text( cemi_node, ", %s", name ); proto_item_append_text( tpci_node, ": %s", name ); proto_tree_add_item( tpci_list, hf_cemi_tc, tvb, offset, 1, ENC_BIG_ENDIAN ); } } if( tpci_error ) { proto_item_prepend_text( tpci_node, "? " ); error = 1; } if( tb & 0x80 ) /* Control Packet */ { pa_flags = 0; offset++; } else /* Data Packet */ { /* APCI etc */ dissect_cemi_app_layer( tvb, pinfo, tree, cemi_node, cemi_list, source_addr, source_node, dest_addr, dest_node, unicast, &offset, size, &pa_flags, &error ); } } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } /* Dissect cEMI Link Layer (typically L_Data or T_Data) */ static void dissect_cemi_link_layer( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* cemi_node, proto_tree* cemi_list, guint8 mc, gint* p_offset, gint size, guint8* p_pa_flags, guint8* p_error ) { column_info* cinfo = pinfo->cinfo; gint offset = *p_offset; guint8 pa_flags = *p_pa_flags; guint8 error = *p_error; proto_item* node = NULL; proto_tree* list = NULL; const gchar* name; gchar text[ 128 ]; guint8 c; guint8 is_tdata = 0; guint8 is_ldata = 0; guint16 source_addr = 0; guint16 dest_addr = 0; guint8 unicast = 0; proto_item* source_node = NULL; proto_item* dest_node = NULL; proto_item* ai_node; proto_tree* ai_list; if( size < 2 ) { ai_list = proto_tree_add_subtree( cemi_list, tvb, offset, 0, ett_cemi_ai, &ai_node, "? Additional Info" ); proto_tree_add_expert_format( ai_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Length: expected 1 byte" ); offset = size; error = 1; } else { /* Additional Information */ guint8 ai_len = tvb_get_guint8( tvb, 1 ); gint ai_end = 2 + ai_len; gint ai_size = ai_len; if( ai_end > size ) { error = 2; ai_size = size - 2; ai_end = size; } ai_node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, 1, ai_size + 1, "Additional Info (%u bytes)", ai_len ); ai_list = proto_item_add_subtree( ai_node, ett_cemi_ai ); node = proto_tree_add_item( ai_list, hf_cemi_ai_length, tvb, 1, 1, ENC_BIG_ENDIAN ); if( error == 2 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Available: %d bytes", ai_size ); } offset = 2; while( offset < ai_end ) { /* Additional Information Element */ guint8 aie_type = tvb_get_guint8( tvb, offset ); guint8 aie_len; gint aie_size; proto_item *aie_node; proto_tree *aie_list; name = try_val_to_str( aie_type, aiet_vals ); if( offset + 1 >= ai_end ) { error = 3; aie_len = 0; aie_size = 1; } else { aie_len = tvb_get_guint8( tvb, offset + 1 ); aie_size = ai_end - offset - 2; if( aie_size < aie_len ) { error = 4; } else { aie_size = aie_len; } aie_size += 2; } aie_node = proto_tree_add_none_format( ai_list, hf_folder, tvb, offset, aie_size, "Additional Info: %s", name ? name : "?" ); aie_list = proto_item_add_subtree( aie_node, ett_cemi_aie ); node = proto_tree_add_item( aie_list, hf_cemi_aie_type, tvb, offset, 1, ENC_BIG_ENDIAN ); if( name ) proto_item_append_text( node, " = %s", name ); offset++; if( error == 3 ) { proto_item_prepend_text( aie_node, "? " ); proto_tree_add_expert_format( aie_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Length: expected 1 byte" ); break; } proto_item_append_text( aie_node, " (%u