/* packet-cipmotion.c * Routines for CIP (Common Industrial Protocol) Motion dissection * CIP Motion Home: www.odva.org * * This dissector includes items from: * CIP Volume 9: CIP Motion, Edition 1.7 * * Copyright 2006-2007 * Benjamin M. Stocks * * Wireshark - Network traffic analyzer * By Gerald Combs * Copyright 1998 Gerald Combs * * SPDX-License-Identifier: GPL-2.0-or-later */ #include "config.h" #include #include #include "packet-cipmotion.h" #include "packet-cip.h" #include "packet-enip.h" void proto_register_cipmotion(void); /* The entry point to the actual dissection is: dissect_cipmotion */ void proto_reg_handoff_cipmotion(void); /* Protocol handle for CIP Motion */ static int proto_cipmotion = -1; static int proto_cipmotion3 = -1; /* Header field identifiers, these are registered in the * proto_register_cipmotion function along with the bites/bytes * they represent */ static int hf_cip_format = -1; static int hf_cip_revision = -1; static int hf_cip_class1_seqnum = -1; static int hf_configuration_block_format_rev = -1; static int hf_configuration_block_drive_power_struct_id = -1; static int hf_cip_updateid = -1; static int hf_cip_instance_cnt = -1; static int hf_cip_last_update = -1; static int hf_cip_node_status = -1; static int hf_cip_node_control = -1; static int hf_cip_node_control_remote = -1; static int hf_cip_node_control_sync = -1; static int hf_cip_node_data_valid = -1; static int hf_cip_node_fault_reset = -1; static int hf_cip_node_device_faulted = -1; static int hf_cip_time_data_set = -1; static int hf_cip_time_data_stamp = -1; static int hf_cip_time_data_offset = -1; static int hf_cip_time_data_diag = -1; static int hf_cip_time_data_time_diag = -1; static int hf_cip_cont_time_stamp = -1; static int hf_cip_cont_time_offset = -1; static int hf_cip_devc_time_stamp = -1; static int hf_cip_devc_time_offset = -1; static int hf_cip_lost_update = -1; static int hf_cip_late_update = -1; static int hf_cip_data_rx_time_stamp = -1; static int hf_cip_data_tx_time_stamp = -1; static int hf_cip_node_fltalarms = -1; static int hf_cip_motor_cntrl = -1; static int hf_cip_feedback = -1; static int hf_cip_feedback_mode = -1; static int hf_cip_feedback_data_type = -1; static int hf_connection_configuration_bits = -1; static int hf_connection_configuration_bits_power = -1; static int hf_connection_configuration_bits_safety_bit_valid = -1; static int hf_connection_configuration_bits_allow_network_safety = -1; static int hf_cip_axis_control = -1; static int hf_cip_control_status = -1; static int hf_cip_control_status_complete = -1; static int hf_cip_control_status_bus_up = -1; static int hf_cip_control_status_bus_unload = -1; static int hf_cip_control_status_power_loss = -1; static int hf_cip_axis_response = -1; static int hf_cip_axis_resp_stat = -1; static int hf_cip_cmd_data_pos_cmd = -1; static int hf_cip_cmd_data_vel_cmd = -1; static int hf_cip_cmd_data_acc_cmd = -1; static int hf_cip_cmd_data_trq_cmd = -1; static int hf_cip_cmd_data_unwind_cycle_count = -1; static int hf_cip_cmd_data_pos_displacement = -1; static int hf_cip_act_data_pos = -1; static int hf_cip_act_data_vel = -1; static int hf_cip_act_data_acc = -1; static int hf_cip_act_unwind_cycle_count = -1; static int hf_cip_act_pos_displacement = -1; static int hf_cip_sts_flt = -1; static int hf_cip_sts_alrm = -1; static int hf_cip_sts_sts = -1; static int hf_cip_sts_iosts = -1; static int hf_cip_sts_axis_safety = -1; static int hf_cip_intrp = -1; static int hf_cip_position_data_type = -1; static int hf_cip_axis_state = -1; static int hf_cip_evnt_ctrl_reg1_pos = -1; static int hf_cip_evnt_ctrl_reg1_neg = -1; static int hf_cip_evnt_ctrl_reg2_pos = -1; static int hf_cip_evnt_ctrl_reg2_neg = -1; static int hf_cip_evnt_ctrl_reg1_posrearm = -1; static int hf_cip_evnt_ctrl_reg1_negrearm = -1; static int hf_cip_evnt_ctrl_reg2_posrearm = -1; static int hf_cip_evnt_ctrl_reg2_negrearm = -1; static int hf_cip_evnt_ctrl_marker_pos = -1; static int hf_cip_evnt_ctrl_marker_neg = -1; static int hf_cip_evnt_ctrl_home_pos = -1; static int hf_cip_evnt_ctrl_home_neg = -1; static int hf_cip_evnt_ctrl_home_pp = -1; static int hf_cip_evnt_ctrl_home_pm = -1; static int hf_cip_evnt_ctrl_home_mp = -1; static int hf_cip_evnt_ctrl_home_mm = -1; static int hf_cip_evnt_ctrl_acks = -1; static int hf_cip_evnt_extend_format = -1; static int hf_cip_evnt_sts_reg1_pos = -1; static int hf_cip_evnt_sts_reg1_neg = -1; static int hf_cip_evnt_sts_reg2_pos = -1; static int hf_cip_evnt_sts_reg2_neg = -1; static int hf_cip_evnt_sts_reg1_posrearm = -1; static int hf_cip_evnt_sts_reg1_negrearm = -1; static int hf_cip_evnt_sts_reg2_posrearm = -1; static int hf_cip_evnt_sts_reg2_negrearm = -1; static int hf_cip_evnt_sts_marker_pos = -1; static int hf_cip_evnt_sts_marker_neg = -1; static int hf_cip_evnt_sts_home_pos = -1; static int hf_cip_evnt_sts_home_neg = -1; static int hf_cip_evnt_sts_home_pp = -1; static int hf_cip_evnt_sts_home_pm = -1; static int hf_cip_evnt_sts_home_mp = -1; static int hf_cip_evnt_sts_home_mm = -1; static int hf_cip_evnt_sts_nfs = -1; static int hf_cip_evnt_sts_stat = -1; static int hf_cip_evnt_type = -1; static int hf_cip_svc_code = -1; static int hf_cip_svc_sts = -1; static int hf_cip_svc_set_axis_attr_sts = -1; static int hf_cip_svc_get_axis_attr_sts = -1; static int hf_cip_svc_transction = -1; static int hf_cip_svc_ext_status = -1; static int hf_cip_svc_data = -1; static int hf_cip_ptp_grandmaster = -1; static int hf_cip_axis_alarm = -1; static int hf_cip_axis_fault = -1; static int hf_cip_axis_sts_local_ctrl = -1; static int hf_cip_axis_sts_alarm = -1; static int hf_cip_axis_sts_dc_bus = -1; static int hf_cip_axis_sts_pwr_struct = -1; static int hf_cip_axis_sts_flux_up = -1; static int hf_cip_axis_sts_tracking = -1; static int hf_cip_axis_sts_pos_lock = -1; static int hf_cip_axis_sts_vel_lock = -1; static int hf_cip_axis_sts_vel_standstill = -1; static int hf_cip_axis_sts_vel_threshold = -1; static int hf_cip_axis_sts_vel_limit = -1; static int hf_cip_axis_sts_acc_limit = -1; static int hf_cip_axis_sts_dec_limit = -1; static int hf_cip_axis_sts_torque_threshold = -1; static int hf_cip_axis_sts_torque_limit = -1; static int hf_cip_axis_sts_cur_limit = -1; static int hf_cip_axis_sts_therm_limit = -1; static int hf_cip_axis_sts_feedback_integ = -1; static int hf_cip_axis_sts_shutdown = -1; static int hf_cip_axis_sts_in_process = -1; static int hf_cip_axis_sts_dc_bus_unload = -1; static int hf_cip_axis_sts_ac_pwr_loss = -1; static int hf_cip_axis_sts_pos_cntrl_mode = -1; static int hf_cip_axis_sts_vel_cntrl_mode = -1; static int hf_cip_axis_sts_trq_cntrl_mode = -1; static int hf_cip_axis_status2 = -1; static int hf_cip_axis_sts2_motor = -1; static int hf_cip_axis_sts2_regenerate = -1; static int hf_cip_axis_sts2_ride_thru = -1; static int hf_cip_axis_sts2_ac_line_sync = -1; static int hf_cip_axis_sts2_bus_volt_lock = -1; static int hf_cip_axis_sts2_react_pwr_only = -1; static int hf_cip_axis_sts2_volt_ctrl_mode = -1; static int hf_cip_axis_sts2_pwr_loss = -1; static int hf_cip_axis_sts2_ac_volt_sag = -1; static int hf_cip_axis_sts2_ac_phase_loss = -1; static int hf_cip_axis_sts2_ac_freq_change = -1; static int hf_cip_axis_sts2_ac_sync_loss = -1; static int hf_cip_axis_sts2_single_phase = -1; static int hf_cip_axis_sts2_bus_volt_limit = -1; static int hf_cip_axis_sts2_bus_volt_rate_limit = -1; static int hf_cip_axis_sts2_active_current_rate_limit = -1; static int hf_cip_axis_sts2_reactive_current_rate_limit = -1; static int hf_cip_axis_sts2_reactive_pwr_limit = -1; static int hf_cip_axis_sts2_reactive_pwr_rate_limit = -1; static int hf_cip_axis_sts2_active_current_limit = -1; static int hf_cip_axis_sts2_reactive_current_limit = -1; static int hf_cip_axis_sts2_motor_pwr_limit = -1; static int hf_cip_axis_sts2_regen_pwr_limit = -1; static int hf_cip_axis_sts2_convert_therm_limit = -1; static int hf_cip_cyclic_wrt_data = -1; static int hf_cip_cyclic_rd_data = -1; static int hf_cip_cyclic_write_blk = -1; static int hf_cip_cyclic_read_blk = -1; static int hf_cip_cyclic_write_sts = -1; static int hf_cip_cyclic_read_sts = -1; static int hf_cip_attribute_data = -1; static int hf_cip_event_checking = -1; static int hf_cip_event_ack = -1; static int hf_cip_event_status = -1; static int hf_cip_event_id = -1; static int hf_cip_event_pos = -1; static int hf_cip_event_ts = -1; static int hf_cip_pos_cmd = -1; static int hf_cip_pos_cmd_int = -1; static int hf_cip_vel_cmd = -1; static int hf_cip_accel_cmd = -1; static int hf_cip_trq_cmd = -1; static int hf_cip_pos_trim = -1; static int hf_cip_vel_trim = -1; static int hf_cip_accel_trim = -1; static int hf_cip_trq_trim = -1; static int hf_cip_act_pos = -1; static int hf_cip_act_pos_64 = -1; static int hf_cip_act_vel = -1; static int hf_cip_act_accel = -1; static int hf_cip_fault_type = -1; static int hf_cip_fault_sub_code = -1; static int hf_cip_fault_action = -1; static int hf_cip_fault_time_stamp = -1; static int hf_cip_alarm_type = -1; static int hf_cip_alarm_sub_code = -1; static int hf_cip_alarm_state = -1; static int hf_cip_alarm_time_stamp = -1; static int hf_cip_axis_status = -1; static int hf_cip_axis_status_mfg = -1; static int hf_cip_axis_io_status = -1; static int hf_cip_axis_io_status_mfg = -1; static int hf_cip_axis_safety_status = -1; static int hf_cip_axis_safety_status_mfg = -1; static int hf_cip_axis_safety_state = -1; static int hf_cip_cmd_data_set = -1; static int hf_cip_act_data_set = -1; static int hf_cip_sts_data_set = -1; static int hf_cip_group_sync = -1; static int hf_cip_command_control = -1; static int hf_get_axis_attr_list_attribute_cnt = -1; static int hf_get_axis_attr_list_attribute_id = -1; static int hf_get_axis_attr_list_dimension = -1; static int hf_get_axis_attr_list_element_size = -1; static int hf_get_axis_attr_list_start_index = -1; static int hf_get_axis_attr_list_data_elements = -1; static int hf_set_axis_attr_list_attribute_cnt = -1; static int hf_set_axis_attr_list_attribute_id = -1; static int hf_set_axis_attr_list_dimension = -1; static int hf_set_axis_attr_list_element_size = -1; static int hf_set_axis_attr_list_start_index = -1; static int hf_set_axis_attr_list_data_elements = -1; static int hf_set_cyclic_list_attribute_cnt = -1; static int hf_set_cyclic_list_attribute_id = -1; static int hf_set_cyclic_list_read_block_id = -1; static int hf_set_cyclic_list_attr_sts = -1; static int hf_var_devce_instance = -1; static int hf_var_devce_instance_block_size = -1; static int hf_var_devce_cyclic_block_size = -1; static int hf_var_devce_cyclic_data_block_size = -1; static int hf_var_devce_cyclic_rw_block_size = -1; static int hf_var_devce_event_block_size = -1; static int hf_var_devce_service_block_size = -1; static int hf_cip_data = -1; /* Subtree pointers for the dissection */ static gint ett_cipmotion = -1; static gint ett_cont_dev_header = -1; static gint ett_control_status = -1; static gint ett_node_control = -1; static gint ett_node_status = -1; static gint ett_time_data_set = -1; static gint ett_inst_data_header = -1; static gint ett_cyclic_data_block = -1; static gint ett_cyclic_command_data = -1; static gint ett_feedback_mode = -1; static gint ett_connection_configuration_bits = -1; static gint ett_control_mode = -1; static gint ett_feedback_config = -1; static gint ett_command_data_set = -1; static gint ett_actual_data_set = -1; static gint ett_status_data_set = -1; static gint ett_interp_control = -1; static gint ett_cyclic_rd_wt = -1; static gint ett_event = -1; static gint ett_event_check_ctrl = -1; static gint ett_event_check_sts = -1; static gint ett_service = -1; static gint ett_get_axis_attribute = -1; static gint ett_set_axis_attribute = -1; static gint ett_get_axis_attr_list = -1; static gint ett_set_axis_attr_list = -1; static gint ett_set_cyclic_list = -1; static gint ett_group_sync = -1; static gint ett_axis_status_set = -1; static gint ett_command_control = -1; static gint ett_configuration_block = -1; static expert_field ei_format_rev_conn_pt = EI_INIT; static dissector_handle_t cipmotion_handle; static dissector_handle_t cipmotion3_handle; static gboolean display_full_attribute_data = FALSE; /* These are the BITMASKS for the Time Data Set header field */ #define TIME_DATA_SET_TIME_STAMP 0x1 #define TIME_DATA_SET_TIME_OFFSET 0x2 #define TIME_DATA_SET_UPDATE_DIAGNOSTICS 0x4 #define TIME_DATA_SET_TIME_DIAGNOSTICS 0x8 /* These are the BITMASKS for the Command Data Set cyclic field */ #define COMMAND_DATA_SET_POSITION 0x01 #define COMMAND_DATA_SET_VELOCITY 0x02 #define COMMAND_DATA_SET_ACCELERATION 0x04 #define COMMAND_DATA_SET_TORQUE 0x08 #define COMMAND_DATA_SET_UNWIND_CYCLE_COUNT 0x40 #define COMMAND_DATA_SET_POSITION_DISPLACE 0x80 /* These are the BITMASKS for the Actual Data Set cyclic field */ #define ACTUAL_DATA_SET_POSITION 0x01 #define ACTUAL_DATA_SET_VELOCITY 0x02 #define ACTUAL_DATA_SET_ACCELERATION 0x04 #define ACTUAL_DATA_SET_UNWIND_CYCLE_COUNT 0x40 #define ACTUAL_DATA_SET_POSITION_DISPLACE 0x80 /* These are the BITMASKS for the Status Data Set cyclic field */ #define STATUS_DATA_SET_AXIS_FAULT 0x01 #define STATUS_DATA_SET_AXIS_ALARM 0x02 #define STATUS_DATA_SET_AXIS_STATUS 0x04 #define STATUS_DATA_SET_AXIS_IO_STATUS 0x08 #define STATUS_DATA_SET_AXIS_SAFETY 0x10 /* These are the BITMASKS for the Command Control cyclic field */ #define COMMAND_CONTROL_TARGET_UPDATE 0x03 #define COMMAND_CONTROL_POSITION_DATA_TYPE 0x0C /* These are the VALUES of the connection format header field of the * CIP Motion protocol */ #define FORMAT_FIXED_CONTROL_TO_DEVICE 2 #define FORMAT_FIXED_DEVICE_TO_CONTROL 3 #define FORMAT_VAR_CONTROL_TO_DEVICE 6 #define FORMAT_VAR_DEVICE_TO_CONTROL 7 #define FEEDBACK_MODE_BITS 0x0F #define FEEDBACK_DATA_TYPE_BITS 0x30 /* Translate function to string - connection format values */ static const value_string cip_con_format_vals[] = { { FORMAT_FIXED_CONTROL_TO_DEVICE, "Fixed Controller-to-Device" }, { FORMAT_FIXED_DEVICE_TO_CONTROL, "Fixed Device-to-Controller" }, { FORMAT_VAR_CONTROL_TO_DEVICE, "Variable Controller-to-Device" }, { FORMAT_VAR_DEVICE_TO_CONTROL, "Variable Device-to-Controller" }, { 0, NULL } }; /* Translate function to string - motor control mode values */ static const value_string cip_motor_control_vals[] = { { 0, "No Control" }, { 1, "Position Control" }, { 2, "Velocity Control" }, { 3, "Acceleration Control" }, { 4, "Torque Control" }, { 0, NULL } }; /* Translate function to string - feedback mode values */ static const value_string cip_feedback_mode_vals[] = { { 0, "No Feedback" }, { 1, "Master Feedback" }, { 2, "Motor Feedback" }, { 3, "Load Feedback" }, { 4, "Dual Feedback" }, { 0, NULL } }; static const value_string cip_feedback_type_vals[] = { { 0, "DINT" }, { 1, "LINT" }, { 0, NULL } }; /* Translate function to string - axis control values */ static const value_string