# # Copyright (c) 2019-2021 NVIDIA CORPORATION & AFFILIATES. # Apache-2.0 # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # ############################################################################# # Mellanox # # Module contains an implementation of SONiC Platform Base API and # provides the FANs status which are available in the platform # ############################################################################# try: import subprocess import os from sonic_platform_base.sonic_eeprom import eeprom_dts from sonic_py_common.logger import Logger from . import utils from .device_data import DeviceDataManager from sonic_platform_base.sonic_xcvr.sfp_optoe_base import SfpOptoeBase except ImportError as e: raise ImportError (str(e) + "- required module not found") try: # python_sdk_api does not support python3 for now. Daemons like thermalctld or psud # also import this file without actually use the sdk lib. So we catch the ImportError # and ignore it here. Meanwhile, we have to trigger xcvrd using python2 now because it # uses the sdk lib. from python_sdk_api.sxd_api import * from python_sdk_api.sx_api import * except ImportError as e: pass try: if os.environ["PLATFORM_API_UNIT_TESTING"] == "1": # Unable to import SDK constants under unit test # Define them here SX_PORT_MODULE_STATUS_INITIALIZING = 0 SX_PORT_MODULE_STATUS_PLUGGED = 1 SX_PORT_MODULE_STATUS_UNPLUGGED = 2 SX_PORT_MODULE_STATUS_PLUGGED_WITH_ERROR = 3 SX_PORT_MODULE_STATUS_PLUGGED_DISABLED = 4 except KeyError: pass # identifier value of xSFP module which is in the first byte of the EEPROM # if the identifier value falls into SFP_TYPE_CODE_LIST the module is treated as a SFP module and parsed according to 8472 # for QSFP_TYPE_CODE_LIST the module is treated as a QSFP module and parsed according to 8436/8636 # Originally the type (SFP/QSFP) of each module is determined according to the SKU dictionary # where the type of each FP port is defined. The content of EEPROM is parsed according to its type. # However, sometimes the SFP module can be fit in an adapter and then pluged into a QSFP port. # In this case the EEPROM content is in format of SFP but parsed as QSFP, causing failure. # To resolve that issue the type field of the xSFP module is also fetched so that we can know exectly what type the # module is. Currently only the following types are recognized as SFP/QSFP module. # Meanwhile, if the a module's identifier value can't be recognized, it will be parsed according to the SKU dictionary. # This is because in the future it's possible that some new identifier value which is not regonized but backward compatible # with the current format and by doing so it can be parsed as much as possible. SFP_TYPE_CODE_LIST = [ '03' # SFP/SFP+/SFP28 ] QSFP_TYPE_CODE_LIST = [ '0d', # QSFP+ or later '11' # QSFP28 or later ] QSFP_DD_TYPE_CODE_LIST = [ '18' # QSFP-DD Double Density 8X Pluggable Transceiver ] RJ45_TYPE = "RJ45" #variables for sdk REGISTER_NUM = 1 DEVICE_ID = 1 SWITCH_ID = 0 SX_PORT_ATTR_ARR_SIZE = 64 PMAOS_ASE = 1 PMAOS_EE = 1 PMAOS_E = 2 PMAOS_RST = 0 PMAOS_ENABLE = 1 PMAOS_DISABLE = 2 PMMP_LPMODE_BIT = 8 MCION_TX_DISABLE_BIT = 1 #on page 0 #i2c address 0x50 MCIA_ADDR_TX_CHANNEL_DISABLE = 86 MCIA_ADDR_POWER_OVERRIDE = 93 #power set bit MCIA_ADDR_POWER_OVERRIDE_PS_BIT = 1 #power override bit MCIA_ADDR_POWER_OVERRIDE_POR_BIT = 0 #on page 0 #i2c address 0x51 MCIA_ADDR_TX_DISABLE = 110 MCIA_ADDR_TX_DISABLE_BIT = 6 PORT_TYPE_NVE = 8 