bytes)", aie_len ); node = proto_tree_add_item( aie_list, hf_cemi_aie_length, tvb, offset, 1, ENC_BIG_ENDIAN ); offset++; if( error == 4 ) { proto_item_prepend_text( aie_node, "? " ); proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Available: %d bytes", aie_size - 2 ); break; } if( aie_len > 0 ) { proto_tree_add_data( aie_list, tvb, offset, aie_len, NULL, NULL, "Data", NULL, NULL ); offset += aie_len; } else { proto_item_prepend_text( aie_node, "? " ); proto_item_append_text( node, " (?)" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: >= 1 byte(s)" ); error = 5; } } if( error >= 2 ) { proto_item_prepend_text( ai_node, "? " ); } offset = ai_end; } switch( mc ) { case CEMI_L_BUSMON_IND: case CEMI_L_RAW_IND: case CEMI_L_RAW_REQ: case CEMI_L_RAW_CON: break; default: switch( mc ) { case CEMI_L_DATA_REQ: case CEMI_L_DATA_CON: case CEMI_L_DATA_IND: is_ldata = 1; break; case CEMI_T_DATA_INDIVIDUAL_REQ: case CEMI_T_DATA_INDIVIDUAL_IND: case CEMI_T_DATA_CONNECTED_REQ: case CEMI_T_DATA_CONNECTED_IND: is_tdata = 1; break; } if( is_tdata ) { gint length = (size >= offset + 6) ? 6 : size - offset; node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, length, NULL, "Reserved" ); if( length < 6 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 6 bytes" ); error = 1; } else { gint pos = 0; for( ; pos < 6; pos++ ) { if( tvb_get_guint8( tvb, offset + pos ) != 0 ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: zero" ); error = 1; break; } } } is_tdata = 1; offset += length; } else { /* 1 byte Control Field 1 */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Ctrl1: expected 1 byte" ); error = 1; } else { if( tree ) { c = tvb_get_guint8( tvb, offset ); proto_item_append_text( cemi_node, ", " ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Ctrl1: " ); if( !(c & 0x80) ) { proto_item_append_text( cemi_node, "X " ); proto_item_append_text( node, "Extended, " ); } if( !(c & 0x20) ) { proto_item_append_text( cemi_node, "R " ); proto_item_append_text( node, "Repeat On Error, " ); } if( !(c & 0x10) ) { proto_item_append_text( cemi_node, "B " ); proto_item_append_text( node, "System Broadcast, " ); } if( c & 0x02 ) { proto_item_append_text( cemi_node, "A " ); proto_item_append_text( node, "Ack Wanted, " ); } if( c & 0x01 ) { proto_item_append_text( cemi_node, "C " ); proto_item_append_text( node, "Unconfirmed, " ); } name = try_val_to_str( (c & 0x0C) >> 2, prio_vals ); if( !name ) name = "?"; proto_item_append_text( cemi_node, "P=%s", name ); proto_item_append_text( node, "Prio = %s", name ); list = proto_item_add_subtree( node, ett_cemi_ctrl1 ); proto_tree_add_item( list, hf_cemi_ft, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_rep, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_bt, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_prio, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_ack, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_ce, tvb, offset, 1, ENC_BIG_ENDIAN ); } offset++; } /* 1 byte Control Field 2 */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Ctrl2: expected 1 byte" ); error = 1; } else { c = tvb_get_guint8( tvb, offset ); unicast = !