cip_axis_control_vals[] = { { 0, "No Request" }, { 1, "Enable Request" }, { 2, "Disable Request" }, { 3, "Shutdown Request" }, { 4, "Shutdown Reset Request" }, { 5, "Abort Request" }, { 6, "Fault Reset Request" }, { 7, "Stop Process" }, { 8, "Change Actual Pos" }, { 9, "Change Command Pos Ref" }, { 127, "Cancel Request" }, { 0, NULL } }; /* Translate function to string - group sync Status */ static const value_string cip_sync_status_vals[] = { { 0, "Synchronized" }, { 1, "Not Synchronized" }, { 2, "Wrong Grandmaster" }, { 3, "Clock Skew Detected" }, { 0, NULL } }; /* Translate function to string - command target update */ static const value_string cip_interpolation_vals[] = { { 0, "Immediate" }, { 1, "Extrapolate (+1)" }, { 2, "Interpolate (+2)" }, { 0, NULL } }; /* These are the VALUES for the Command Position Data Type */ #define POSITION_DATA_LREAL 0x00 #define POSITION_DATA_DINT 0x01 /* Translate function to string - position data type */ static const value_string cip_pos_data_type_vals[] = { { POSITION_DATA_LREAL, "LREAL (64-bit Float)" }, { POSITION_DATA_DINT, "DINT (32-bit Integer)" }, { 0, NULL } }; /* Translate function to string - axis response values */ static const value_string cip_axis_response_vals[] = { { 0, "No Acknowledge" }, { 1, "Enable Acknowledge" }, { 2, "Disable Acknowledge" }, { 3, "Shutdown Acknowledge" }, { 4, "Shutdown Reset Acknowledge" }, { 5, "Abort Acknowledge" }, { 6, "Fault Reset Acknowledge" }, { 7, "Stop Process Acknowledge" }, { 8, "Change Actual Position Reference Acknowledge" }, { 9, "Change Command Position Reference Acknowledge" }, { 127, "Cancel Acknowledge" }, { 0, NULL } }; /* Translate function to string - axis state values */ static const value_string cip_axis_state_vals[] = { { 0, "Initializing" }, { 1, "Pre-Charge" }, { 2, "Stopped" }, { 3, "Starting" }, { 4, "Running" }, { 5, "Testing" }, { 6, "Stopping" }, { 7, "Aborting" }, { 8, "Major Faulted" }, { 9, "Start Inhibited" }, { 10, "Shutdown" }, { 0, NULL } }; /* Translate function to string - event type values */ static const value_string cip_event_type_vals[] = { { 0, "Registration 1 Positive Edge" }, { 1, "Registration 1 Negative Edge" }, { 2, "Registration 2 Positive Edge" }, { 3, "Registration 2 Negative Edge" }, { 4, "Marker Positive Edge" }, { 5, "Marker Negative Edge" }, { 6, "Home Switch Positive Edge" }, { 7, "Home Switch Negative Edge" }, { 8, "Home Switch Marker ++" }, { 9, "Home Switch Marker +-" }, { 10, "Home Switch Marker -+" }, { 11, "Home Switch Marker --" }, { 0, NULL } }; #define SC_GET_AXIS_ATTRIBUTE_LIST 0x4B #define SC_SET_AXIS_ATTRIBUTE_LIST 0x4C #define SC_SET_CYCLIC_WRITE_LIST 0x4D #define SC_SET_CYCLIC_READ_LIST 0x4E #define SC_RUN_MOTOR_TEST 0x4F #define SC_GET_MOTOR_TEST_DATA 0x50 #define SC_RUN_INERTIA_TEST 0x51 #define SC_GET_INERTIA_TEST_DATA 0x52 #define SC_RUN_HOOKUP_TEST 0x53 #define SC_GET_HOOKUP_TEST_DATA 0x54 /* Translate function to string - CIP Service codes */ static const value_string cip_sc_vals[] = { GENERIC_SC_LIST { SC_GET_AXIS_ATTRIBUTE_LIST, "Get Axis Attribute List" }, { SC_SET_AXIS_ATTRIBUTE_LIST, "Set Axis Attribute List" }, { SC_SET_CYCLIC_WRITE_LIST, "Set Cyclic Write List" }, { SC_SET_CYCLIC_READ_LIST, "Set Cyclic Read List" }, { SC_RUN_MOTOR_TEST, "Run Motor Test" }, { SC_GET_MOTOR_TEST_DATA, "Get Motor Test Data" }, { SC_RUN_INERTIA_TEST, "Run Inertia Test" }, { SC_GET_INERTIA_TEST_DATA, "Get Inertia Test Data" }, { SC_RUN_HOOKUP_TEST, "Run Hookup Test" }, { SC_GET_HOOKUP_TEST_DATA, "Get Hookup Test Data" }, { 0, NULL } }; static int dissect_axis_status(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_axis_sts_local_ctrl, &hf_cip_axis_sts_alarm, &hf_cip_axis_sts_dc_bus, &hf_cip_axis_sts_pwr_struct, &hf_cip_axis_sts_flux_up, &hf_cip_axis_sts_tracking, &hf_cip_axis_sts_pos_lock, &hf_cip_axis_sts_vel_lock, &hf_cip_axis_sts_vel_standstill, &hf_cip_axis_sts_vel_threshold, &hf_cip_axis_sts_vel_limit, &hf_cip_axis_sts_acc_limit, &hf_cip_axis_sts_dec_limit, &hf_cip_axis_sts_torque_threshold, &hf_cip_axis_sts_torque_limit, &hf_cip_axis_sts_cur_limit, &hf_cip_axis_sts_therm_limit, &hf_cip_axis_sts_feedback_integ, &hf_cip_axis_sts_shutdown, &hf_cip_axis_sts_in_process, &hf_cip_axis_sts_dc_bus_unload, &hf_cip_axis_sts_ac_pwr_loss, &hf_cip_axis_sts_pos_cntrl_mode, &hf_cip_axis_sts_vel_cntrl_mode, &hf_cip_axis_sts_trq_cntrl_mode, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_axis_status, ett_axis_status_set, bits, ENC_LITTLE_ENDIAN); return 4; } static int dissect_axis_status2(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_axis_sts2_motor, &hf_cip_axis_sts2_regenerate, &hf_cip_axis_sts2_ride_thru, &hf_cip_axis_sts2_ac_line_sync, &hf_cip_axis_sts2_bus_volt_lock, &hf_cip_axis_sts2_react_pwr_only, &hf_cip_axis_sts2_volt_ctrl_mode, &hf_cip_axis_sts2_pwr_loss, &hf_cip_axis_sts2_ac_volt_sag, &hf_cip_axis_sts2_ac_phase_loss, &hf_cip_axis_sts2_ac_freq_change, &hf_cip_axis_sts2_ac_sync_loss, &hf_cip_axis_sts2_single_phase, &hf_cip_axis_sts2_bus_volt_limit, &hf_cip_axis_sts2_bus_volt_rate_limit, &hf_cip_axis_sts2_active_current_rate_limit, &hf_cip_axis_sts2_reactive_current_rate_limit, &hf_cip_axis_sts2_reactive_pwr_limit, &hf_cip_axis_sts2_reactive_pwr_rate_limit, &hf_cip_axis_sts2_active_current_limit, &hf_cip_axis_sts2_reactive_current_limit, &hf_cip_axis_sts2_motor_pwr_limit, &hf_cip_axis_sts2_regen_pwr_limit, &hf_cip_axis_sts2_convert_therm_limit, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_axis_status2, ett_axis_status_set, bits, ENC_LITTLE_ENDIAN); return 4; } static int dissect_event_checking_control(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_evnt_ctrl_reg1_pos, &hf_cip_evnt_ctrl_reg1_neg, &hf_cip_evnt_ctrl_reg2_pos, &hf_cip_evnt_ctrl_reg2_neg, &hf_cip_evnt_ctrl_reg1_posrearm, &hf_cip_evnt_ctrl_reg1_negrearm, &hf_cip_evnt_ctrl_reg2_posrearm, &hf_cip_evnt_ctrl_reg2_negrearm, &hf_cip_evnt_ctrl_marker_pos, &hf_cip_evnt_ctrl_marker_neg, &hf_cip_evnt_ctrl_home_pos, &hf_cip_evnt_ctrl_home_neg, &hf_cip_evnt_ctrl_home_pp, &hf_cip_evnt_ctrl_home_pm, &hf_cip_evnt_ctrl_home_mp, &hf_cip_evnt_ctrl_home_mm, &hf_cip_evnt_ctrl_acks, // The dissector will indicate if the protocol is requesting an extended event format but will not dissect it. &hf_cip_evnt_extend_format, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_event_checking, ett_event_check_ctrl, bits, ENC_LITTLE_ENDIAN); return 4; } static int dissect_event_checking_status(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_evnt_sts_reg1_pos, &hf_cip_evnt_sts_reg1_neg, &hf_cip_evnt_sts_reg2_pos, &hf_cip_evnt_sts_reg2_neg, &hf_cip_evnt_sts_reg1_posrearm, &hf_cip_evnt_sts_reg1_negrearm, &hf_cip_evnt_sts_reg2_posrearm, &hf_cip_evnt_sts_reg2_negrearm, &hf_cip_evnt_sts_marker_pos, &hf_cip_evnt_sts_marker_neg, &hf_cip_evnt_sts_home_pos, &hf_cip_evnt_sts_home_neg, &hf_cip_evnt_sts_home_pp, &hf_cip_evnt_sts_home_pm, &hf_cip_evnt_sts_home_mp, &hf_cip_evnt_sts_home_mm, &hf_cip_evnt_sts_nfs, // The dissector will indicate if the protocol is requesting an extended event format but will not dissect it. &hf_cip_evnt_extend_format, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_event_status, ett_event_check_sts, bits, ENC_LITTLE_ENDIAN); return 4; } static int dissect_actual_data_set_bits(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_act_data_pos, &hf_cip_act_data_vel, &hf_cip_act_data_acc, &hf_cip_act_unwind_cycle_count, &hf_cip_act_pos_displacement, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_act_data_set, ett_actual_data_set, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_command_data_set_bits(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_cmd_data_pos_cmd, &hf_cip_cmd_data_vel_cmd, &hf_cip_cmd_data_acc_cmd, &hf_cip_cmd_data_trq_cmd, &hf_cip_cmd_data_unwind_cycle_count, &hf_cip_cmd_data_pos_displacement, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_cmd_data_set, ett_command_data_set, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_command_control(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_intrp, &hf_cip_position_data_type, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_command_control, ett_command_control, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_status_data_set_bits(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_sts_flt, &hf_cip_sts_alrm, &hf_cip_sts_sts, &hf_cip_sts_iosts, &hf_cip_sts_axis_safety, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_sts_data_set, ett_status_data_set, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_node_control(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_node_control_remote, &hf_cip_node_control_sync, &hf_cip_node_data_valid, &hf_cip_node_fault_reset, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_node_control, ett_node_control, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_node_status(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_node_control_remote, &hf_cip_node_control_sync, &hf_cip_node_data_valid, &hf_cip_node_device_faulted, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_node_status, ett_node_status, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_time_data_set(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_time_data_stamp, &hf_cip_time_data_offset, &hf_cip_time_data_diag, &hf_cip_time_data_time_diag, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_time_data_set, ett_time_data_set, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_control_status(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_control_status_complete, &hf_cip_control_status_bus_up, &hf_cip_control_status_bus_unload, &hf_cip_control_status_power_loss, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_control_status, ett_control_status, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_feedback_mode(packet_info *pinfo _U_, proto_tree *tree, proto_item *item _U_, tvbuff_t *tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_cip_feedback_mode, &hf_cip_feedback_data_type, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_cip_feedback, ett_feedback_mode, bits, ENC_LITTLE_ENDIAN); return 1; } static int dissect_connection_configuration_bits(packet_info* pinfo _U_, proto_tree* tree, proto_item* item _U_, tvbuff_t* tvb, int offset, int total_len _U_) { static int* const bits[] = { &hf_connection_configuration_bits_power, &hf_connection_configuration_bits_safety_bit_valid, &hf_connection_configuration_bits_allow_network_safety, NULL }; proto_tree_add_bitmask(tree, tvb, offset, hf_connection_configuration_bits, ett_connection_configuration_bits, bits, ENC_LITTLE_ENDIAN); return 1; } attribute_info_t cip_motion_attribute_vals[] = { { CI_CLS_MOTION, CIP_ATTR_CLASS, 14, -1, "Node Control", cip_dissector_func, NULL, dissect_node_control }, { CI_CLS_MOTION, CIP_ATTR_CLASS, 15, -1, "Node Status", cip_dissector_func, NULL, dissect_node_status }, { CI_CLS_MOTION, CIP_ATTR_CLASS, 31, -1, "Time Data Set", cip_dissector_func, NULL, dissect_time_data_set }, { CI_CLS_MOTION, CIP_ATTR_CLASS, 34, -1, "Drive Power Structure Class ID", cip_udint, &hf_configuration_block_drive_power_struct_id, NULL }, { CI_CLS_MOTION, CIP_ATTR_CLASS, 36, -1, "Connection Configuration Bits", cip_dissector_func, NULL, dissect_connection_configuration_bits }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 40, -1, "Control Mode", cip_usint, &hf_cip_motor_cntrl, NULL }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 42, -1, "Feedback Mode", cip_dissector_func, NULL, dissect_feedback_mode }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 60, -1, "Event Checking Control", cip_dissector_func, NULL, dissect_event_checking_control }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 61, -1, "Event Checking Status", cip_dissector_func, NULL, dissect_event_checking_status }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 89, -1, "Control Status", cip_dissector_func, NULL, dissect_control_status }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 90, -1, "Actual Data Set", cip_dissector_func, NULL, dissect_actual_data_set_bits }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 91, -1, "Command Data Set", cip_dissector_func, NULL, dissect_command_data_set_bits }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 92, -1, "Command Control", cip_dissector_func, NULL, dissect_command_control }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 94, -1, "Status Data Set", cip_dissector_func, NULL, dissect_status_data_set_bits }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 431, -1, "Position Trim", cip_dint, &hf_cip_pos_trim, NULL }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 451, -1, "Velocity Trim", cip_real, &hf_cip_vel_trim, NULL }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 481, -1, "Acceleration Trim", cip_real, &hf_cip_accel_trim, NULL }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 491, -1, "Torque Trim", cip_real, &hf_cip_trq_trim, NULL }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 651, -1, "Axis Status", cip_dissector_func, NULL, dissect_axis_status }, { CI_CLS_MOTION, CIP_ATTR_INSTANCE, 740, -1, "Axis Status 2", cip_dissector_func, NULL, dissect_axis_status2 }, }; /* * Function name: dissect_cmd_data_set * * Purpose: Dissect the "Cyclic Command Data" of a Controller-to-Device format message * * Based on the Command Data Set bits of the Cyclic Command Data Block header, display * any of those command values. * * Returns: The number of bytes in the cyclic data used */ static guint32 dissect_cmd_data_set(guint32 cmd_data_set, proto_tree* parent_tree, tvbuff_t* tvb, guint32 offset, gboolean lreal_pos) { // If no Command Data Set bits are set, then we don't need to display any additional data. if (cmd_data_set == 0) { return 0; } guint32 bytes_used = 0; proto_item* item; proto_tree* tree = proto_tree_add_subtree(parent_tree, tvb, offset, 0, ett_cyclic_command_data, &item, "Cyclic Command Data"); /* The order of these if statements is VERY important, this is the order the values will * appear in the cyclic data */ if ( (cmd_data_set & COMMAND_DATA_SET_POSITION) == COMMAND_DATA_SET_POSITION ) { /* Based on the Command Position Data Type value embedded in the Command Control * header field the position is either 64-bit floating or 32-bit integer */ if (lreal_pos) { /* Display the command data set position command value */ proto_tree_add_item(tree, hf_cip_pos_cmd, tvb, offset + bytes_used, 8, ENC_LITTLE_ENDIAN ); bytes_used += 8; } else { /* Display the command data set position command value */ proto_tree_add_item(tree, hf_cip_pos_cmd_int, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } } if ( (cmd_data_set & COMMAND_DATA_SET_VELOCITY) == COMMAND_DATA_SET_VELOCITY ) { /* Display the command data set velocity command value */ proto_tree_add_item(tree, hf_cip_vel_cmd, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } if ( (cmd_data_set & COMMAND_DATA_SET_ACCELERATION) == COMMAND_DATA_SET_ACCELERATION ) { /* Display the command data set acceleration command value */ proto_tree_add_item(tree, hf_cip_accel_cmd, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } if ( (cmd_data_set & COMMAND_DATA_SET_TORQUE) == COMMAND_DATA_SET_TORQUE ) { /* Display the command data set torque command value */ proto_tree_add_item(tree, hf_cip_trq_cmd, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } proto_item_set_len(item, bytes_used); return bytes_used; } /* * Function name: dissect_act_data_set * * Purpose: Dissect the "Cyclic Actual Data" of a Device-to-Controller format message * * Based on the Actual Data Set bits of the "Cyclic Actual Data Block" header, display * any of those feedback values. * * Returns: The number of bytes in the cyclic data used */ static guint32 dissect_act_data_set(guint32 act_data_set, proto_tree* parent_tree, tvbuff_t* tvb, guint32 offset, guint8 feedback_mode) { // If no Actual Data Set bits are set, then we don't need to display any additional data. if (act_data_set == 0) { return 0; } guint32 bytes_used = 0; proto_item* item; proto_tree* tree = proto_tree_add_subtree(parent_tree, tvb, offset, 0, ett_cyclic_command_data, &item, "Cyclic Actual Data"); /* The order of these if statements is VERY important, this is the order the values will * appear in the cyclic data */ if ( (act_data_set & ACTUAL_DATA_SET_POSITION) == ACTUAL_DATA_SET_POSITION ) { /* Display the actual data set position feedback value in either 32 or 64 bit */ gboolean is_64_bit_position = (feedback_mode & FEEDBACK_DATA_TYPE_BITS) == 0x10; if (is_64_bit_position) { proto_tree_add_item(tree, hf_cip_act_pos_64, tvb, offset + bytes_used, 8, ENC_LITTLE_ENDIAN); bytes_used += 8; } else { proto_tree_add_item(tree, hf_cip_act_pos, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; } } if ( (act_data_set & ACTUAL_DATA_SET_VELOCITY) == ACTUAL_DATA_SET_VELOCITY ) { /* Display the actual data set velocity feedback value */ proto_tree_add_item(tree, hf_cip_act_vel, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } if ( (act_data_set & ACTUAL_DATA_SET_ACCELERATION) == ACTUAL_DATA_SET_ACCELERATION ) { /* Display the actual data set acceleration feedback value */ proto_tree_add_item(tree, hf_cip_act_accel, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN ); bytes_used += 4; } proto_item_set_len(item, bytes_used); return bytes_used; } /* * Function name: dissect_status_data_set * * Purpose: Dissect the "Cyclic Status Data" of a Device-to-Controller format message * * Based on the Status Data Set bits of the "Cyclic Actual Data Block" header, display * any of those status values. * * Returns: The number of bytes in the cyclic data used */ static guint32 dissect_status_data_set(guint32 status_data_set, proto_tree* parent_tree, tvbuff_t* tvb, guint32 offset) { // If no Status Data Set bits are set, then we don't need to display any additional data. if (status_data_set == 0) { return 0; } guint32 bytes_used = 0; proto_item* item; proto_tree* tree = proto_tree_add_subtree(parent_tree, tvb, offset, 0, ett_cyclic_command_data, &item, "Cyclic Status Data"); /* The order of these if statements is VERY important, this is the order the values will * appear in the cyclic data */ if ( (status_data_set & STATUS_DATA_SET_AXIS_FAULT) == STATUS_DATA_SET_AXIS_FAULT ) { /* Display the various fault codes from the device */ proto_tree_add_item(tree, hf_cip_fault_type, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_axis_fault, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_fault_sub_code, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_fault_action, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_fault_time_stamp, tvb, offset + bytes_used, 8, ENC_LITTLE_ENDIAN); bytes_used += 8; } if ( (status_data_set & STATUS_DATA_SET_AXIS_ALARM) == STATUS_DATA_SET_AXIS_ALARM ) { /* Display the various alarm codes from the device */ proto_tree_add_item(tree, hf_cip_alarm_type, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_axis_alarm, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_alarm_sub_code, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_alarm_state, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; proto_tree_add_item(tree, hf_cip_alarm_time_stamp, tvb, offset + bytes_used, 8, ENC_LITTLE_ENDIAN); bytes_used += 8; } if ( (status_data_set & STATUS_DATA_SET_AXIS_STATUS) == STATUS_DATA_SET_AXIS_STATUS ) { /* Display the various axis state values from the device */ bytes_used += dissect_axis_status(NULL, tree, NULL, tvb, offset + bytes_used, 4); proto_tree_add_item(tree, hf_cip_axis_status_mfg, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; } if ( (status_data_set & STATUS_DATA_SET_AXIS_IO_STATUS) == STATUS_DATA_SET_AXIS_IO_STATUS ) { proto_tree_add_item(tree, hf_cip_axis_io_status, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; proto_tree_add_item(tree, hf_cip_axis_io_status_mfg, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; } if ( (status_data_set & STATUS_DATA_SET_AXIS_SAFETY) == STATUS_DATA_SET_AXIS_SAFETY ) { proto_tree_add_item(tree, hf_cip_axis_safety_status, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; proto_tree_add_item(tree, hf_cip_axis_safety_status_mfg, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; proto_tree_add_item(tree, hf_cip_axis_safety_state, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 4; } proto_item_set_len(item, bytes_used); return bytes_used; } /* * Function name: dissect_cntr_cyclic * * Purpose: Dissect the "Cyclic Command Data Block" of a Controller-to-Device format message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_cntr_cyclic(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { /* Create the tree for the entire instance data header */ proto_tree* header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_cyclic_data_block, NULL, "Cyclic Command Data Block"); proto_tree_add_item(header_tree, hf_cip_motor_cntrl, tvb, offset, 1, ENC_LITTLE_ENDIAN); dissect_feedback_mode(NULL, header_tree, NULL, tvb, offset + 1, 1); proto_tree_add_item(header_tree, hf_cip_axis_control, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); dissect_control_status(NULL, header_tree, NULL, tvb, offset + 3, 1); dissect_command_data_set_bits(NULL, header_tree, NULL, tvb, offset + 4, 1); dissect_actual_data_set_bits(NULL, header_tree, NULL, tvb, offset + 5, 1); dissect_status_data_set_bits(NULL, header_tree, NULL, tvb, offset + 6, 1); dissect_command_control(NULL, header_tree, NULL, tvb, offset + 7, 1); guint32 bytes_used = 8; /* Determine if the dissector should be using an LREAL or DINT for position */ guint8 command_control = tvb_get_guint8(tvb, offset + 7); gboolean lreal_pos = ((command_control & COMMAND_CONTROL_POSITION_DATA_TYPE) == POSITION_DATA_LREAL); /* Cyclic Command Data: Display the command data values from the cyclic data payload, the * cyclic data starts immediately after the interpolation control field in the controller to device * direction */ guint32 command_data_set = tvb_get_guint8(tvb, offset + 4); bytes_used += dissect_cmd_data_set(command_data_set, header_tree, tvb, offset + bytes_used, lreal_pos); /* Return the offset to the next byte in the message */ return offset + bytes_used; } /* * Function name: dissect_device_cyclic * * Purpose: Dissect the "Cyclic Actual Data Block" of a Device-to-Controller format message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_device_cyclic(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { /* Create the tree for the entire instance data header */ proto_tree* header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_cyclic_data_block, NULL, "Cyclic Actual Data Block"); proto_tree_add_item(header_tree, hf_cip_motor_cntrl, tvb, offset, 1, ENC_LITTLE_ENDIAN); dissect_feedback_mode(NULL, header_tree, NULL, tvb, offset + 1, 1); proto_tree_add_item(header_tree, hf_cip_axis_response, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(header_tree, hf_cip_axis_resp_stat, tvb, offset + 3, 1, ENC_LITTLE_ENDIAN); dissect_actual_data_set_bits(NULL, header_tree, NULL, tvb, offset + 5, 1); dissect_status_data_set_bits(NULL, header_tree, NULL, tvb, offset + 6, 1); proto_tree_add_item(header_tree, hf_cip_axis_state, tvb, offset + 7, 1, ENC_LITTLE_ENDIAN); guint32 bytes_used = 8; /* Display the "Cyclic Actual Data" values from the cyclic data payload. */ guint8 feedback_mode = tvb_get_guint8(tvb, offset + 1); guint8 actual_data_set = tvb_get_guint8(tvb, offset + 5); bytes_used += dissect_act_data_set(actual_data_set, header_tree, tvb, offset + bytes_used, feedback_mode); /* Display the "Cyclic Status Data" values from the cyclic data payload. */ guint8 status_data_set = tvb_get_guint8(tvb, offset + 6); bytes_used += dissect_status_data_set(status_data_set, header_tree, tvb, offset + bytes_used); /* Return the offset to the next byte in the message */ return offset + bytes_used; } /* * Function name: dissect_cyclic_wt * * Purpose: Dissect the "Cyclic Write Data Block" in a Controller-to-Device message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_cyclic_wt(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { proto_tree *header_tree; /* Create the tree for the entire cyclic write data block */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_cyclic_rd_wt, NULL, "Cyclic Write Data Block"); /* Display the cyclic write block id value */ proto_tree_add_item(header_tree, hf_cip_cyclic_write_blk, tvb, offset, 1, ENC_LITTLE_ENDIAN); /* Display the cyclic read block id value */ proto_tree_add_item(header_tree, hf_cip_cyclic_read_blk, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); /* Display the remainder of the cyclic write data if there is any */ if ( (size - 4) > 0 ) { proto_tree_add_item(header_tree, hf_cip_cyclic_wrt_data, tvb, offset + 4, size - 4, ENC_NA); } return offset + size; } /* * Function name: dissect_cyclic_rd * * Purpose: Dissect the "Cyclic Read Data Block" in a Device-to-Controller message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_cyclic_rd(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { proto_tree *header_tree; /* Create the tree for the entire cyclic write data block */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_cyclic_rd_wt, NULL, "Cyclic Read Data Block"); /* Display the cyclic write block id value */ proto_tree_add_item(header_tree, hf_cip_cyclic_write_blk, tvb, offset, 1, ENC_LITTLE_ENDIAN); /* Display the cyclic write status value */ proto_tree_add_item(header_tree, hf_cip_cyclic_write_sts, tvb, offset + 1, 1, ENC_LITTLE_ENDIAN); /* Display the cyclic read block id value */ proto_tree_add_item(header_tree, hf_cip_cyclic_read_blk, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); /* Display the cyclic read status value */ proto_tree_add_item(header_tree, hf_cip_cyclic_read_sts, tvb, offset + 3, 1, ENC_LITTLE_ENDIAN); /* Display the remainder of the cyclic read data if there is any*/ if ( (size - 4) > 0 ) { proto_tree_add_item(header_tree, hf_cip_cyclic_rd_data, tvb, offset + 4, size - 4, ENC_NA); } return offset + size; } /* * Function name: dissect_cntr_event * * Purpose: Dissect the "Event Data Block" in a Controller-to-Device message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_cntr_event(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { proto_tree *header_tree; guint32 acks, cur_ack; guint32 bytes_used = 0; /* Create the tree for the entire cyclic write data block */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_event, NULL, "Event Data Block"); guint32 event_checking_control = tvb_get_letohl(tvb, offset); dissect_event_checking_control(NULL, header_tree, NULL, tvb, offset, 4); /* The event checking control value is 4 bytes long */ bytes_used = 4; /* The final 4 bits of the event checking control value are the number of acknowledgements in the message */ acks = (event_checking_control >> 28) & 0x0F; /* Each acknowledgement contains and id and a status value */ for (cur_ack = 0; cur_ack < acks; cur_ack++) { /* Display the current acknowledgement id */ proto_tree_add_item(header_tree, hf_cip_event_ack, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; /* Display the current event status */ proto_tree_add_item(header_tree, hf_cip_evnt_sts_stat, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; } return offset + size; } /* * Function name: dissect_devce_event * * Purpose: Dissect the "Event Data Block" in a Device-to-Controller message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_devce_event(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { proto_tree *header_tree; guint64 nots, cur_not; guint32 bytes_used = 0; /* Create the tree for the entire cyclic write data block */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_event, NULL, "Event Data Block"); guint32 event_checking_status = tvb_get_letohl(tvb, offset); dissect_event_checking_status(NULL, header_tree, NULL, tvb, offset, 4); /* The event status control value is 4 bytes long */ bytes_used = 4; /* The final 4 bits of the event status control value are the number of notifications in the message */ nots = (event_checking_status >> 28) & 0x0F; /* Each notification contains and id, status value, event type, position and time stamp */ for (cur_not = 0; cur_not < nots; cur_not++) { /* Display the current event id */ proto_tree_add_item(header_tree, hf_cip_event_id, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; /* Display the current event status */ proto_tree_add_item(header_tree, hf_cip_evnt_sts_stat, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 1; /* Display the current event type */ proto_tree_add_item(header_tree, hf_cip_evnt_type, tvb, offset + bytes_used, 1, ENC_LITTLE_ENDIAN); bytes_used += 2; /* Increment by 2 to jump the reserved byte */ /* Display the event position value */ proto_tree_add_item(header_tree, hf_cip_event_pos, tvb, offset + bytes_used, 4, ENC_LITTLE_ENDIAN); bytes_used += 4; /* Display the event time stamp value */ proto_tree_add_item(header_tree, hf_cip_event_ts, tvb, offset + bytes_used, 8, ENC_LITTLE_ENDIAN); bytes_used += 8; } return size + offset; } /* * Function name: dissect_get_axis_attr_list_request * * Purpose: Dissect the get axis attribute list service request * * Returns: None */ static void dissect_get_axis_attr_list_request(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_item *attr_item; proto_tree *header_tree, *attr_tree; guint32 local_offset; /* Create the tree for the get axis attribute list request */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_get_axis_attribute, NULL, "Get Axis Attribute List Request"); /* Read the number of attributes that are contained within the request */ guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_get_axis_attr_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); /* Start the attribute loop at the beginning of