PORT_TYPE_CPU = 4 PORT_TYPE_OFFSET = 28 PORT_TYPE_MASK = 0xF0000000 NVE_MASK = PORT_TYPE_MASK & (PORT_TYPE_NVE << PORT_TYPE_OFFSET) CPU_MASK = PORT_TYPE_MASK & (PORT_TYPE_CPU << PORT_TYPE_OFFSET) # parameters for SFP presence SFP_STATUS_INSERTED = '1' # SFP constants SFP_PAGE_SIZE = 256 SFP_UPPER_PAGE_OFFSET = 128 SFP_VENDOR_PAGE_START = 640 BYTES_IN_DWORD = 4 # Global logger class instance logger = Logger() # SDK initializing stuff, called from chassis def initialize_sdk_handle(): rc, sdk_handle = sx_api_open(None) if (rc != SX_STATUS_SUCCESS): logger.log_warning("Failed to open api handle, please check whether SDK is running.") sdk_handle = None return sdk_handle def deinitialize_sdk_handle(sdk_handle): if sdk_handle is not None: rc = sx_api_close(sdk_handle) if (rc != SX_STATUS_SUCCESS): logger.log_warning("Failed to close api handle.") return rc == SXD_STATUS_SUCCESS else: logger.log_warning("Sdk handle is none") return False class MlxregManager: def __init__(self, mst_pci_device, slot_id, sdk_index): self.mst_pci_device = mst_pci_device self.slot_id = slot_id self.sdk_index = sdk_index def construct_dword(self, write_buffer): if len(write_buffer) == 0: return None used_bytes_in_dword = len(write_buffer) % BYTES_IN_DWORD res = "dword[0]=0x" for idx, x in enumerate(write_buffer): word = hex(x)[2:] if (idx > 0) and (idx % BYTES_IN_DWORD) == 0: res += ",dword[{}]=0x".format(str((idx + 1)//BYTES_IN_DWORD)) res += word.zfill(2) if used_bytes_in_dword > 0: res += (BYTES_IN_DWORD - used_bytes_in_dword) * "00" return res def write_mlxreg_eeprom(self, num_bytes, dword, device_address, page): if not dword: return False try: cmd = "mlxreg -d /dev/mst/{} --reg_name MCIA --indexes \ slot_index={},module={},device_address={},page_number={},i2c_device_address=0x50,size={},bank_number=0 \ --set {} -y".format(self.mst_pci_device, self.slot_id, self.sdk_index, device_address, page, num_bytes, dword) subprocess.check_call(cmd, shell=True, universal_newlines=True, stdout=subprocess.DEVNULL) except subprocess.CalledProcessError as e: logger.log_error("Error! Unable to write data dword={} for {} port, page {} offset {}, rc = {}, err msg: {}".format(dword, self.sdk_index, page, device_address, e.returncode, e.output)) return False return True def read_mlxred_eeprom(self, offset, page, num_bytes): try: cmd = "mlxreg -d /dev/mst/{} --reg_name MCIA --indexes \ slot_index={},module={},device_address={},page_number={},i2c_device_address=0x50,size={},bank_number=0 \ --get".format(self.mst_pci_device, self.slot_id, self.sdk_index, offset, page, num_bytes) result = subprocess.check_output(cmd, universal_newlines=True, shell=True) except subprocess.CalledProcessError as e: logger.log_error("Error! Unable to read data for {} port, page {} offset {}, rc = {}, err msg: {}".format(self.sdk_index, page, offset, e.returncode, e.output)) return None return result def parse_mlxreg_read_output(self, read_output, num_bytes): if not read_output: return None res = "" dword_num = num_bytes // BYTES_IN_DWORD used_bytes_in_dword = num_bytes % BYTES_IN_DWORD arr = [value for value in read_output.split('\n') if value[0:5] == "dword"] for i in range(dword_num): dword = arr[i].split()[2] res += dword[2:] if used_bytes_in_dword > 0: # Cut needed info and insert into final hex string # Example: 3 bytes : 0x12345600 # ^ ^ dword = arr[dword_num].split()[2] res += dword[2 : 2 + used_bytes_in_dword * 2] return bytearray.fromhex(res) if res else None class SdkHandleContext(object): def __init__(self): self.sdk_handle = None def __enter__(self): self.sdk_handle = initialize_sdk_handle() return self.sdk_handle def __exit__(self, exc_type, exc_val, exc_tb): deinitialize_sdk_handle(self.sdk_handle) class NvidiaSFPCommon(SfpOptoeBase): def __init__(self, sfp_index): super(NvidiaSFPCommon, self).