(c & 0x80); /* Address Type (IA or GA) */ if( tree ) { guint8 hc = (c & 0x70) >> 4; /* Hop Count */ guint8 eff = c & 0x0F; /* Extended Frame Format (0 = standard) */ snprintf( text, sizeof text, "%u", (c & 0x70) >> 4 ); /* hop count */ proto_item_append_text( cemi_node, ", H=%u", hc ); node = proto_tree_add_none_format( cemi_list, hf_folder, tvb, offset, 1, "Ctrl2: Hops = %u", hc ); if( eff ) { proto_item_append_text( cemi_node, " F=%u", eff ); proto_item_append_text( cemi_node, " Frame = %u", eff ); } list = proto_item_add_subtree( node, ett_cemi_ctrl2 ); proto_tree_add_item( list, hf_cemi_at, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_hc, tvb, offset, 1, ENC_BIG_ENDIAN ); proto_tree_add_item( list, hf_cemi_eff, tvb, offset, 1, ENC_BIG_ENDIAN ); } offset++; } /* 2 bytes Source Address */ if( offset + 1 >= size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Source" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size; } else { source_addr = tvb_get_ntohs( tvb, offset ); snprintf( text, sizeof text, "%u.%u.%u", (source_addr >> 12) & 0xF, (source_addr >> 8) & 0xF, source_addr & 0xFF ); col_append_fstr( cinfo, COL_INFO, " %s", text ); if( tree ) { proto_item_append_text( cemi_node, ", Src=%s", text ); source_node = proto_tree_add_item( cemi_list, hf_cemi_sa, tvb, offset, 2, ENC_BIG_ENDIAN ); proto_item_append_text( source_node, " = %s", text ); } offset += 2; } /* 2 bytes Destination Address */ if( offset + 1 >= size ) { node = proto_tree_add_bytes_format( cemi_list, hf_bytes, tvb, offset, size - offset, NULL, "? Destination" ); expert_add_info_format( pinfo, node, KIP_ERROR, "Expected: 2 bytes" ); error = 1; offset = size; } else { dest_addr = tvb_get_ntohs( tvb, offset ); if( unicast ) { /* Individual Address */ snprintf( text, sizeof text, "%u.%u.%u", (dest_addr >> 12) & 0xF, (dest_addr >> 8) & 0xF, dest_addr & 0xFF ); } else { /* Group Address */ snprintf( text, sizeof text, "%u/%u/%u", (dest_addr >> 11) & 0x1F, (dest_addr >> 8) & 0x7, dest_addr & 0xFF ); } col_append_fstr( cinfo, COL_INFO, "->%s", text ); if( tree ) { proto_item_append_text( cemi_node, ", Dst=%s", text ); dest_node = proto_tree_add_item( cemi_list, hf_cemi_da, tvb, offset, 2, ENC_BIG_ENDIAN ); proto_item_append_text( dest_node, " = %s", text ); } offset += 2; } } if( is_ldata || is_tdata ) { /* 1 byte NPDU Length */ if( offset >= size ) { proto_tree_add_expert_format( cemi_list, pinfo, KIP_ERROR, tvb, offset, 0, "? Length: expected 1 byte" ); error = 1; } else { guint8 data_len = tvb_get_guint8( tvb, offset ); node = proto_tree_add_item( cemi_list, hf_cemi_len, tvb, offset, 1, ENC_BIG_ENDIAN ); if( offset + 2 + data_len != size ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Available: %d bytes", size - offset - 2 ); error = 1; } offset++; } /* TPCI etc */ dissect_cemi_transport_layer( tvb, pinfo, tree, cemi_node, cemi_list, is_tdata, source_addr, source_node, dest_addr, dest_node, unicast, &offset, size, &pa_flags, &error ); } break; } *p_offset = offset; *p_pa_flags = pa_flags; *p_error = error; } static gint