the first attribute in the list */ local_offset = offset + 4; /* For each attribute display the associated fields */ for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { /* At a minimum the local offset needs will need to be incremented by 4 bytes to reach the next attribute */ guint8 increment_size = 4; /* Create the tree for this attribute within the request */ guint32 attribute_id; attr_item = proto_tree_add_item_ret_uint(header_tree, hf_get_axis_attr_list_attribute_id, tvb, local_offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attr_tree = proto_item_add_subtree(attr_item, ett_get_axis_attr_list); guint32 dimension; proto_tree_add_item_ret_uint(attr_tree, hf_get_axis_attr_list_dimension, tvb, local_offset + 2, 1, ENC_LITTLE_ENDIAN, &dimension); proto_tree_add_item(attr_tree, hf_get_axis_attr_list_element_size, tvb, local_offset + 3, 1, ENC_LITTLE_ENDIAN); if (dimension == 1) { /* Display the start index and start index from the request */ proto_tree_add_item(attr_tree, hf_get_axis_attr_list_start_index, tvb, local_offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(attr_tree, hf_get_axis_attr_list_data_elements, tvb, local_offset + 6, 2, ENC_LITTLE_ENDIAN); /* Modify the amount to update the local offset by and the start of the data to include the index and elements field */ increment_size += 4; } attribute_info_t* pattribute = cip_get_attribute(CI_CLS_MOTION, instance_id, attribute_id); if (pattribute != NULL) { proto_item_append_text(attr_item, " (%s)", pattribute->text); } /* Move the local offset to the next attribute */ local_offset += increment_size; } } static int dissect_motion_attribute(packet_info *pinfo, tvbuff_t* tvb, int offset, guint32 attribute_id, guint32 instance_id, proto_item* attr_item, proto_tree* attr_tree, guint8 dimension, guint32 attribute_size) { attribute_info_t* pattribute = cip_get_attribute(CI_CLS_MOTION, instance_id, attribute_id); int parsed_len = 0; if (pattribute != NULL) { proto_item_append_text(attr_item, " (%s)", pattribute->text); // TODO: Handle more dimensions. Unsure about the format when there is more than 1 item. if (dimension <= 1) { parsed_len = dissect_cip_attribute(pinfo, attr_tree, attr_item, tvb, pattribute, offset, attribute_size); } } return parsed_len; } /* * Function name: dissect_set_axis_attr_list_request * * Purpose: Dissect the set axis attribute list service request * * Returns: None */ static void dissect_set_axis_attr_list_request(packet_info *pinfo, tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_item *attr_item; proto_tree *header_tree, *attr_tree; guint32 local_offset; /* Create the tree for the set axis attribute list request */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_set_axis_attribute, NULL, "Set Axis Attribute List Request"); /* Read the number of attributes that are contained within the request */ guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_set_axis_attr_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); /* Start the attribute loop at the beginning of the first attribute in the list */ local_offset = offset + 4; /* For each attribute display the associated fields */ for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { /* At a minimum the local offset needs to be incremented by 4 bytes to reach the next attribute */ guint8 increment_size = 4; /* Pull the fields for this attribute from the payload, all fields are needed to make some calculations before * properly displaying of the attribute is possible */ guint8 attribute_start = 4; /* Create the tree for this attribute in the get axis attribute list request */ guint32 attribute_id; attr_item = proto_tree_add_item_ret_uint(header_tree, hf_set_axis_attr_list_attribute_id, tvb, local_offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attr_tree = proto_item_add_subtree(attr_item, ett_set_axis_attr_list); guint32 dimension; proto_tree_add_item_ret_uint(attr_tree, hf_set_axis_attr_list_dimension, tvb, local_offset + 2, 1, ENC_LITTLE_ENDIAN, &dimension); guint32 attribute_size; proto_tree_add_item_ret_uint(attr_tree, hf_set_axis_attr_list_element_size, tvb, local_offset + 3, 1, ENC_LITTLE_ENDIAN, &attribute_size); if (dimension == 1) { guint32 data_elements; /* Display the start index and start index from the request if the request is an array */ proto_tree_add_item(attr_tree, hf_set_axis_attr_list_start_index, tvb, local_offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item_ret_uint(attr_tree, hf_set_axis_attr_list_data_elements, tvb, local_offset + 6, 2, ENC_LITTLE_ENDIAN, &data_elements); /* Modify the size of the attribute data by the number of elements if the request is an array request */ attribute_size *= data_elements; /* Modify the amount to update the local offset by and the start of the data to include the index and elements field */ increment_size += 4; attribute_start += 4; } int parsed_len = dissect_motion_attribute(pinfo, tvb, local_offset + attribute_start, attribute_id, instance_id, attr_item, attr_tree, dimension, attribute_size); // Display the raw attribute data if configured. Otherwise, just show the remaining unparsed data. if (display_full_attribute_data) { proto_tree_add_item(attr_tree, hf_cip_attribute_data, tvb, local_offset + attribute_start, attribute_size, ENC_NA); } else if ((attribute_size - parsed_len) > 0) { proto_tree_add_item(attr_tree, hf_cip_attribute_data, tvb, local_offset + attribute_start + parsed_len, attribute_size - parsed_len, ENC_NA); } /* Round the attribute size up so the next attribute lines up on a 32-bit boundary */ if (attribute_size % 4 != 0) { attribute_size = attribute_size + (4 - (attribute_size % 4)); } /* Move the local offset to the next attribute */ local_offset += (attribute_size + increment_size); } } /* * Function name: dissect_group_sync_request * * Purpose: Dissect the group sync service request * * Returns: None */ static void dissect_group_sync_request (tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size) { proto_tree *header_tree; /* Create the tree for the group sync request */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_group_sync, NULL, "Group Sync Request"); /* Read the grandmaster id from the payload */ proto_tree_add_item(header_tree, hf_cip_ptp_grandmaster, tvb, offset, 8, ENC_LITTLE_ENDIAN); } static void dissect_set_cyclic_list_request(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id, const char* service_name) { proto_tree* header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_set_cyclic_list, NULL, service_name); guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_set_cyclic_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); // Skip Number of Attributes and Reserved field. offset += 4; for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { guint32 attribute_id; proto_item* attr_item = proto_tree_add_item_ret_uint(header_tree, hf_set_cyclic_list_attribute_id, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attribute_info_t* pattribute = cip_get_attribute(CI_CLS_MOTION, instance_id, attribute_id); if (pattribute != NULL) { proto_item_append_text(attr_item, " (%s)", pattribute->text); } offset += 2; } } static void dissect_set_cyclic_list_respone(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id, const char* service_name) { proto_tree* header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_set_cyclic_list, NULL, service_name); guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_set_cyclic_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); proto_tree_add_item(header_tree, hf_set_cyclic_list_read_block_id, tvb, offset + 2, 2, ENC_LITTLE_ENDIAN); // Skip Number of Attributes and Cyclic Read Block ID field. offset += 4; for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { guint32 attribute_id; proto_item* attr_item = proto_tree_add_item_ret_uint(header_tree, hf_set_cyclic_list_attribute_id, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attribute_info_t* pattribute = cip_get_attribute(CI_CLS_MOTION, instance_id, attribute_id); if (pattribute != NULL) { proto_item_append_text(attr_item, " (%s)", pattribute->text); } offset += 2; proto_tree_add_item(header_tree, hf_set_cyclic_list_attr_sts, tvb, offset, 1, ENC_LITTLE_ENDIAN); // Skip over Attribute Status and Reserved field. offset += 2; } } /* * Function name: dissect_cntr_service * * Purpose: Dissect the "Service Data Block" in a Controller-to-Device message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_cntr_service(tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_tree *header_tree; guint32 service; /* Create the tree for the entire service data block */ proto_item *item; header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_service, &item, "Service Data Block"); /* Display the transaction id value */ proto_tree_add_item(header_tree, hf_cip_svc_transction, tvb, offset, 1, ENC_LITTLE_ENDIAN); /* Display the service code */ proto_tree_add_item_ret_uint(header_tree, hf_cip_svc_code, tvb, offset + 1, 1, ENC_LITTLE_ENDIAN, &service); /* If the service is a set axis, get axis attribute or group sync request dissect it as well */ if (size > 4) { switch (service) { case SC_GET_AXIS_ATTRIBUTE_LIST: dissect_get_axis_attr_list_request(tvb, header_tree, offset + 4, size - 4, instance_id); break; case SC_SET_AXIS_ATTRIBUTE_LIST: dissect_set_axis_attr_list_request(pinfo, tvb, header_tree, offset + 4, size - 4, instance_id); break; case SC_GROUP_SYNC: dissect_group_sync_request(tvb, header_tree, offset + 4, size - 4); break; case SC_SET_CYCLIC_WRITE_LIST: dissect_set_cyclic_list_request(tvb, header_tree, offset + 4, size - 4, instance_id, "Set Cyclic Write List Request"); break; case SC_SET_CYCLIC_READ_LIST: dissect_set_cyclic_list_request(tvb, header_tree, offset + 4, size - 4, instance_id, "Set Cyclic Read List Request"); break; case SC_SET_ATT_LIST: { cip_simple_request_info_t motion_path; motion_path.iClass = CI_CLS_MOTION; motion_path.iInstance = instance_id; tvbuff_t* tvb_set_attr = tvb_new_subset_length(tvb, offset + 4, size - 4); int parsed_len = dissect_cip_set_attribute_list_req(tvb_set_attr, pinfo, header_tree, item, 0, &motion_path); // Display any remaining unparsed data. int remain_len = tvb_reported_length_remaining(tvb, offset + 4 + parsed_len); if (remain_len > 0) { proto_tree_add_item(header_tree, hf_cip_attribute_data, tvb, offset + 4 + parsed_len, size - 4 - parsed_len, ENC_NA); } break; } default: /* Display the remainder of the service channel data */ proto_tree_add_item(header_tree, hf_cip_svc_data, tvb, offset + 4, size - 4, ENC_NA); } } return offset + size; } /* * Function name: dissect_set_axis_attr_list_response * * Purpose: Dissect the set axis attribute list service response * * Returns: None */ static void dissect_set_axis_attr_list_response(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_item *attr_item; proto_tree *header_tree, *attr_tree; guint32 local_offset; /* Create the tree for the set axis attribute list response */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_get_axis_attribute, NULL, "Set Axis Attribute List Response"); /* Read the number of attributes that are contained within the response */ guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_set_axis_attr_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); /* Start the attribute loop at the beginning of the first attribute in the list */ local_offset = offset + 4; /* For each attribute display the associated fields */ for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { /* Create the tree for the current attribute in the set axis attribute list response */ guint32 attribute_id; attr_item = proto_tree_add_item_ret_uint(header_tree, hf_set_axis_attr_list_attribute_id, tvb, local_offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attr_tree = proto_item_add_subtree(attr_item, ett_get_axis_attr_list); /* Add the response status to the tree */ proto_tree_add_item(attr_tree, hf_cip_svc_set_axis_attr_sts, tvb, local_offset + 2, 1, ENC_LITTLE_ENDIAN); attribute_info_t* pattribute = cip_get_attribute(CI_CLS_MOTION, instance_id, attribute_id); if (pattribute != NULL) { proto_item_append_text(attr_item, " (%s)", pattribute->text); } /* Move the local offset to the next attribute */ local_offset += 4; } } /* * Function name: dissect_get_axis_attr_list_response * * Purpose: Dissect the get axis attribute list service response * * Returns: None */ static void dissect_get_axis_attr_list_response(packet_info* pinfo, tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_item *attr_item; proto_tree *header_tree, *attr_tree; guint32 local_offset; /* Create the tree for the get axis attribute list response */ header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_get_axis_attribute, NULL, "Get Axis Attribute List Response"); /* Read the number of attributes that are contained within the request */ guint32 attribute_cnt; proto_tree_add_item_ret_uint(header_tree, hf_get_axis_attr_list_attribute_cnt, tvb, offset, 2, ENC_LITTLE_ENDIAN, &attribute_cnt); /* Start the attribute loop at the beginning of the first attribute in the list */ local_offset = offset + 4; /* For each attribute display the associated fields */ for (guint32 attribute = 0; attribute < attribute_cnt; attribute++) { /* At a minimum the local offset needs to be incremented by 4 bytes to reach the next attribute */ guint8 increment_size = 4; /* Pull the fields for this attribute from the payload, all fields are needed to make some calculations before * properly displaying of the attribute is possible */ guint8 dimension = tvb_get_guint8(tvb, local_offset + 2); guint32 attribute_size = tvb_get_guint8(tvb, local_offset + 3); guint8 attribute_start = 4; if (dimension == 1) { guint16 data_elements = tvb_get_letohs(tvb, local_offset + 6); /* Modify the size of the attribute data by the number of elements if the request is an array request */ attribute_size *= data_elements; /* Modify the amount to update the local offset by and the start of the data to include the index and elements field */ increment_size += 4; attribute_start += 4; } /* Display the fields associated with the get axis attribute list response */ guint32 attribute_id; attr_item = proto_tree_add_item_ret_uint(header_tree, hf_get_axis_attr_list_attribute_id, tvb, local_offset, 2, ENC_LITTLE_ENDIAN, &attribute_id); attr_tree = proto_item_add_subtree(attr_item, ett_get_axis_attr_list); if (dimension == 0xFF) { /* Display the element size as an error code if the dimension field indicates an error */ proto_tree_add_item(attr_tree, hf_cip_svc_get_axis_attr_sts, tvb, local_offset + 3, 1, ENC_LITTLE_ENDIAN); /* No attribute data so no attribute size */ attribute_size = 0; } else { proto_tree_add_item(attr_tree, hf_get_axis_attr_list_dimension, tvb, local_offset + 2, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(attr_tree, hf_get_axis_attr_list_element_size, tvb, local_offset + 3, 1, ENC_LITTLE_ENDIAN); if (dimension == 1) { /* Display the start index and start index from the request */ proto_tree_add_item(attr_tree, hf_get_axis_attr_list_start_index, tvb, local_offset + 4, 2, ENC_LITTLE_ENDIAN); proto_tree_add_item(attr_tree, hf_get_axis_attr_list_data_elements, tvb, local_offset + 6, 2, ENC_LITTLE_ENDIAN); } int parsed_len = dissect_motion_attribute(pinfo, tvb, local_offset + attribute_start, attribute_id, instance_id, attr_item, attr_tree, dimension, attribute_size); // Display the raw attribute data if configured. Otherwise, just show the remaining unparsed data if (display_full_attribute_data) { proto_tree_add_item(attr_tree, hf_cip_attribute_data, tvb, local_offset + attribute_start, attribute_size, ENC_NA); } else if ((attribute_size - parsed_len) > 0) { proto_tree_add_item(attr_tree, hf_cip_attribute_data, tvb, local_offset + attribute_start + parsed_len, attribute_size - parsed_len, ENC_NA); } /* Round the attribute size up so the next attribute lines up on a 32-bit boundary */ if (attribute_size % 4 != 0) { attribute_size = attribute_size + (4 - (attribute_size % 4)); } } /* Move the local offset to the next attribute */ local_offset += (attribute_size + increment_size); } } /* * Function name: dissect_group_sync_response * * Purpose: Dissect the group sync service response * * Returns: None */ static void dissect_group_sync_response (tvbuff_t* tvb, proto_tree* tree, guint32 offset) { proto_tree_add_item(tree, hf_cip_group_sync, tvb, offset, 1, ENC_LITTLE_ENDIAN); } /* * Function name: dissect_devce_service * * Purpose: Dissect the "Service Data Block" in a Device-to-Controller message * * Returns: The new offset into the message that follow on dissections should use * as their starting offset */ static guint32 dissect_devce_service(tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, guint32 offset, guint32 size, guint32 instance_id) { proto_tree *header_tree; /* Create the tree for the entire service data block */ proto_item* item; header_tree = proto_tree_add_subtree(tree, tvb, offset, size, ett_service, &item, "Service Data Block"); /* Display the transaction id value */ proto_tree_add_item(header_tree, hf_cip_svc_transction, tvb, offset, 1, ENC_LITTLE_ENDIAN); /* Display the service code */ guint32 service_code; proto_tree_add_item_ret_uint(header_tree, hf_cip_svc_code, tvb, offset + 1, 1, ENC_LITTLE_ENDIAN, &service_code); /* Display the general status code */ proto_tree_add_item(header_tree, hf_cip_svc_sts, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); /* Display the extended status code */ proto_tree_add_item(header_tree, hf_cip_svc_ext_status, tvb, offset + 3, 1, ENC_LITTLE_ENDIAN); /* If the service is a set axis, get axis attribute response or group sync dissect it as well */ if (size > 4) { switch (service_code) { case SC_GET_AXIS_ATTRIBUTE_LIST: dissect_get_axis_attr_list_response(pinfo, tvb, header_tree, offset + 4, size - 4, instance_id); break; case SC_SET_AXIS_ATTRIBUTE_LIST: dissect_set_axis_attr_list_response(tvb, header_tree, offset + 4, size - 4, instance_id); break; case SC_GROUP_SYNC: dissect_group_sync_response(tvb, header_tree, offset + 4); break; case SC_SET_CYCLIC_WRITE_LIST: dissect_set_cyclic_list_respone(tvb, header_tree, offset + 4, size - 4, instance_id, "Set Cyclic Write List Response"); break; case SC_SET_CYCLIC_READ_LIST: dissect_set_cyclic_list_respone(tvb, header_tree, offset + 4, size - 4, instance_id, "Set Cyclic Read List Response"); break; case SC_SET_ATT_LIST: { cip_simple_request_info_t motion_path; motion_path.iClass = CI_CLS_MOTION; motion_path.iInstance = instance_id; tvbuff_t* tvb_set_attr = tvb_new_subset_length(tvb, offset + 4, size - 4); dissect_cip_set_attribute_list_rsp(tvb_set_attr, pinfo, header_tree, item, 0, &motion_path); break; } default: /* Display the remainder of the service channel data */ proto_tree_add_item(header_tree, hf_cip_svc_data, tvb, offset + 4, size - 4, ENC_NA); break; } } return offset + size; } /* * Function name: dissect_var_inst_header * * Purpose: Dissect the instance data header of a variable controller to device or * device to controller message * * Returns: void */ static void dissect_var_inst_header(tvbuff_t* tvb, proto_tree* tree, guint32 offset, guint8* inst_number, guint32* cyc_size, guint32* cyc_blk_size, guint32* evnt_size, guint32* servc_size) { proto_tree *header_tree; /* Create the tree for the entire instance data header */ *inst_number = tvb_get_guint8(tvb, offset); header_tree = proto_tree_add_subtree_format(tree, tvb, offset, 8, ett_inst_data_header, NULL, "Instance Data Header - Instance: %d", *inst_number); /* Read the instance number field from the instance data header */ proto_tree_add_item(header_tree, hf_var_devce_instance, tvb, offset, 1, ENC_LITTLE_ENDIAN); /* The "size" fields in the instance data block header are all stored as number of 32-bit words the * block uses since all blocks should pad up to 32-bits so to convert to bytes each is multiplied by 4 */ /* Read the instance block size field in bytes from the instance data header */ proto_tree_add_item(header_tree, hf_var_devce_instance_block_size, tvb, offset + 2, 1, ENC_NA); /* Read the cyclic block size field in bytes from the instance data header */ proto_tree_add_item(header_tree, hf_var_devce_cyclic_block_size, tvb, offset + 3, 1, ENC_NA); /* Read the cyclic command block size field in bytes from the instance data header */ *cyc_size = (tvb_get_guint8(tvb, offset + 4) * 4); proto_tree_add_item(header_tree, hf_var_devce_cyclic_data_block_size, tvb, offset + 4, 1, ENC_NA); /* Read the cyclic write block size field in bytes from the instance data header */ *cyc_blk_size = (tvb_get_guint8(tvb, offset + 5) * 4); proto_tree_add_item(header_tree, hf_var_devce_cyclic_rw_block_size, tvb, offset + 5, 1, ENC_NA); /* Read the event block size in bytes from the instance data header */ *evnt_size = (tvb_get_guint8(tvb, offset + 6) * 4); proto_tree_add_item(header_tree, hf_var_devce_event_block_size, tvb, offset + 6, 1, ENC_NA); /* Read the service block size in bytes from the instance data header */ *servc_size = (tvb_get_guint8(tvb, offset + 7) * 4); proto_tree_add_item(header_tree, hf_var_devce_service_block_size, tvb, offset + 7, 1, ENC_NA); } /* * Function name: dissect_var_cont_conn_header * * Purpose: Dissect the connection header of a variable controller to device message * * Returns: Offset to the start of the instance data block */ static guint32 dissect_var_cont_conn_header(tvbuff_t* tvb, proto_tree* tree, guint32* inst_count, guint32 offset) { guint32 header_size; proto_tree *header_tree; /* Calculate the header size, start with the basic header size */ header_size = 8; guint32 time_data_set = tvb_get_guint8(tvb, offset + 7); /* Check the time data set field for enabled bits. If either update period or * update time stamp fields are set, bump the header size by the appropriate size */ if ( (time_data_set & TIME_DATA_SET_TIME_STAMP) == TIME_DATA_SET_TIME_STAMP ) { header_size += 8; } if ( (time_data_set & TIME_DATA_SET_TIME_OFFSET) == TIME_DATA_SET_TIME_OFFSET ) { header_size += 8; } /* Create the tree for the entire connection header */ header_tree = proto_tree_add_subtree(tree, tvb, offset, header_size, ett_cont_dev_header, NULL, "Connection Header"); /* Add the connection header fields that are common to all types of messages */ proto_tree_add_item(header_tree, hf_cip_format, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(header_tree, hf_cip_revision, tvb, offset + 1, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(header_tree, hf_cip_updateid, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); dissect_node_control(NULL, header_tree, NULL, tvb, offset + 3, 1); /* Add the instance count and last update id to the connection header tree */ proto_tree_add_item_ret_uint(header_tree, hf_cip_instance_cnt, tvb, offset + 4, 1, ENC_LITTLE_ENDIAN, inst_count); proto_tree_add_item(header_tree, hf_cip_last_update, tvb, offset + 6, 1, ENC_LITTLE_ENDIAN); dissect_time_data_set(NULL, header_tree, NULL, tvb, offset + 7, 1); /* Move the offset to the byte just beyond the time data set field */ offset = (offset + 7 + 1); /* Add the time values if they are present in the time data set header field */ if ( (time_data_set & TIME_DATA_SET_TIME_STAMP) == TIME_DATA_SET_TIME_STAMP ) { proto_tree_add_item(header_tree, hf_cip_cont_time_stamp, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset = (offset + 8); } if ( (time_data_set & TIME_DATA_SET_TIME_OFFSET) == TIME_DATA_SET_TIME_OFFSET ) { proto_tree_add_item(header_tree, hf_cip_cont_time_offset, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset = (offset + 8); } /* Return the number of bytes used so it can be used as an offset in the following dissections */ return offset; } /* * Function name: dissect_var_devce_conn_header * * Purpose: Dissect the connection header of a variable device to controller message * * Returns: Offset to the start of the instance data block */ static guint32 dissect_var_devce_conn_header(tvbuff_t* tvb, proto_tree* tree, guint32* inst_count, guint32 offset) { guint32 header_size; proto_tree *header_tree; /* Calculate the header size, start with the basic header size */ header_size = 8; guint32 time_data_set = tvb_get_guint8(tvb, offset + 7); if ( (time_data_set & TIME_DATA_SET_TIME_STAMP) == TIME_DATA_SET_TIME_STAMP ) { header_size += 8; } if ( (time_data_set & TIME_DATA_SET_TIME_OFFSET) == TIME_DATA_SET_TIME_OFFSET ) { header_size += 8; } if ( (time_data_set & TIME_DATA_SET_UPDATE_DIAGNOSTICS) == TIME_DATA_SET_UPDATE_DIAGNOSTICS ) { header_size += 4; } if ( (time_data_set & TIME_DATA_SET_TIME_DIAGNOSTICS) == TIME_DATA_SET_TIME_DIAGNOSTICS ) { header_size += 16; } /* Create the tree for the entire connection header */ header_tree = proto_tree_add_subtree(tree, tvb, offset, header_size, ett_cont_dev_header, NULL, "Connection Header"); /* Add the connection header fields that are common to all types of messages */ proto_tree_add_item(header_tree, hf_cip_format, tvb, offset, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(header_tree, hf_cip_revision, tvb, offset + 1, 1, ENC_LITTLE_ENDIAN); proto_tree_add_item(header_tree, hf_cip_updateid, tvb, offset + 2, 1, ENC_LITTLE_ENDIAN); dissect_node_status(NULL, header_tree, NULL, tvb, offset + 3, 1); /* Add the instance count to the connection header tree */ proto_tree_add_item_ret_uint(header_tree, hf_cip_instance_cnt, tvb, offset + 4, 1, ENC_LITTLE_ENDIAN, inst_count); /* The device to controller header contains the node alarms and node faults fields as well. */ proto_tree_add_item(header_tree, hf_cip_node_fltalarms, tvb, offset + 5, 1, ENC_LITTLE_ENDIAN); /* Add the last update id to the connection header tree */ proto_tree_add_item(header_tree, hf_cip_last_update, tvb, offset + 6, 1, ENC_LITTLE_ENDIAN); dissect_time_data_set(NULL, header_tree, NULL, tvb, offset + 7, 1); /* Move the offset to the byte just beyond the time data set field */ offset = (offset + 7 + 1); /* Add the time values if they are present in the time data set header field */ if ( (time_data_set & TIME_DATA_SET_TIME_STAMP) == TIME_DATA_SET_TIME_STAMP ) { proto_tree_add_item(header_tree, hf_cip_devc_time_stamp, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset = (offset + 8); } if ( (time_data_set & TIME_DATA_SET_TIME_OFFSET) == TIME_DATA_SET_TIME_OFFSET ) { proto_tree_add_item(header_tree, hf_cip_devc_time_offset, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset = (offset + 8); } if ( (time_data_set & TIME_DATA_SET_UPDATE_DIAGNOSTICS) == TIME_DATA_SET_UPDATE_DIAGNOSTICS ) { /* If the time diagnostic bit is set then the header contains the count of lost updates, late updates, data * received time stamp and data transmit time stamp */ proto_tree_add_item(header_tree, hf_cip_lost_update, tvb, offset, 1, ENC_LITTLE_ENDIAN); offset = (offset + 1); /* Add the reserved bytes to the offset after adding the late updates to the display */ proto_tree_add_item(header_tree, hf_cip_late_update, tvb, offset, 1, ENC_LITTLE_ENDIAN); offset = (offset + 3); } if ( (time_data_set & TIME_DATA_SET_TIME_DIAGNOSTICS) == TIME_DATA_SET_TIME_DIAGNOSTICS ) { proto_tree_add_item(header_tree, hf_cip_data_rx_time_stamp, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset += 8; proto_tree_add_item(header_tree, hf_cip_data_tx_time_stamp, tvb, offset, 8, ENC_LITTLE_ENDIAN); offset += 8; } /* Return the number of bytes used so it can be used as an offset in the following dissections */ return offset; } /* * Function name: dissect_cipmotion * * Purpose: Perform the top level dissection of the CIP Motion datagram, it is called by * Wireshark when the dissection rule registered in proto_reg_handoff_cipmotion is fired * * Returns: void */ static int dissect_cipmotion(tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, void* data) { cip_io_data_input* io_data_input = (cip_io_data_input*)data; guint32 con_format; guint32 update_id; proto_item *proto_item_top; proto_tree *proto_tree_top; guint32 offset = 0; guint8 ConnPoint = 2; if (io_data_input && io_data_input->conn_info) { ConnPoint = io_data_input->conn_info->connection_path.iConnPoint; } /* Create display subtree for the protocol by creating an item and then * creating a subtree from the item, the subtree must have been registered * in proto_register_cipmotion already */ proto_item_top = proto_tree_add_item(tree, proto_cipmotion, tvb, 0, -1, ENC_NA); proto_tree_top = proto_item_add_subtree(proto_item_top, ett_cipmotion); /* Add the CIP class 1 sequence number to the tree */ proto_tree_add_item(proto_tree_top, hf_cip_class1_seqnum, tvb, offset, 2, ENC_LITTLE_ENDIAN); offset = (offset + 2); if (ConnPoint >= 3) { dissect_cip_run_idle(tvb, offset, proto_tree_top); offset += 4; } /* Pull the actual values for the connection format and update id from the * incoming message to be used in the column info */ con_format = tvb_get_guint8(tvb, offset); update_id = tvb_get_guint8(tvb, offset + 2); /* Make entries in Protocol column and Info column on summary display */ col_set_str(pinfo->cinfo, COL_PROTOCOL, "CIP Motion"); /* Add connection format and update number to the info column */ col_add_fstr( pinfo->cinfo, COL_INFO, "%s, Update Id: %d", val_to_str(con_format, cip_con_format_vals, "Unknown connection format (%x)"), update_id ); /* Attempt to classify the incoming header */ if (( con_format == FORMAT_VAR_CONTROL_TO_DEVICE ) || ( con_format == FORMAT_VAR_DEVICE_TO_CONTROL )) { /* Sizes of the individual channels within the connection */ guint32 cyc_size, cyc_blk_size, evnt_size, servc_size; guint32 inst_count = 0, inst; guint32 format_rev = 0; /* Dissect the header fields */ switch(con_format) { case FORMAT_VAR_CONTROL_TO_DEVICE: format_rev = tvb_get_guint8(tvb, offset + 