__init__() self.index = sfp_index + 1 self.sdk_index = sfp_index @property def sdk_handle(self): if not SFP.shared_sdk_handle: SFP.shared_sdk_handle = initialize_sdk_handle() if not SFP.shared_sdk_handle: logger.log_error('Failed to open SDK handle') return SFP.shared_sdk_handle @classmethod def _get_module_info(self, sdk_handle, sdk_index): """ Get error code of the SFP module Returns: The error code fetch from SDK API """ module_id_info_list = new_sx_mgmt_module_id_info_t_arr(1) module_info_list = new_sx_mgmt_phy_module_info_t_arr(1) module_id_info = sx_mgmt_module_id_info_t() module_id_info.slot_id = 0 module_id_info.module_id = sdk_index sx_mgmt_module_id_info_t_arr_setitem(module_id_info_list, 0, module_id_info) rc = sx_mgmt_phy_module_info_get(sdk_handle, module_id_info_list, 1, module_info_list) assert SX_STATUS_SUCCESS == rc, "sx_mgmt_phy_module_info_get failed, error code {}".format(rc) mod_info = sx_mgmt_phy_module_info_t_arr_getitem(module_info_list, 0) return mod_info.module_state.oper_state, mod_info.module_state.error_type class SFP(NvidiaSFPCommon): """Platform-specific SFP class""" shared_sdk_handle = None SFP_MLNX_ERROR_DESCRIPTION_LONGRANGE_NON_MLNX_CABLE = 'Long range for non-Mellanox cable or module' SFP_MLNX_ERROR_DESCRIPTION_ENFORCE_PART_NUMBER_LIST = 'Enforce part number list' SFP_MLNX_ERROR_DESCRIPTION_PMD_TYPE_NOT_ENABLED = 'PMD type not enabled' SFP_MLNX_ERROR_DESCRIPTION_PCIE_POWER_SLOT_EXCEEDED = 'PCIE system power slot exceeded' SFP_MLNX_ERROR_DESCRIPTION_RESERVED = 'Reserved' SFP_MLNX_ERROR_BIT_LONGRANGE_NON_MLNX_CABLE = 0x00010000 SFP_MLNX_ERROR_BIT_ENFORCE_PART_NUMBER_LIST = 0x00020000 SFP_MLNX_ERROR_BIT_PMD_TYPE_NOT_ENABLED = 0x00040000 SFP_MLNX_ERROR_BIT_PCIE_POWER_SLOT_EXCEEDED = 0x00080000 SFP_MLNX_ERROR_BIT_RESERVED = 0x80000000 def __init__(self, sfp_index, sfp_type=None, slot_id=0, linecard_port_count=0, lc_name=None): super(SFP, self).__init__(sfp_index) self._sfp_type = sfp_type if slot_id == 0: # For non-modular chassis from .thermal import initialize_sfp_thermal self._thermal_list = initialize_sfp_thermal(sfp_index) else: # For modular chassis # (slot_id % MAX_LC_CONUNT - 1) * MAX_PORT_COUNT + (sfp_index + 1) * (MAX_PORT_COUNT / LC_PORT_COUNT) max_linecard_count = DeviceDataManager.get_linecard_count() max_linecard_port_count = DeviceDataManager.get_linecard_max_port_count() self.index = (slot_id % max_linecard_count - 1) * max_linecard_port_count + sfp_index * (max_linecard_port_count / linecard_port_count) + 1 self.sdk_index = sfp_index from .thermal import initialize_linecard_sfp_thermal self._thermal_list = initialize_linecard_sfp_thermal(lc_name, slot_id, sfp_index) self.slot_id = slot_id self.mst_pci_device = self.get_mst_pci_device() # get MST PCI device name def get_mst_pci_device(self): device_name = None try: device_name = subprocess.check_output("ls /dev/mst/ | grep pciconf", universal_newlines=True, shell=True).strip() except subprocess.CalledProcessError as e: logger.log_error("Failed to find mst PCI device rc={} err.msg={}".format(e.returncode, e.output)) return device_name ''' @property def sdk_handle(self): if not