dissect_cemi( tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, void* data _U_ ) { gint offset = 0; gint size = tvb_captured_length_remaining( tvb, 0 ); guint8 error = 0; column_info* cinfo = pinfo->cinfo; /* cEMI node in tree view */ proto_item* cemi_node = proto_tree_add_item( tree, proto_cemi, tvb, 0, size, ENC_BIG_ENDIAN ); /* Subnodes of cEMI node */ proto_tree* cemi_list = proto_item_add_subtree( cemi_node, ett_cemi ); guint8 pa_flags = PA_DATA; /* Only add cEMI information to the info column (not replacing it). This means that we do not have to clear that column here, but are adding a seperator here. */ col_append_str( cinfo, COL_INFO, " " ); /* Replace long name "Common External Message Interface" by short name "cEMI" */ proto_item_set_text( cemi_node, "cEMI" ); if( size <= 0 ) { expert_add_info_format( pinfo, cemi_node, KIP_ERROR, "Expected: min 1 byte" ); error = 1; } else { /* 1 byte cEMI Message Code */ guint8 mc = tvb_get_guint8( tvb, 0 ); const gchar* name = try_val_to_str( mc, mc_vals ); if( !name ) { /* Unknown Message Code */ col_append_str( cinfo, COL_INFO, "cEMI" ); pa_flags = 0; } else { /* Add cEMI message code to info column */ col_append_str( cinfo, COL_INFO, name ); /* Show MC in cEMI node, and more detailed in a subnode */ proto_item_append_text( cemi_node, " %s", name ); proto_tree_add_item( cemi_list, hf_cemi_mc, tvb, 0, 1, ENC_BIG_ENDIAN ); offset = 1; if( mc >= 0xF0 ) { /* cEMI Management packet */ dissect_cemi_mgmt_packet( tvb, pinfo, cemi_node, cemi_list, mc, &offset, size, &pa_flags, &error ); } else { /* cEMI Link Layer packet */ dissect_cemi_link_layer( tvb, pinfo, tree, cemi_node, cemi_list, mc, &offset, size, &pa_flags, &error ); } } } if( offset < size ) { /* Trailing data */ proto_item* node = proto_tree_add_data( cemi_list, tvb, offset, size - offset, cinfo, cemi_node, "Data", " $", ", $" ); if( !pa_flags ) { proto_item_prepend_text( node, "? " ); expert_add_info_format( pinfo, node, KIP_ERROR, "Unexpected" ); error = 1; } offset = size; } if( error ) { /* If not already done */ if( !knxip_error ) { knxip_error = 1; col_prepend_fstr( cinfo, COL_INFO, "? " ); } proto_item_prepend_text( cemi_node, "? " ); } return size; } void proto_register_cemi( void ) { /* Header fields */ static hf_register_info hf[] = { { &hf_bytes, { "Data", "cemi.data", FT_BYTES, BASE_NONE, NULL, 0, NULL, HFILL } }, { &hf_folder, { "Folder", "cemi.folder", FT_NONE, BASE_NONE, NULL, 0, NULL, HFILL } }, { &hf_cemi_mc, { "Message Code", "cemi.mc", FT_UINT8, BASE_HEX, VALS( mc_vals ), 0, NULL, HFILL } }, { &hf_cemi_error, { "Error", "cemi.e", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_ai_length, { "Additional Information Length", "cemi.ai.n", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_aie_type, { "Additional Information Element Type", "cemi.ait.n", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_aie_length, { "Additional Information Element Length", "cemi.aie.n", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ot, { "Object Type", "cemi.ot", FT_UINT16, BASE_DEC, VALS( ot_vals ), 0, NULL, HFILL } }, { &hf_cemi_oi, { "Object