1); offset = dissect_var_cont_conn_header(tvb, proto_tree_top, &inst_count, offset); break; case FORMAT_VAR_DEVICE_TO_CONTROL: format_rev = tvb_get_guint8(tvb, offset + 1); offset = dissect_var_devce_conn_header(tvb, proto_tree_top, &inst_count, offset); break; } if (format_rev != ConnPoint) { expert_add_info(pinfo, proto_item_top, &ei_format_rev_conn_pt); } /* Repeat the following dissections for each instance within the payload */ for( inst = 0; inst < inst_count; inst++ ) { /* Actual instance number from header field */ guint8 instance; /* Dissect the instance data header */ dissect_var_inst_header( tvb, proto_tree_top, offset, &instance, &cyc_size, &cyc_blk_size, &evnt_size, &servc_size ); /* Increment the offset to just beyond the instance header */ offset += 8; /* Dissect the cyclic command (actual) data if any exists */ /* Dissect the cyclic write (read) data if any exists */ /* Dissect the event data block if there is any event data */ switch(con_format) { case FORMAT_VAR_CONTROL_TO_DEVICE: if ( cyc_size > 0 ) offset = dissect_cntr_cyclic(tvb, proto_tree_top, offset, cyc_size); if ( cyc_blk_size > 0 ) offset = dissect_cyclic_wt(tvb, proto_tree_top, offset, cyc_blk_size); if ( evnt_size > 0 ) offset = dissect_cntr_event(tvb, proto_tree_top, offset, evnt_size); if ( servc_size > 0 ) offset = dissect_cntr_service(tvb, pinfo, proto_tree_top, offset, servc_size, instance); break; case FORMAT_VAR_DEVICE_TO_CONTROL: if ( cyc_size > 0 ) offset = dissect_device_cyclic(tvb, proto_tree_top, offset, cyc_size); if ( cyc_blk_size > 0 ) offset = dissect_cyclic_rd( tvb, proto_tree_top, offset, cyc_blk_size ); if ( evnt_size > 0 ) offset = dissect_devce_event(tvb, proto_tree_top, offset, evnt_size); if ( servc_size > 0 ) offset = dissect_devce_service(tvb, pinfo, proto_tree_top, offset, servc_size, instance); break; } } /* End of instance for( ) loop */ } // Display any remaining unparsed data. int remain_len = tvb_reported_length_remaining(tvb, offset); if (remain_len > 0) { proto_tree_add_item(proto_tree_top, hf_cip_data, tvb, offset, remain_len, ENC_NA); } return tvb_captured_length(tvb); } static int dissect_cipmotion3(tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, void* data _U_) { cip_conn_info_t conn_info; memset(&conn_info, 0, sizeof(conn_info)); conn_info.connection_path.iConnPoint = 3; cip_io_data_input io_data_input; io_data_input.conn_info = &conn_info; return dissect_cipmotion(tvb, pinfo, tree, &io_data_input); } int dissect_motion_configuration_block(tvbuff_t* tvb, packet_info* pinfo, proto_tree* tree, proto_item* item, int offset) { proto_item* config_item; proto_tree* config_tree = proto_tree_add_subtree(tree, tvb, offset, 0, ett_configuration_block, &config_item, "Motion Configuration Block"); proto_tree_add_item(config_tree, hf_configuration_block_format_rev, tvb, offset, 1, ENC_LITTLE_ENDIAN); int parsed_len = 1; parsed_len += dissect_connection_configuration_bits(pinfo, config_tree, item, tvb, offset + parsed_len, 1); // 2 reserved bytes parsed_len += 2; proto_tree_add_item(config_tree, hf_configuration_block_drive_power_struct_id, tvb, offset + parsed_len, 4, ENC_LITTLE_ENDIAN); parsed_len += 4; proto_item_set_len(config_item, parsed_len); return parsed_len; } /* * Function name: proto_register_cipmotion * * Purpose: Register the protocol with Wireshark, a script will add this protocol * to the list of protocols during the build process. This function is where the * header fields and subtree identifiers are registered. * * Returns: void */ void proto_register_cipmotion(void) { /* This is a list of header fields that can be used in the dissection or * to use in a filter expression */ static hf_register_info hf[] = { /* Connection format header field, the first byte in the message which * determines if the message is fixed or variable, controller to device, * device to controller, etc. */ { &hf_cip_format, { "Connection Format", "cipm.format", FT_UINT8, BASE_DEC, VALS(cip_con_format_vals), 0, "Message connection format", HFILL } }, /* Connection format revision header field */ { &hf_cip_revision, { "Format Revision", "cipm.revision", FT_UINT8, BASE_DEC, NULL, 0, "Message format revision", HFILL } }, { &hf_cip_class1_seqnum, { "CIP Class 1 Sequence Count", "cipm.class1seqnum", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_configuration_block_format_rev, { "Format Revision", "cipm.config.format_rev", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_configuration_block_drive_power_struct_id, { "Drive Power Structure Class ID", "cipm.config.drive_class_id", FT_UINT32, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cip_updateid, { "Update Id", "cipm.updateid", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Transaction Number", HFILL } }, { &hf_cip_instance_cnt, { "Instance Count", "cipm.instancecount", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cip_last_update, { "Last Update Id", "cipm.lastupdate", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cip_node_status, { "Node Status", "cipm.nodestatus", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_node_control, { "Node Control", "cipm.nodecontrol", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_node_control_remote, { "Remote Control", "cipm.remote", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x01, "Node Control: Remote Control", HFILL} }, { &hf_cip_node_control_sync, { "Sync Control", "cipm.sync", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x02, "Node Control: Synchronous Operation", HFILL} }, { &hf_cip_node_data_valid, { "Data Valid", "cipm.valid", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x04, "Node Control: Data Valid", HFILL} }, { &hf_cip_node_fault_reset, { "Node Fault Reset", "cipm.fltrst", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x08, "Node Control: Node Fault Reset", HFILL} }, { &hf_cip_node_device_faulted, { "Faulted", "cipm.flt", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x08, "Node Control: Device Faulted", HFILL} }, { &hf_cip_node_fltalarms, { "Node Faults and Alarms", "cipm.fltalarms", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cip_time_data_set, { "Time Data Set", "cipm.timedataset", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_time_data_stamp, { "Time Stamp", "cipm.time.stamp", FT_BOOLEAN, 8, TFS(&tfs_true_false), TIME_DATA_SET_TIME_STAMP, "Time Data Set: Time Stamp", HFILL} }, { &hf_cip_time_data_offset, { "Time Offset", "cipm.time.offset", FT_BOOLEAN, 8, TFS(&tfs_true_false), TIME_DATA_SET_TIME_OFFSET, "Time Data Set: Time Offset", HFILL} }, { &hf_cip_time_data_diag, { "Update Diagnostics", "cipm.time.update", FT_BOOLEAN, 8, TFS(&tfs_true_false), TIME_DATA_SET_UPDATE_DIAGNOSTICS, "Time Data Set: Update Diagnostics", HFILL} }, { &hf_cip_time_data_time_diag, { "Time Diagnostics", "cipm.time.diag", FT_BOOLEAN, 8, TFS(&tfs_true_false), TIME_DATA_SET_TIME_DIAGNOSTICS, "Time Data Set: Time Diagnostics", HFILL} }, { &hf_cip_cont_time_stamp, { "Controller Time Stamp", "cipm.ctrltimestamp", FT_UINT64, BASE_DEC, NULL, 0, "Time Data Set: Controller Time Stamp", HFILL} }, { &hf_cip_cont_time_offset, { "Controller Time Offset", "cipm.ctrltimeoffser", FT_UINT64, BASE_DEC, NULL, 0, "Time Data Set: Controller Time Offset", HFILL} }, { &hf_cip_data_rx_time_stamp, { "Data Received Time Stamp", "cipm.rxtimestamp", FT_UINT64, BASE_DEC, NULL, 0, "Time Data Set: Data Received Time Stamp", HFILL} }, { &hf_cip_data_tx_time_stamp, { "Data Transmit Time Stamp", "cipm.txtimestamp", FT_UINT64, BASE_DEC, NULL, 0, "Time Data Set: Data Transmit Time Offset", HFILL} }, { &hf_cip_devc_time_stamp, { "Device Time Stamp", "cipm.devctimestamp", FT_UINT64, BASE_DEC|BASE_UNIT_STRING, &units_nanosecond_nanoseconds, 0, "Time Data Set: Device Time Stamp", HFILL} }, { &hf_cip_devc_time_offset, { "Device Time Offset", "cipm.devctimeoffser", FT_UINT64, BASE_DEC, NULL, 0, "Time Data Set: Device Time Offset", HFILL} }, { &hf_cip_lost_update, { "Lost Updates", "cipm.lostupdates", FT_UINT8, BASE_DEC, NULL, 0, "Time Data Set: Lost Updates", HFILL} }, { &hf_cip_late_update, { "Lost Updates", "cipm.lateupdates", FT_UINT8, BASE_DEC, NULL, 0, "Time Data Set: Late Updates", HFILL} }, { &hf_cip_motor_cntrl, { "Control Mode", "cipm.ctrlmode", FT_UINT8, BASE_DEC, VALS(cip_motor_control_vals), 0, "Cyclic Data Block: Motor Control Mode", HFILL } }, { &hf_cip_feedback, { "Feedback Information", "cipm.feedback", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cip_feedback_mode, { "Feedback Mode", "cipm.feedback_mode", FT_UINT8, BASE_DEC, VALS(cip_feedback_mode_vals), FEEDBACK_MODE_BITS, NULL, HFILL } }, { &hf_cip_feedback_data_type, { "Feedback Data Type", "cipm.feedback_data_type", FT_UINT8, BASE_DEC, VALS(cip_feedback_type_vals), FEEDBACK_DATA_TYPE_BITS, NULL, HFILL } }, { &hf_connection_configuration_bits, { "Connection Configuration Bits", "cipm.ccb", FT_UINT8, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_connection_configuration_bits_power, { "Verify Power Ratings", "cipm.ccb.verify_power_ratings", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x01, NULL, HFILL } }, { &hf_connection_configuration_bits_safety_bit_valid, { "Networked Safety Bit Valid", "cipm.ccb.networked_safety_bit_valid", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x02, NULL, HFILL } }, { &hf_connection_configuration_bits_allow_network_safety, { "Allow Networked Safety", "cipm.ccb.allow_networked_safety", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x04, NULL, HFILL } }, { &hf_cip_axis_control, { "Axis Control", "cipm.axisctrl", FT_UINT8, BASE_DEC, VALS(cip_axis_control_vals), 0, "Cyclic Data Block: Axis Control", HFILL } }, { &hf_cip_control_status, { "Control Status", "cipm.csts", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Axis Control Status", HFILL } }, { &hf_cip_control_status_complete, { "Configuration Complete", "cipm.control_status.complete", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x01, NULL, HFILL } }, { &hf_cip_control_status_bus_up, { "Converter Bus Up", "cipm.control_status.bus_up", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x04, NULL, HFILL } }, { &hf_cip_control_status_bus_unload, { "Converter Bus Unload", "cipm.control_status.bus_unload", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x08, NULL, HFILL } }, { &hf_cip_control_status_power_loss, { "Converter AC Power Loss", "cipm.control_status.power_loss", FT_BOOLEAN, 8, TFS(&tfs_true_false), 0x10, NULL, HFILL } }, { &hf_cip_axis_response, { "Axis Response", "cipm.axisresp", FT_UINT8, BASE_DEC, VALS(cip_axis_response_vals), 0, "Cyclic Data Block: Axis Response", HFILL } }, { &hf_cip_axis_resp_stat, { "Response Status", "cipm.respstat", FT_UINT8, BASE_DEC|BASE_EXT_STRING, &cip_gs_vals_ext, 0, "Cyclic Data Block: Axis Response Status", HFILL } }, { &hf_cip_group_sync, { "Group Sync Status", "cipm.syncstatus", FT_UINT8, BASE_HEX, VALS(cip_sync_status_vals), 0, NULL, HFILL } }, { &hf_cip_cmd_data_set, { "Command Data Set", "cipm.cmdset", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_act_data_set, { "Actual Data Set", "cipm.actset", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_sts_data_set, { "Status Data Set", "cipm.stsset", FT_UINT8, BASE_HEX, NULL, 0, NULL, HFILL} }, // Command Data Set { &hf_cip_cmd_data_pos_cmd, { "Command Position", "cipm.cmd.pos", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_POSITION, "Command Data Set: Command Position", HFILL} }, { &hf_cip_cmd_data_vel_cmd, { "Command Velocity", "cipm.cmd.vel", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_VELOCITY, "Command Data Set: Command Velocity", HFILL} }, { &hf_cip_cmd_data_acc_cmd, { "Command Acceleration", "cipm.cmd.acc", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_ACCELERATION, "Command Data Set: Command Acceleration", HFILL} }, { &hf_cip_cmd_data_trq_cmd, { "Command Torque", "cipm.cmd.trq", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_TORQUE, "Command Data Set: Command Torque", HFILL} }, { &hf_cip_cmd_data_unwind_cycle_count, { "Unwind Cycle Count", "cipm.cmd.unwind", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_UNWIND_CYCLE_COUNT, "Command Data Set: Unwind Cycle Count", HFILL} }, { &hf_cip_cmd_data_pos_displacement, { "Position Displacement", "cipm.cmd.pos_displacement", FT_BOOLEAN, 8, TFS(&tfs_true_false), COMMAND_DATA_SET_POSITION_DISPLACE, "Command Data Set: Position Displacement", HFILL} }, // Actual Data Set { &hf_cip_act_data_pos, { "Actual Position", "cipm.act.pos", FT_BOOLEAN, 8, TFS(&tfs_true_false), ACTUAL_DATA_SET_POSITION, "Actual Data Set: Actual Position", HFILL} }, { &hf_cip_act_data_vel, { "Actual Velocity", "cipm.act.vel", FT_BOOLEAN, 8, TFS(&tfs_true_false), ACTUAL_DATA_SET_VELOCITY, "Actual Data Set: Actual Velocity", HFILL} }, { &hf_cip_act_data_acc, { "Actual Acceleration", "cipm.act.acc", FT_BOOLEAN, 8, TFS(&tfs_true_false), ACTUAL_DATA_SET_ACCELERATION, "Actual Data Set: Actual Acceleration", HFILL} }, { &hf_cip_act_unwind_cycle_count, { "Unwind Cycle Count", "cipm.act.unwind", FT_BOOLEAN, 8, TFS(&tfs_true_false), ACTUAL_DATA_SET_UNWIND_CYCLE_COUNT, "Actual Data Set: Unwind Cycle Count", HFILL} }, { &hf_cip_act_pos_displacement, { "Position Displacement", "cipm.act.pos_displacement", FT_BOOLEAN, 8, TFS(&tfs_true_false), ACTUAL_DATA_SET_POSITION_DISPLACE, "Actual Data Set: Position Displacement", HFILL} }, { &hf_cip_axis_fault, { "Axis Fault Code", "cipm.fault.code", FT_UINT8, BASE_DEC, NULL, 0, "Status Data Set: Fault Code", HFILL } }, { &hf_cip_fault_type, { "Axis Fault Type", "cipm.flttype", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Fault Type", HFILL} }, { &hf_cip_fault_sub_code, { "Axis Fault Sub Code", "cipm.fltsubcode", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Fault Sub Code", HFILL} }, { &hf_cip_fault_action, { "Axis Fault Action", "cipm.fltaction", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Fault Action", HFILL} }, { &hf_cip_fault_time_stamp, { "Axis Fault Time Stamp", "cipm.flttimestamp", FT_UINT64, BASE_DEC, NULL, 0, "Axis Status: Axis Fault Time Stamp", HFILL} }, { &hf_cip_alarm_type, { "Axis Fault Type", "cipm.alarmtype", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Alarm Type", HFILL} }, { &hf_cip_alarm_sub_code, { "Axis Alarm Sub Code", "cipm.alarmsubcode", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Alarm Sub Code", HFILL} }, { &hf_cip_alarm_state, { "Axis Alarm State", "cipm.alarmstate", FT_UINT8, BASE_DEC, NULL, 0, "Axis Status: Axis Alarm State", HFILL } }, { &hf_cip_alarm_time_stamp, { "Axis Fault Time Stamp", "cipm.alarmtimestamp", FT_UINT64, BASE_DEC, NULL, 0, "Axis Status: Axis Alarm Time Stamp", HFILL} }, { &hf_cip_axis_status, { "Axis Status", "cipm.axisstatus", FT_UINT32, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_axis_status_mfg, { "Axis Status Mfg", "cipm.axisstatusmfg", FT_UINT32, BASE_HEX, NULL, 