SFP.shared_sdk_handle: SFP.shared_sdk_handle = initialize_sdk_handle() if not SFP.shared_sdk_handle: logger.log_error('Failed to open SDK handle') return SFP.shared_sdk_handle ''' def reinit(self): """ Re-initialize this SFP object when a new SFP inserted :return: """ self.refresh_xcvr_api() def get_presence(self): """ Retrieves the presence of the device Returns: bool: True if device is present, False if not """ eeprom_raw = self.read_eeprom(0, 1) return eeprom_raw is not None # Read out any bytes from any offset def _read_eeprom_specific_bytes(self, offset, num_bytes): if offset + num_bytes > SFP_VENDOR_PAGE_START: logger.log_error("Error mismatch between page size and bytes to read (offset: {} num_bytes: {}) ".format(offset, num_bytes)) return None eeprom_raw = [] ethtool_cmd = "ethtool -m sfp{} hex on offset {} length {}".format(self.index, offset, num_bytes) try: output = subprocess.check_output(ethtool_cmd, shell=True, universal_newlines=True) output_lines = output.splitlines() first_line_raw = output_lines[0] if "Offset" in first_line_raw: for line in output_lines[2:]: line_split = line.split() eeprom_raw = eeprom_raw + line_split[1:] except subprocess.CalledProcessError as e: return None eeprom_raw = list(map(lambda h: int(h, base=16), eeprom_raw)) return bytearray(eeprom_raw) # read eeprom specfic bytes beginning from offset with size as num_bytes def read_eeprom(self, offset, num_bytes): """ Read eeprom specfic bytes beginning from a random offset with size as num_bytes Returns: bytearray, if raw sequence of bytes are read correctly from the offset of size num_bytes None, if the read_eeprom fails Example: mlxreg -d /dev/mst/mt52100_pciconf0 --reg_name MCIA --indexes slot_index=0,module=1,device_address=148,page_number=0,i2c_device_address=0x50,size=16,bank_number=0 -g Sending access register... Field Name | Data =================================== status | 0x00000000 slot_index | 0x00000000 module | 0x00000001 l | 0x00000000 device_address | 0x00000094 page_number | 0x00000000 i2c_device_address | 0x00000050 size | 0x00000010 bank_number | 0x00000000 dword[0] | 0x43726564 dword[1] | 0x6f202020 dword[2] | 0x20202020 dword[3] | 0x20202020 dword[4] | 0x00000000 dword[5] | 0x00000000 .... 16 bytes to read from dword -> 0x437265646f2020202020202020202020 -> Credo """ # recalculate offset and page. Use 'ethtool' if there is no need to read vendor pages if offset < SFP_VENDOR_PAGE_START: return self._read_eeprom_specific_bytes(offset, num_bytes) else: page = (offset - SFP_PAGE_SIZE) // SFP_UPPER_PAGE_OFFSET + 1 # calculate offset per page device_address = (offset - SFP_PAGE_SIZE) % SFP_UPPER_PAGE_OFFSET + SFP_UPPER_PAGE_OFFSET if not self.mst_pci_device: return None mlxreg_mngr = MlxregManager(self.mst_pci_device, self.slot_id, self.sdk_index) read_output = mlxreg_mngr.read_mlxred_eeprom(device_address, page, num_bytes) return mlxreg_mngr.parse_mlxreg_read_output(read_output, num_bytes) # write eeprom specfic bytes beginning from offset with size as num_bytes def write_eeprom(self, offset, num_bytes, write_buffer): """ write eeprom specfic bytes beginning from a random offset with size as num_bytes and write_buffer as the required bytes Returns: Boolean, true if the write succeeded and false if it did not succeed. Example: mlxreg -d /dev/mst/mt52100_pciconf0 --reg_name MCIA --indexes slot_index=0,module=1,device_address=154,page_number=5,i2c_device_address=0x50,size=1,bank_number=0 --set