Instance", "cemi.oi", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ox, { "Object Index", "cemi.ox", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_px, { "Property Index", "cemi.px",FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_pid, { "Property ID", "cemi.pid", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ne, { "Count", "cemi.n", FT_UINT8, BASE_DEC, NULL, 0xF0, NULL, HFILL } }, { &hf_cemi_sx, { "Index", "cemi.x", FT_UINT16, BASE_DEC, NULL, 0x0FFF, NULL, HFILL } }, { &hf_cemi_ft, { "Frame Type", "cemi.ft", FT_UINT8, BASE_DEC, VALS( ft_vals ), 0x80, NULL, HFILL } }, { &hf_cemi_rep, { "Repeat On Error", "cemi.rep", FT_BOOLEAN, 8, TFS(&tfs_no_yes), 0x20, NULL, HFILL } }, { &hf_cemi_bt, { "Broadcast Type", "cemi.bt", FT_UINT8, BASE_DEC, VALS( bt_vals ), 0x10, NULL, HFILL } }, { &hf_cemi_prio, { "Priority", "cemi.prio", FT_UINT8, BASE_DEC, VALS( prio_vals ), 0x0C, NULL, HFILL } }, { &hf_cemi_ack, { "Ack Wanted", "cemi.ack", FT_BOOLEAN, 8, TFS(&tfs_no_yes), 0x02, NULL, HFILL } }, { &hf_cemi_ce, { "Confirmation Error", "cemi.ce", FT_BOOLEAN, 8, TFS(&tfs_no_yes), 0x01, NULL, HFILL } }, { &hf_cemi_at, { "Address Type", "cemi.at", FT_UINT8, BASE_DEC, VALS( at_vals ), 0x80, NULL, HFILL } }, { &hf_cemi_hc, { "Hop Count", "cemi.hc", FT_UINT8, BASE_DEC, NULL, 0x70, NULL, HFILL } }, { &hf_cemi_eff, { "Extended Frame Format", "cemi.eff", FT_UINT8, BASE_HEX, NULL, 0x0F, NULL, HFILL } }, { &hf_cemi_sa, { "Source", "cemi.sa", FT_UINT16, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_da, { "Destination", "cemi.da", FT_UINT16, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_len, { "Length", "cemi.len", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_tpt, { "Packet Type", "cemi.tpt", FT_UINT8, BASE_DEC, VALS( pt_vals ), 0x80, NULL, HFILL } }, { &hf_cemi_tst, { "Sequence Type", "cemi.st", FT_UINT8, BASE_DEC, VALS( st_vals ), 0x40, NULL, HFILL } }, { &hf_cemi_num, { "Sequence Number", "cemi.num", FT_UINT8, BASE_DEC, NULL, 0x3C, NULL, HFILL } }, { &hf_cemi_tc, { "Service", "cemi.tc", FT_UINT8, BASE_HEX, VALS( tc_vals ), 0x03, NULL, HFILL } }, { &hf_cemi_ac, { "Service", "cemi.ac", FT_UINT16, BASE_HEX, VALS( ac_vals ), 0x03C0, NULL, HFILL } }, { &hf_cemi_ad, { "Data", "cemi.ad", FT_UINT8, BASE_HEX, NULL, 0x3F, NULL, HFILL } }, { &hf_cemi_ad_memory_length, { "Memory Length", "cemi.ad.ml", FT_UINT8, BASE_HEX, NULL, 0x3F, NULL, HFILL } }, { &hf_cemi_ad_channel, { "Channel", "cemi.ad.ch", FT_UINT8, BASE_HEX, NULL, 0x3F, NULL, HFILL } }, { &hf_cemi_ad_type, { "Data", "cemi.ad.type", FT_UINT8, BASE_HEX, NULL, 0x3F, NULL, HFILL } }, { &hf_cemi_ax, { "Service", "cemi.ax", FT_UINT16, BASE_HEX, VALS( ax_vals ), 0x03FF, NULL, HFILL } }, { &hf_cemi_pw, { "Writable", "cemi.pw", FT_UINT8, BASE_DEC, NULL, 0x80, NULL, HFILL } }, { &hf_cemi_pdt, { "Property Data Type", "cemi.pdt", FT_UINT8, BASE_HEX, VALS( pdt_vals ), 0x3F, NULL, HFILL } }, { &hf_cemi_me, { "Max Elements", "cemi.me", FT_UINT16, BASE_DEC, NULL, 0x0FFF, NULL, HFILL } }, { &hf_cemi_ra, { "Read Access", "cemi.ra", FT_UINT8, BASE_DEC, NULL, 0xF0, NULL, HFILL } }, { &hf_cemi_wa, { "Write Access", "cemi.wa", FT_UINT8, BASE_DEC, NULL, 