0, "Axis Status, Manufacturer Specific", HFILL} }, { &hf_cip_axis_io_status, { "Axis I/O Status", "cipm.axisiostatus", FT_UINT32, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_axis_io_status_mfg, { "Axis I/O Status Mfg", "cipm.axisiostatusmfg", FT_UINT32, BASE_HEX, NULL, 0, "Axis I/O Status, Manufacturer Specific", HFILL} }, { &hf_cip_axis_safety_status, { "Axis Safety Status", "cipm.safetystatus", FT_UINT32, BASE_HEX, NULL, 0, NULL, HFILL} }, { &hf_cip_axis_safety_status_mfg, { "Axis Safety Status Mfg", "cipm.safetystatusmfg", FT_UINT32, BASE_HEX, NULL, 0, "Axis Safety Status, Manufacturer Specific", HFILL} }, { &hf_cip_axis_safety_state, { "Axis Safety State", "cipm.safetystate", FT_UINT8, BASE_HEX, NULL, 0, "Axis Safety Sate", HFILL} }, { &hf_cip_sts_flt, { "Axis Fault Codes", "cipm.sts.flt", FT_BOOLEAN, 8, TFS(&tfs_true_false), STATUS_DATA_SET_AXIS_FAULT, "Status Data Set: Axis Fault Codes", HFILL} }, { &hf_cip_sts_alrm, { "Axis Alarm Codes", "cipm.sts.alarm", FT_BOOLEAN, 8, TFS(&tfs_true_false), STATUS_DATA_SET_AXIS_ALARM, "Status Data Set: Axis Alarm Codes", HFILL} }, { &hf_cip_sts_sts, { "Axis Status", "cipm.sts.sts", FT_BOOLEAN, 8, TFS(&tfs_true_false), STATUS_DATA_SET_AXIS_STATUS, "Status Data Set: Axis Status", HFILL} }, { &hf_cip_sts_iosts, { "Axis I/O Status", "cipm.sts.iosts", FT_BOOLEAN, 8, TFS(&tfs_true_false), STATUS_DATA_SET_AXIS_IO_STATUS, "Status Data Set: Axis I/O Status", HFILL} }, { &hf_cip_sts_axis_safety, { "Axis Safety Status", "cipm.sts.safety", FT_BOOLEAN, 8, TFS(&tfs_true_false), STATUS_DATA_SET_AXIS_SAFETY, "Status Data Set: Axis Safety Status", HFILL} }, { &hf_cip_intrp, { "Command Target Update", "cipm.intrp", FT_UINT8, BASE_DEC, VALS(cip_interpolation_vals), COMMAND_CONTROL_TARGET_UPDATE, "Cyclic Data Block: Command Target Update", HFILL} }, { &hf_cip_position_data_type, { "Command Position Data Type", "cipm.posdatatype", FT_UINT8, BASE_DEC, VALS(cip_pos_data_type_vals), COMMAND_CONTROL_POSITION_DATA_TYPE, "Cyclic Data Block: Command Position Data Type", HFILL } }, { &hf_cip_axis_state, { "Axis State", "cipm.axste", FT_UINT8, BASE_DEC, VALS(cip_axis_state_vals), 0, "Cyclic Data Block: Axis State", HFILL} }, { &hf_cip_command_control, { "Command Control", "cipm.cmdcontrol", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Command Control", HFILL } }, { &hf_cip_cyclic_wrt_data, { "Write Data", "cipm.writedata", FT_BYTES, BASE_NONE, NULL, 0, "Cyclic Write: Data", HFILL } }, { &hf_cip_cyclic_rd_data, { "Read Data", "cipm.readdata", FT_BYTES, BASE_NONE, NULL, 0, "Cyclic Read: Data", HFILL } }, { &hf_cip_cyclic_write_blk, { "Write Block", "cipm.writeblk", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Write Block Id", HFILL } }, { &hf_cip_cyclic_read_blk, { "Read Block", "cipm.readblk", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Read Block Id", HFILL} }, { &hf_cip_cyclic_write_sts, { "Write Status", "cipm.writests", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Write Status", HFILL } }, { &hf_cip_cyclic_read_sts, { "Read Status", "cipm.readsts", FT_UINT8, BASE_DEC, NULL, 0, "Cyclic Data Block: Read Status", HFILL } }, { &hf_cip_event_checking, { "Event Checking Control", "cipm.evntchkcontrol", FT_UINT32, BASE_HEX, NULL, 0, "Event Channel: Event Checking Control", HFILL} }, { &hf_cip_event_ack, { "Event Acknowledgement", "cipm.evntack", FT_UINT8, BASE_DEC, NULL, 0, "Event Channel: Event Acknowledgement", HFILL} }, { &hf_cip_event_status, { "Event Checking Status", "cipm.evntchkstatus", FT_UINT32, BASE_HEX, NULL, 0, "Event Channel: Event Checking Status", HFILL} }, { &hf_cip_event_id, { "Event Id", "cipm.evntack", FT_UINT8, BASE_DEC, NULL, 0, "Event Channel: Event Id", HFILL } }, { &hf_cip_event_pos, { "Event Position", "cipm.evntpos", FT_INT32, BASE_DEC, NULL, 0, "Event Channel: Event Position", HFILL} }, { &hf_cip_event_ts, { "Event Time Stamp", "cipm.evntimestamp", FT_UINT64, BASE_DEC|BASE_UNIT_STRING, &units_nanosecond_nanoseconds, 0, "Event Channel: Time Stamp", HFILL} }, { &hf_cip_evnt_ctrl_reg1_pos, { "Reg 1 Pos Edge", "cipm.evnt.ctrl.reg1posedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000001, "Event Checking Control: Reg 1 Pos Edge", HFILL} }, { &hf_cip_evnt_ctrl_reg1_neg, { "Reg 1 Neg Edge", "cipm.evnt.ctrl.reg1negedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000002, "Event Checking Control: Reg 1 Neg Edge", HFILL} }, { &hf_cip_evnt_ctrl_reg2_pos, { "Reg 2 Pos Edge", "cipm.evnt.ctrl.reg2posedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000004, "Event Checking Control: Reg 2 Pos Edge", HFILL} }, { &hf_cip_evnt_ctrl_reg2_neg, { "Reg 2 Neg Edge", "cipm.evnt.ctrl.reg2negedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000008, "Event Checking Control: Reg 2 Neg Edge", HFILL} }, { &hf_cip_evnt_ctrl_reg1_posrearm, { "Reg 1 Pos Rearm", "cipm.evnt.ctrl.reg1posrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000100, "Event Checking Control: Reg 1 Pos Rearm", HFILL} }, { &hf_cip_evnt_ctrl_reg1_negrearm, { "Reg 1 Neg Rearm", "cipm.evnt.ctrl.reg1negrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000200, "Event Checking Control: Reg 1 Neg Rearm", HFILL} }, { &hf_cip_evnt_ctrl_reg2_posrearm, { "Reg 2 Pos Rearm", "cipm.evnt.ctrl.reg2posrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000400, "Event Checking Control: Reg 2 Pos Rearm", HFILL} }, { &hf_cip_evnt_ctrl_reg2_negrearm, { "Reg 2 Neg Rearm", "cipm.evnt.ctrl.reg2negrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000800, "Event Checking Control: Reg 2 Neg Rearm", HFILL} }, { &hf_cip_evnt_ctrl_marker_pos, { "Marker Pos Edge", "cipm.evnt.ctrl.mrkrpos", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00010000, "Event Checking Control: Marker Pos Edge", HFILL} }, { &hf_cip_evnt_ctrl_marker_neg, { "Marker Neg Edge", "cipm.evnt.ctrl.mrkrneg", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00020000, "Event Checking Control: Marker Neg Edge", HFILL} }, { &hf_cip_evnt_ctrl_home_pos, { "Home Pos Edge", "cipm.evnt.ctrl.homepos", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00040000, "Event Checking Control: Home Pos Edge", HFILL} }, { &hf_cip_evnt_ctrl_home_neg, { "Home Neg Edge", "cipm.evnt.ctrl.homeneg", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00080000, "Event Checking Control: Home Neg Edge", HFILL} }, { &hf_cip_evnt_ctrl_home_pp, { "Home-Switch-Marker Plus Plus", "cipm.evnt.ctrl.homepp", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00100000, "Event Checking Control: Home-Switch-Marker Plus Plus", HFILL} }, { &hf_cip_evnt_ctrl_home_pm, { "Home-Switch-Marker Plus Minus", "cipm.evnt.ctrl.homepm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00200000, "Event Checking Control: Home-Switch-Marker Plus Minus", HFILL} }, { &hf_cip_evnt_ctrl_home_mp, { "Home-Switch-Marker Minus Plus", "cipm.evnt.ctrl.homemp", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00400000, "Event Checking Control: Home-Switch-Marker Minus Plus", HFILL} }, { &hf_cip_evnt_ctrl_home_mm, { "Home-Switch-Marker Minus Minus", "cipm.evnt.ctrl.homemm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00800000, "Event Checking Control: Home-Switch-Marker Minus Minus", HFILL} }, { &hf_cip_evnt_ctrl_acks, { "Event Block Count", "cipm.evnt.ctrl.acks", FT_UINT32, BASE_DEC, NULL, 0x70000000, "Event Checking Control: Event Block Count", HFILL} }, { &hf_cip_evnt_extend_format, { "Extended Event Format", "cipm.evnt.extend", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x80000000, "Event Checking Control: Extended Event Format", HFILL} }, { &hf_cip_evnt_sts_reg1_pos, { "Reg 1 Pos Edge", "cipm.evnt.sts.reg1posedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000001, "Event Checking Status: Reg 1 Pos Edge", HFILL} }, { &hf_cip_evnt_sts_reg1_neg, { "Reg 1 Neg Edge", "cipm.evnt.sts.reg1negedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000002, "Event Checking Status: Reg 1 Neg Edge", HFILL } }, { &hf_cip_evnt_sts_reg2_pos, { "Reg 2 Pos Edge", "cipm.evnt.sts.reg2posedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000004, "Event Checking Status: Reg 2 Pos Edge", HFILL} }, { &hf_cip_evnt_sts_reg2_neg, { "Reg 2 Neg Edge", "cipm.evnt.sts.reg2negedge", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000008, "Event Checking Status: Reg 2 Neg Edge", HFILL} }, { &hf_cip_evnt_sts_reg1_posrearm, { "Reg 1 Pos Rearm", "cipm.evnt.sts.reg1posrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000100, "Event Checking Status: Reg 1 Pos Rearm", HFILL} }, { &hf_cip_evnt_sts_reg1_negrearm, { "Reg 1 Neg Rearm", "cipm.evnt.sts.reg1negrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000200, "Event Checking Status: Reg 1 Neg Rearm", HFILL} }, { &hf_cip_evnt_sts_reg2_posrearm, { "Reg 2 Pos Rearm", "cipm.evnt.sts.reg2posrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000400, "Event Checking Status: Reg 2 Pos Rearm", HFILL} }, { &hf_cip_evnt_sts_reg2_negrearm, { "Reg 2 Neg Rearm", "cipm.evnt.sts.reg2negrearm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000800, "Event Checking Status: Reg 2 Neg Rearm", HFILL} }, { &hf_cip_evnt_sts_marker_pos, { "Marker Pos Edge", "cipm.evnt.sts.mrkrpos", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00010000, "Event Checking Status: Marker Pos Edge", HFILL} }, { &hf_cip_evnt_sts_marker_neg, { "Marker Neg Edge", "cipm.evnt.sts.mrkrneg", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00020000, "Event Checking Status: Marker Neg Edge", HFILL } }, { &hf_cip_evnt_sts_home_pos, { "Home Pos Edge", "cipm.evnt.sts.homepos", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00040000, "Event Checking Status: Home Pos Edge", HFILL} }, { &hf_cip_evnt_sts_home_neg, { "Home Neg Edge", "cipm.evnt.sts.homeneg", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00080000, "Event Checking Status: Home Neg Edge", HFILL } }, { &hf_cip_evnt_sts_home_pp, { "Home-Switch-Marker Plus Plus", "cipm.evnt.sts.homepp", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00100000, "Event Checking Status: Home-Switch-Marker Plus Plus", HFILL} }, { &hf_cip_evnt_sts_home_pm, { "Home-Switch-Marker Plus Minus", "cipm.evnt.sts.homepm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00200000, "Event Checking Status: Home-Switch-Marker Plus Minus", HFILL} }, { &hf_cip_evnt_sts_home_mp, { "Home-Switch-Marker Minus Plus", "cipm.evnt.sts.homemp", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00400000, "Event Checking Status: Home-Switch-Marker Minus Plus", HFILL} }, { &hf_cip_evnt_sts_home_mm, { "Home-Switch-Marker Minus Minus", "cipm.evnt.sts.homemm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00800000, "Event Checking Status: Home-Switch-Marker Minus Minus", HFILL} }, { &hf_cip_evnt_sts_nfs, { "Event Block Count", "cipm.evnt.sts.nfs", FT_UINT32, BASE_DEC, NULL, 0x70000000, "Event Checking Status: Event Block Count", HFILL} }, { &hf_cip_evnt_sts_stat, { "Event Status", "cipm.evnt.stat", FT_UINT8, BASE_DEC|BASE_EXT_STRING, &cip_gs_vals_ext, 0, "Event Data Block: Event Status", HFILL } }, { &hf_cip_evnt_type, { "Event Type", "cipm.evnt.type", FT_UINT8, BASE_DEC, VALS(cip_event_type_vals), 0, "Event Data Block: Event Type", HFILL} }, { &hf_cip_svc_code, { "Service Code", "cipm.svc.code", FT_UINT8, BASE_HEX, VALS(cip_sc_vals), 0, "Service Data Block: Service Code", HFILL} }, { &hf_cip_svc_sts, { "General Status", "cipm.svc.sts", FT_UINT8, BASE_DEC|BASE_EXT_STRING, &cip_gs_vals_ext, 0, "Service Data Block: General Status", HFILL } }, { &hf_cip_svc_transction, { "Transaction Id", "cipm.svc.tranid", FT_UINT8, BASE_DEC, NULL, 0, "Service Data Block: Transaction Id", HFILL } }, { &hf_cip_svc_ext_status, { "Extended Status", "cipm.svc.extstatus", FT_UINT8, BASE_DEC, NULL, 0, "Service Data Block: Extended Status", HFILL } }, { &hf_cip_svc_data, { "Service Data", "cipm.svc.data", FT_BYTES, BASE_NONE, NULL, 0, "Service Data Block: Data", HFILL } }, { &hf_cip_attribute_data, { "Attribute Data", "cipm.attrdata", FT_BYTES, BASE_NONE, NULL, 0, "Attribute Service: Data", HFILL } }, { &hf_cip_ptp_grandmaster, { "Grandmaster", "cipm.grandmaster", FT_UINT64, BASE_HEX, NULL, 0, "Group Sync: Grandmaster Id", HFILL} }, { &hf_cip_svc_get_axis_attr_sts, { "Attribute Status", "cipm.getaxisattr.sts", FT_UINT8, BASE_DEC|BASE_EXT_STRING, &cip_gs_vals_ext, 0, "Service Channel: Get Axis Attribute List Response Status", HFILL } }, { &hf_get_axis_attr_list_attribute_cnt, { "Number of attributes", "cipm.getaxisattr.cnt", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Attribute Count", HFILL} }, { &hf_get_axis_attr_list_attribute_id, { "Attribute ID", "cipm.getaxisattr.id", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Attribute ID", HFILL} }, { &hf_get_axis_attr_list_dimension, { "Dimension", "cipm.getaxisattr.dimension", FT_UINT8, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Dimension", HFILL} }, { &hf_get_axis_attr_list_element_size, { "Element size", "cipm.getaxisattr.element_size", FT_UINT8, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Element Size", HFILL} }, { &hf_get_axis_attr_list_start_index, { "Start index", "cipm.getaxisattr.start_index", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Start index", HFILL} }, { &hf_get_axis_attr_list_data_elements, { "Data elements", "cipm.getaxisattr.data_elements", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Get Axis Attribute List Data elements", HFILL} }, { &hf_cip_svc_set_axis_attr_sts, { "Attribute Status", "cipm.setaxisattr.sts", FT_UINT8, BASE_DEC|BASE_EXT_STRING, &cip_gs_vals_ext, 0, "Service Channel: Set Axis Attribute List Response Status", HFILL } }, { &hf_set_axis_attr_list_attribute_cnt, { "Number of attributes", "cipm.setaxisattr.cnt", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Attribute Count", HFILL} }, { &hf_set_axis_attr_list_attribute_id, { "Attribute ID", "cipm.setaxisattr.id", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Attribute ID", HFILL} }, { &hf_set_axis_attr_list_dimension, { "Dimension", "cipm.setaxisattr.dimension", FT_UINT8, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Dimension", HFILL} }, { &hf_set_axis_attr_list_element_size, { "Element size", "cipm.setaxisattr.element_size", FT_UINT8, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Element Size", HFILL} }, { &hf_set_axis_attr_list_start_index, { "Start index", "cipm.setaxisattr.start_index", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Start index", HFILL} }, { &hf_set_axis_attr_list_data_elements, { "Data elements", "cipm.setaxisattr.data_elements", FT_UINT16, BASE_DEC, NULL, 0, "Service Channel: Set Axis Attribute List Data elements", HFILL} }, { &hf_set_cyclic_list_attribute_cnt, { "Number of attributes", "cipm.set_cyclic.cnt", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL} }, { &hf_set_cyclic_list_attribute_id, { "Attribute