dword[0]=0x01000000 -y """ if num_bytes != len(write_buffer): logger.log_error("Error mismatch between buffer length and number of bytes to be written") return False # recalculate offset and page if offset < SFP_PAGE_SIZE: page = 0 device_address = offset else: page = (offset - SFP_PAGE_SIZE) // SFP_UPPER_PAGE_OFFSET + 1 # calculate offset per page device_address = (offset - SFP_PAGE_SIZE) % SFP_UPPER_PAGE_OFFSET + SFP_UPPER_PAGE_OFFSET if not self.mst_pci_device: return False mlxreg_mngr = MlxregManager(self.mst_pci_device, self.slot_id, self.sdk_index) dword = mlxreg_mngr.construct_dword(write_buffer) return mlxreg_mngr.write_mlxreg_eeprom(num_bytes, dword, device_address, page) @classmethod def mgmt_phy_mod_pwr_attr_get(cls, power_attr_type, sdk_handle, sdk_index, slot_id): sx_mgmt_phy_mod_pwr_attr_p = new_sx_mgmt_phy_mod_pwr_attr_t_p() sx_mgmt_phy_mod_pwr_attr = sx_mgmt_phy_mod_pwr_attr_t() sx_mgmt_phy_mod_pwr_attr.power_attr_type = power_attr_type sx_mgmt_phy_mod_pwr_attr_t_p_assign(sx_mgmt_phy_mod_pwr_attr_p, sx_mgmt_phy_mod_pwr_attr) module_id_info = sx_mgmt_module_id_info_t() module_id_info.slot_id = slot_id module_id_info.module_id = sdk_index try: rc = sx_mgmt_phy_module_pwr_attr_get(sdk_handle, module_id_info, sx_mgmt_phy_mod_pwr_attr_p) assert SX_STATUS_SUCCESS == rc, "sx_mgmt_phy_module_pwr_attr_get failed {}".format(rc) sx_mgmt_phy_mod_pwr_attr = sx_mgmt_phy_mod_pwr_attr_t_p_value(sx_mgmt_phy_mod_pwr_attr_p) pwr_mode_attr = sx_mgmt_phy_mod_pwr_attr.pwr_mode_attr return pwr_mode_attr.admin_pwr_mode_e, pwr_mode_attr.oper_pwr_mode_e finally: delete_sx_mgmt_phy_mod_pwr_attr_t_p(sx_mgmt_phy_mod_pwr_attr_p) def get_lpmode(self): """ Retrieves the lpmode (low power mode) status of this SFP Returns: A Boolean, True if lpmode is enabled, False if disabled """ if utils.is_host(): # To avoid performance issue, # call class level method to avoid initialize the whole sonic platform API get_lpmode_code = 'from sonic_platform import sfp;\n' \ 'with sfp.SdkHandleContext() as sdk_handle:' \ 'print(sfp.SFP._get_lpmode(sdk_handle, {}, {}))'.format(self.sdk_index, self.slot_id) lpm_cmd = "docker exec pmon python3 -c \"{}\"".format(get_lpmode_code) try: output = subprocess.check_output(lpm_cmd, shell=True, universal_newlines=True) return 'True' in output except subprocess.CalledProcessError as e: print("Error! Unable to get LPM for {}, rc = {}, err msg: {}".format(self.sdk_index, e.returncode, e.output)) return False else: return self._get_lpmode(self.sdk_handle, self.sdk_index, self.slot_id) @classmethod def _get_lpmode(cls, sdk_handle, sdk_index, slot_id): """Class level method to get low power mode. Args: sdk_handle: SDK handle sdk_index (integer): SDK port index slot_id (integer): Slot ID Returns: [boolean]: True if low power mode is on else off """ _, oper_pwr_mode = cls.mgmt_phy_mod_pwr_attr_get(SX_MGMT_PHY_MOD_PWR_ATTR_PWR_MODE_E, sdk_handle, sdk_index, slot_id) return oper_pwr_mode == SX_MGMT_PHY_MOD_PWR_MODE_LOW_E def reset(self): """ Reset SFP and return all user module settings to their default state. Returns: A boolean, True if successful, False if not refer plugins/sfpreset.py """ if utils.is_host(): # To avoid performance issue, # call class level method to avoid initialize the whole sonic platform API reset_code = 'from sonic_platform import sfp;\n' \ 'with sfp.SdkHandleContext() as sdk_handle:' \ 'print(sfp.SFP._reset(sdk_handle, {}, {}))' \ .format(self.sdk_index, self.slot_id) reset_cmd = "docker exec