0x0F, NULL, HFILL } }, { &hf_cemi_ext_oi, { "Object Instance", "cemi.oi", FT_UINT16, BASE_DEC, NULL, 0xFFF0, NULL, HFILL } }, { &hf_cemi_ext_pid, { "Property ID", "cemi.pid", FT_UINT16, BASE_DEC, NULL, 0x0FFF, NULL, HFILL } }, { &hf_cemi_ext_ne, { "Count", "cemi.n", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ext_sx, { "Index", "cemi.x", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ext_dt, { "Description Type", "cemi.dt", FT_UINT8, BASE_DEC, NULL, 0xF0, NULL, HFILL } }, { &hf_cemi_ext_px, { "Property Index", "cemi.px", FT_UINT16, BASE_DEC, NULL, 0x0FFF, NULL, HFILL } }, { &hf_cemi_ext_memory_length, { "Memory Length", "cemi.n", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_ext_memory_address, { "Memory Address", "cemi.x", FT_UINT16, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_memory_length, { "Memory Length", "cemi.n", FT_UINT8, BASE_DEC, NULL, 0x0F, NULL, HFILL } }, { &hf_cemi_memory_address, { "Memory Address", "cemi.x", FT_UINT16, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cemi_memory_address_ext, { "Memory Address Extension", "cemi.xx", FT_UINT8, BASE_HEX, NULL, 0xF0, NULL, HFILL } }, { &hf_cemi_level, { "Level", "cemi.level", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_snp_pid, { "Property ID", "cemi.pid", FT_UINT16, BASE_DEC, NULL, 0xFFF0, NULL, HFILL } }, { &hf_cemi_snp_reserved, { "Reserved", "cemi.reserved", FT_UINT16, BASE_DEC, NULL, 0x0F, NULL, HFILL } }, { &hf_cemi_dpt_major, { "Data Point Type Major", "cemi.pdt.major", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_dpt_minor, { "Data Point Type Minor", "cemi.pdt.minor", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cemi_scf, { "Security Control Field", "cemi.scf", FT_UINT8, BASE_HEX, VALS( scf_vals ), 0, NULL, HFILL } }, { &hf_cemi_scf_t, { "Tool Access", "cemi.scf.t", FT_UINT8, BASE_DEC, NULL, 0x80, NULL, HFILL } }, { &hf_cemi_scf_sai, { "Security Algorithm Identifier", "cemi.scf.sai", FT_UINT8, BASE_HEX, VALS( scf_sai_vals ), 0x70, NULL, HFILL } }, { &hf_cemi_scf_sbc, { "System Broadcast", "cemi.scf.sbc", FT_UINT8, BASE_DEC, NULL, 0x08, NULL, HFILL } }, { &hf_cemi_scf_svc, { "Service", "cemi.scf.svc", FT_UINT8, BASE_HEX, VALS( scf_svc_vals ), 0x07, NULL, HFILL } }, { &hf_cemi_adc_count, { "Count", "cemi.adc.n", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, }; /* Subtrees */ static gint *ett[] = { &ett_cemi, &ett_cemi_ai, &ett_cemi_aie, &ett_cemi_ctrl1, &ett_cemi_ctrl2, &ett_cemi_tpci, &ett_cemi_apci, &ett_cemi_range, &ett_cemi_pd, &ett_cemi_dpt, &ett_cemi_scf, &ett_cemi_decrypted }; proto_cemi = proto_register_protocol( "Common External Message Interface", "cEMI", "cemi" ); proto_register_field_array( proto_cemi, hf, array_length( hf ) ); proto_register_subtree_array( ett, array_length( ett ) ); register_dissector( "cemi", dissect_cemi, proto_cemi ); } void proto_reg_handoff_cemi( void ) { } /* * Editor modelines - https://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 2 * tab-width: 8 * indent-tabs-mode: nil * End: * * vi: set shiftwidth=2 tabstop=8 expandtab: * :indentSize=2:tabSize=8:noTabs=true: */