ID", "cipm.set_cyclic.id", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL} }, { &hf_set_cyclic_list_read_block_id, { "Cyclic Read Block ID", "cipm.set_cyclic.read_block_id", FT_UINT16, BASE_DEC, NULL, 0, NULL, HFILL} }, { &hf_set_cyclic_list_attr_sts, { "Attribute Status", "cipm.set_cyclic.sts", FT_UINT8, BASE_DEC | BASE_EXT_STRING, &cip_gs_vals_ext, 0, NULL, HFILL } }, { &hf_var_devce_instance, { "Instance Number", "cipm.var_devce.header.instance", FT_UINT8, BASE_DEC, NULL, 0, "Variable Device Header: Instance Number", HFILL} }, { &hf_var_devce_instance_block_size, { "Instance Block Size", "cipm.var_devce.header.instance_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Instance Block Size", HFILL} }, { &hf_var_devce_cyclic_block_size, { "Cyclic Block Size", "cipm.var_devce.header.cyclic_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Cyclic Block Size", HFILL} }, { &hf_var_devce_cyclic_data_block_size, { "Cyclic Data Block Size", "cipm.var_devce.header.cyclic_data_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Cyclic Data Block Size", HFILL} }, { &hf_var_devce_cyclic_rw_block_size, { "Cyclic Read/Write Block Size", "cipm.var_devce.header.cyclic_rw_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Cyclic Read/Write Block Size", HFILL} }, { &hf_var_devce_event_block_size, { "Event Block Size", "cipm.var_devce.header.event_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Event Block Size", HFILL} }, { &hf_var_devce_service_block_size, { "Service Block Size", "cipm.var_devce.header.service_block_size", FT_UINT8, BASE_DEC|BASE_UNIT_STRING, &units_word_words, 0, "Variable Device Header: Service Block Size", HFILL} }, { &hf_cip_axis_alarm, { "Axis Alarm Code", "cipm.alarm.code", FT_UINT8, BASE_DEC, NULL, 0, "Status Data Set: Alarm Code", HFILL } }, { &hf_cip_axis_sts_local_ctrl, { "Local Control", "cipm.axis.local", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000001, "Axis Status Data Set: Local Control", HFILL } }, { &hf_cip_axis_sts_alarm, { "Alarm", "cipm.axis.alarm", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000002, "Axis Status Data Set: Alarm", HFILL } }, { &hf_cip_axis_sts_dc_bus, { "DC Bus", "cipm.axis.bus", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000004, "Axis Status Data Set: DC Bus", HFILL } }, { &hf_cip_axis_sts_pwr_struct, { "Power Struct", "cipm.axis.pwr", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000008, "Axis Status Data Set: Power Struct", HFILL } }, { &hf_cip_axis_sts_flux_up, { "Motor Flux Up", "cipm.axis.flx", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000010, "Axis Status Data Set: Motor Flux Up", HFILL } }, { &hf_cip_axis_sts_tracking, { "Tracking", "cipm.axis.track", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000020, "Axis Status Data Set: Tracking", HFILL } }, { &hf_cip_axis_sts_pos_lock, { "Pos Lock", "cipm.axis.poslock", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000040, "Axis Status Data Set: Pos Lock", HFILL } }, { &hf_cip_axis_sts_vel_lock, { "Vel Lock", "cipm.axis.vellock", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000080, "Axis Status Data Set: Vel Lock", HFILL } }, { &hf_cip_axis_sts_vel_standstill, { "Vel Standstill", "cipm.axis.nomo", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000100, "Axis Status Data Set: Vel Standstill", HFILL } }, { &hf_cip_axis_sts_vel_threshold, { "Vel Threshold", "cipm.axis.vthresh", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000200, "Axis Status Data Set: Vel Threshold", HFILL } }, { &hf_cip_axis_sts_vel_limit, { "Vel Limit", "cipm.axis.vlim", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000400, "Axis Status Data Set: Vel Limit", HFILL } }, { &hf_cip_axis_sts_acc_limit, { "Acc Limit", "cipm.axis.alim", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000800, "Axis Status Data Set: Acc Limit", HFILL } }, { &hf_cip_axis_sts_dec_limit, { "Decel Limit", "cipm.axis.dlim", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00001000, "Axis Status Data Set: Decel Limit", HFILL } }, { &hf_cip_axis_sts_torque_threshold, { "Torque Threshold", "cipm.axis.tthresh", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00002000, "Axis Status Data Set: Torque Threshold", HFILL } }, { &hf_cip_axis_sts_torque_limit, { "Torque Limit", "cipm.axis.tlim", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00004000, "Axis Status Data Set: Torque Limit", HFILL } }, { &hf_cip_axis_sts_cur_limit, { "Current Limit", "cipm.axis.ilim", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00008000, "Axis Status Data Set: Current Limit", HFILL } }, { &hf_cip_axis_sts_therm_limit, { "Thermal Limit", "cipm.axis.hot", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00010000, "Axis Status Data Set: Thermal Limit", HFILL } }, { &hf_cip_axis_sts_feedback_integ, { "Feedback Integrity", "cipm.axis.fgood", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00020000, "Axis Status Data Set: Feedback Integrity", HFILL } }, { &hf_cip_axis_sts_shutdown, { "Shutdown", "cipm.axis.sdwn", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00040000, "Axis Status Data Set: Shutdown", HFILL } }, { &hf_cip_axis_sts_in_process, { "In Process", "cipm.axis.inp", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00080000, "Axis Status Data Set: In Process", HFILL } }, { &hf_cip_axis_sts_dc_bus_unload, { "DC Bus Unload", "cipm.axis.dcunload", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00100000, "Axis Status Data Set: DC Bus Unload", HFILL } }, { &hf_cip_axis_sts_ac_pwr_loss, { "AC Power Loss", "cipm.axis.acpwrloss", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00200000, "Axis Status Data Set: AC Power Loss", HFILL } }, { &hf_cip_axis_sts_pos_cntrl_mode, { "Pos Control Mode", "cipm.axis.poscntrl", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00400000, "Axis Status Data Set: Position Control Mode", HFILL } }, { &hf_cip_axis_sts_vel_cntrl_mode, { "Vel Control Mode", "cipm.axis.velcntrl", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00800000, "Axis Status Data Set: Velocity Control Mode", HFILL } }, { &hf_cip_axis_sts_trq_cntrl_mode, { "Torque Control Mode", "cipm.axis.trqcntrl", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x01000000, "Axis Status Data Set: Torque Control Mode", HFILL } }, // Attribute #740 - Axis Status 2. { &hf_cip_axis_status2, { "Axis Status 2", "cipm.axisstatus2", FT_UINT32, BASE_HEX, NULL, 0, NULL, HFILL } }, { &hf_cip_axis_sts2_motor, { "Motoring", "cipm.axis2.motor", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000001, NULL, HFILL } }, { &hf_cip_axis_sts2_regenerate, { "Regenerating", "cipm.axis2.regen", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000002, NULL, HFILL } }, { &hf_cip_axis_sts2_ride_thru, { "Ride Thru", "cipm.axis2.ridethru", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000004, NULL, HFILL } }, { &hf_cip_axis_sts2_ac_line_sync, { "AC Line Sync", "cipm.axis2.acsync", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000008, NULL, HFILL } }, { &hf_cip_axis_sts2_bus_volt_lock, { "Bus Voltage Lock", "cipm.axis2.voltlock", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000010, NULL, HFILL } }, { &hf_cip_axis_sts2_react_pwr_only, { "Reactive Power Only Mode", "cipm.axis2.reactpwr", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000020, NULL, HFILL } }, { &hf_cip_axis_sts2_volt_ctrl_mode, { "Voltage Control Mode", "cipm.axis2.voltmode", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000040, NULL, HFILL } }, { &hf_cip_axis_sts2_pwr_loss, { "Power Loss", "cipm.axis2.pwrloss", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000080, NULL, HFILL } }, { &hf_cip_axis_sts2_ac_volt_sag, { "AC Line Voltage Sag", "cipm.axis2.voltsag", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000100, NULL, HFILL } }, { &hf_cip_axis_sts2_ac_phase_loss, { "AC Line Phase Loss", "cipm.axis2.phaseloss", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000200, NULL, HFILL } }, { &hf_cip_axis_sts2_ac_freq_change, { "AC Line Frequency Change", "cipm.axis2.freqchange", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000400, NULL, HFILL } }, { &hf_cip_axis_sts2_ac_sync_loss, { "AC Line Sync Loss", "cipm.axis2.syncloss", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00000800, NULL, HFILL } }, { &hf_cip_axis_sts2_single_phase, { "Single Phase", "cipm.axis2.singlephase", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00001000, NULL, HFILL } }, { &hf_cip_axis_sts2_bus_volt_limit, { "Bus Voltage Limit", "cipm.axis2.bus_volt_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00002000, NULL, HFILL } }, { &hf_cip_axis_sts2_bus_volt_rate_limit, { "Bus Voltage Rate Limit", "cipm.axis2.bus_volt_rate_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00004000, NULL, HFILL } }, { &hf_cip_axis_sts2_active_current_rate_limit, { "Active Current Rate Limit", "cipm.axis2.active_current_rate_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00008000, NULL, HFILL } }, { &hf_cip_axis_sts2_reactive_current_rate_limit, { "Reactive Current Rate Limit", "cipm.axis2.reactive_current_rate_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00010000, NULL, HFILL } }, { &hf_cip_axis_sts2_reactive_pwr_limit, { "Reactive Power Limit", "cipm.axis2.reactive_pwr_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00020000, NULL, HFILL } }, { &hf_cip_axis_sts2_reactive_pwr_rate_limit, { "Reactive Power Rate Limit", "cipm.axis2.reactive_pwr_rate_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00040000, NULL, HFILL } }, { &hf_cip_axis_sts2_active_current_limit, { "Active Current Limit", "cipm.axis2.active_current_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00080000, NULL, HFILL } }, { &hf_cip_axis_sts2_reactive_current_limit, { "Reactive Current Limit", "cipm.axis2.reactive_current_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00100000, NULL, HFILL } }, { &hf_cip_axis_sts2_motor_pwr_limit, { "Motoring Power Limit", "cipm.axis2.motor_pwr_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00200000, NULL, HFILL } }, { &hf_cip_axis_sts2_regen_pwr_limit, { "Regenerative Power Limit", "cipm.axis2.regen_pwr_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00400000, NULL, HFILL } }, { &hf_cip_axis_sts2_convert_therm_limit, { "Converter Thermal Limit", "cipm.axis2.convert_therm_limit", FT_BOOLEAN, 32, TFS(&tfs_true_false), 0x00800000, NULL, HFILL } }, { &hf_cip_act_pos, { "Actual Position", "cipm.actpos", FT_INT32, BASE_DEC, NULL, 0, "Cyclic Data Set: Actual Position", HFILL } }, { &hf_cip_act_pos_64, { "Actual Position", "cipm.actpos_64", FT_INT64, BASE_DEC, NULL, 0, "Cyclic Data Set: Actual Position", HFILL } }, { &hf_cip_act_vel, { "Actual Velocity", "cipm.actvel", FT_FLOAT, BASE_NONE, NULL, 0, "Cyclic Data Set: Actual Velocity", HFILL } }, { &hf_cip_act_accel, { "Actual Acceleration", "cipm.actaccel", FT_FLOAT, BASE_NONE, NULL, 0, "Cyclic Data Set: Actual Acceleration", HFILL } }, { &hf_cip_pos_cmd, { "Position Command", "cipm.posfcmd", FT_DOUBLE, BASE_NONE, NULL, 0, "Cyclic Data Set: Position Command (LREAL)", HFILL } }, { &hf_cip_pos_cmd_int, { "Position Command", "cipm.posicmd", FT_INT32, BASE_DEC, NULL, 0, "Cyclic Data Set: Position Command (DINT)", HFILL } }, { &hf_cip_vel_cmd, { "Velocity Command", "cipm.velcmd", FT_FLOAT, BASE_NONE, NULL, 0, "Cyclic Data Set: Velocity Command", HFILL } }, { &hf_cip_accel_cmd, { "Acceleration Command", "cipm.accelcmd", FT_FLOAT, BASE_NONE, NULL, 0, "Cyclic Data Set: Acceleration Command", HFILL } }, { &hf_cip_trq_cmd, { "Torque Command", "cipm.torquecmd", FT_FLOAT, BASE_NONE, NULL, 0, "Cyclic Data Set: Torque Command", HFILL } }, { &hf_cip_pos_trim, { "Position Trim", "cipm.postrim", FT_INT32, BASE_DEC, NULL, 0, NULL, HFILL } }, { &hf_cip_vel_trim, { "Velocity Trim", "cipm.veltrim", FT_FLOAT, BASE_NONE, NULL, 0, NULL, HFILL } }, { &hf_cip_accel_trim, { "Acceleration Trim", "cipm.acceltrim", FT_FLOAT, BASE_NONE, NULL, 0, NULL, HFILL } }, { &hf_cip_trq_trim, { "Torque Trim", "cipm.trqtrim", FT_FLOAT, BASE_NONE, NULL, 0, NULL, HFILL } }, { &hf_cip_data, { "Data", "cipm.data", FT_BYTES, BASE_NONE, NULL, 0, NULL, HFILL } } }; /* Setup protocol subtree array, these will help Wireshark remember * if the subtree should be expanded as the user moves through packets */ static gint *cip_subtree[] = { &ett_cipmotion, &ett_cont_dev_header, &ett_control_status, &ett_node_control, &ett_node_status, &ett_time_data_set, &ett_inst_data_header, &ett_cyclic_data_block, &ett_cyclic_command_data, &ett_feedback_mode, &ett_connection_configuration_bits, &ett_control_mode, &ett_feedback_config, &ett_command_data_set, &ett_actual_data_set, &ett_status_data_set, &ett_interp_control, &ett_cyclic_rd_wt, &ett_event, &ett_event_check_ctrl, &ett_event_check_sts, &ett_service, &ett_get_axis_attribute, &ett_set_axis_attribute, &ett_get_axis_attr_list, &ett_set_axis_attr_list, &ett_set_cyclic_list, &ett_group_sync, &ett_axis_status_set, &ett_command_control, &ett_configuration_block }; static ei_register_info ei[] = { { &ei_format_rev_conn_pt, { "cipm.malformed.format_revision_mismatch", PI_MALFORMED, PI_WARN, "Format Revision does not match Connection Point", EXPFILL } }, }; /* Create a CIP Motion protocol handle */ proto_cipmotion = proto_register_protocol( "Common Industrial Protocol, Motion", /* Full name of protocol */ "CIP Motion", /* Short name of protocol */ "cipm"); /* Abbreviated name of protocol */ proto_cipmotion3 = proto_register_protocol_in_name_only( "Common Industrial Protocol, Motion - Rev 3", "CIP Motion - Rev 3", "cipm3", proto_cipmotion, FT_PROTOCOL); /* Register the header fields with the protocol */ proto_register_field_array(proto_cipmotion, hf, array_length(hf)); /* Register the subtrees for the protocol dissection */ proto_register_subtree_array(cip_subtree, array_length(cip_subtree)); expert_module_t* expert_cipm = expert_register_protocol(proto_cipmotion); expert_register_field_array(expert_cipm, ei, array_length(ei)); module_t* cipm_module = prefs_register_protocol(proto_cipmotion, NULL); prefs_register_bool_preference(cipm_module, "display_full_attribute_data", "Display full attribute data in the Service Data Block", "Whether the CIP Motion dissector always display the full raw attribute data bytes", &display_full_attribute_data); cipmotion_handle = register_dissector("cipmotion", dissect_cipmotion, proto_cipmotion); cipmotion3_handle = register_dissector("cipmotion3", dissect_cipmotion3, proto_cipmotion3); } void proto_reg_handoff_cipmotion(void) { dissector_add_for_decode_as("cip.io", cipmotion_handle); dissector_add_for_decode_as("cip.io", cipmotion3_handle); dissector_add_uint("cip.io.iface", CI_CLS_MOTION, cipmotion_handle); } /* * Editor modelines - https://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 3 * tab-width: 8 * indent-tabs-mode: nil * End: * * ex: set shiftwidth=3 tabstop=8 expandtab: * :indentSize=3:tabSize=8:noTabs=true: */