pmon python3 -c \"{}\"".format(reset_code) try: output = subprocess.check_output(reset_cmd, shell=True, universal_newlines=True) return 'True' in output except subprocess.CalledProcessError as e: print("Error! Unable to set LPM for {}, rc = {}, err msg: {}".format(self.sdk_index, e.returncode, e.output)) return False else: return self._reset(self.sdk_handle, self.sdk_index, self.slot_id) @classmethod def _reset(cls, sdk_handle, sdk_index, slot_id): module_id_info = sx_mgmt_module_id_info_t() module_id_info.slot_id = slot_id module_id_info.module_id = sdk_index rc = sx_mgmt_phy_module_reset(sdk_handle, module_id_info) if rc != SX_STATUS_SUCCESS: logger.log_error("Error occurred when resetting SFP module {}, slot {}, error code {}".format(sdk_index, slot_id, rc)) return rc == SX_STATUS_SUCCESS @classmethod def is_nve(cls, port): return (port & NVE_MASK) != 0 @classmethod def is_cpu(cls, port): return (port & CPU_MASK) != 0 @classmethod def _fetch_port_status(cls, sdk_handle, log_port): oper_state_p = new_sx_port_oper_state_t_p() admin_state_p = new_sx_port_admin_state_t_p() module_state_p = new_sx_port_module_state_t_p() rc = sx_api_port_state_get(sdk_handle, log_port, oper_state_p, admin_state_p, module_state_p) assert rc == SXD_STATUS_SUCCESS, "sx_api_port_state_get failed, rc = %d" % rc admin_state = sx_port_admin_state_t_p_value(admin_state_p) oper_state = sx_port_oper_state_t_p_value(oper_state_p) delete_sx_port_oper_state_t_p(oper_state_p) delete_sx_port_admin_state_t_p(admin_state_p) delete_sx_port_module_state_t_p(module_state_p) return oper_state, admin_state @classmethod def is_port_admin_status_up(cls, sdk_handle, log_port): _, admin_state = cls._fetch_port_status(sdk_handle, log_port); admin_state == SX_PORT_ADMIN_STATUS_UP @classmethod def set_port_admin_status_by_log_port(cls, sdk_handle, log_port, admin_status): rc = sx_api_port_state_set(sdk_handle, log_port, admin_status) if SX_STATUS_SUCCESS != rc: logger.log_error("sx_api_port_state_set failed, rc = %d" % rc) return SX_STATUS_SUCCESS == rc @classmethod def get_logical_ports(cls, sdk_handle, sdk_index, slot_id): # Get all the ports related to the sfp, if port admin status is up, put it to list port_attributes_list = new_sx_port_attributes_t_arr(SX_PORT_ATTR_ARR_SIZE) port_cnt_p = new_uint32_t_p() uint32_t_p_assign(port_cnt_p, SX_PORT_ATTR_ARR_SIZE) rc = sx_api_port_device_get(sdk_handle, DEVICE_ID , SWITCH_ID, port_attributes_list, port_cnt_p) assert rc == SX_STATUS_SUCCESS, "sx_api_port_device_get failed, rc = %d" % rc port_cnt = uint32_t_p_value(port_cnt_p) log_port_list = [] for i in range(0, port_cnt): port_attributes = sx_port_attributes_t_arr_getitem(port_attributes_list, i) if not cls.is_nve(int(port_attributes.log_port)) \ and not cls.is_cpu(int(port_attributes.log_port)) \ and port_attributes.port_mapping.module_port == sdk_index \ and port_attributes.port_mapping.slot == slot_id \ and cls.is_port_admin_status_up(sdk_handle, port_attributes.log_port): log_port_list.append(port_attributes.log_port) delete_sx_port_attributes_t_arr(port_attributes_list) delete_uint32_t_p(port_cnt_p) return log_port_list @classmethod def mgmt_phy_mod_pwr_attr_set(cls, sdk_handle, sdk_index, slot_id, power_attr_type, admin_pwr_mode): result = False sx_mgmt_phy_mod_pwr_attr = sx_mgmt_phy_mod_pwr_attr_t() sx_mgmt_phy_mod_pwr_mode_attr = sx_mgmt_phy_mod_pwr_mode_attr_t() sx_mgmt_phy_mod_pwr_attr.power_attr_type = power_attr_type sx_mgmt_phy_mod_pwr_mode_attr.admin_pwr_mode_e = admin_pwr_mode sx_mgmt_phy_mod_pwr_attr.pwr_mode_attr = sx_mgmt_phy_mod_pwr_mode_attr sx_mgmt_phy_mod_pwr_attr_p = new_sx_mgmt_phy_mod_pwr_attr_t_p() sx_mgmt_phy_mod_pwr_attr_t_p_assign(sx_mgmt_phy_mod_pwr_attr_p, sx_mgmt_phy_mod_pwr_attr) module_id_info = sx_mgmt_module_id_info_t() module_id_info.slot_id = slot_id module_id_info.module_id = sdk_index try: rc = sx_mgmt_phy_module_pwr_attr_set(sdk_handle, SX_ACCESS_CMD_SET, module_id_info, sx_mgmt_phy_mod_pwr_attr_p) if SX_STATUS_SUCCESS != rc: logger.log_error("Error occurred when setting power mode for SFP module {}, slot {}, error code {}".format(sdk_index, slot_id, rc)) result = False else: result = True finally: delete_sx_mgmt_phy_mod_pwr_attr_t_p(sx_mgmt_phy_mod_pwr_attr_p) return result @classmethod def _set_lpmode_raw(cls, sdk_handle, sdk_index, slot_id, ports, attr_type, power_mode): result = False # Check if the module already works in the same mode admin_pwr_mode, oper_pwr_mode = cls.mgmt_phy_mod_pwr_attr_get(attr_type, sdk_handle, sdk_index, slot_id) if (power_mode == SX_MGMT_PHY_MOD_PWR_MODE_LOW_E and oper_pwr_mode == SX_MGMT_PHY_MOD_PWR_MODE_LOW_E) \ or (power_mode == SX_MGMT_PHY_MOD_PWR_MODE_AUTO_E and admin_pwr_mode == SX_MGMT_PHY_MOD_PWR_MODE_AUTO_E): return True try: # Bring the port down for port in ports: cls.set_port_admin_status_by_log_port(sdk_handle, port, SX_PORT_ADMIN_STATUS_DOWN) # Set the desired power mode result = cls.mgmt_phy_mod_pwr_attr_set(sdk_handle, sdk_index, slot_id, attr_type, power_mode) finally: # Bring the port up for port in ports: cls.set_port_admin_status_by_log_port(sdk_handle, port, SX_PORT_ADMIN_STATUS_UP) return result def set_lpmode(self, lpmode): """ Sets the lpmode (low power mode) of SFP Args: lpmode: A Boolean, True to enable lpmode, False to disable it Note : lpmode can be overridden by set_power_override Returns: A boolean, True if lpmode is set successfully, False if not """ if utils.is_host(): # To avoid performance issue, # call class level method to avoid initialize the whole sonic platform API set_lpmode_code = 'from sonic_platform import sfp;\n' \ 'with sfp.SdkHandleContext() as sdk_handle:' \ 'print(sfp.SFP._set_lpmode({}, sdk_handle, {}, {}))' \ .format('True' if lpmode else 'False', self.sdk_index, self.slot_id) lpm_cmd = "docker exec pmon python3 -c \"{}\"".format(set_lpmode_code) # Set LPM try: output = subprocess.check_output(lpm_cmd, shell=True, universal_newlines=True) return 'True' in output except subprocess.CalledProcessError as e: print("Error! Unable to set LPM for {}, rc = {}, err msg: {}".format(self.sdk_index, e.returncode, e.output)) return False else: return self._set_lpmode(lpmode, self.sdk_handle, self.sdk_index, self.slot_id) @classmethod def _set_lpmode(cls, lpmode, sdk_handle, sdk_index, slot_id): log_port_list = cls.get_logical_ports(sdk_handle, sdk_index, slot_id) sdk_lpmode = SX_MGMT_PHY_MOD_PWR_MODE_LOW_E if lpmode else SX_MGMT_PHY_MOD_PWR_MODE_AUTO_E cls._set_lpmode_raw(sdk_handle, sdk_index, slot_id, log_port_list, SX_MGMT_PHY_MOD_PWR_ATTR_PWR_MODE_E, sdk_lpmode) logger.log_info("{} low power mode for module {}, slot {}".format("Enabled" if lpmode else "Disabled", sdk_index, slot_id)) return True def is_replaceable(self): """ Indicate whether this device is replaceable. Returns: bool: True if it is replaceable. """ return True @classmethod def _get_error_description_dict(cls): return {0: cls.SFP_ERROR_DESCRIPTION_POWER_BUDGET_EXCEEDED, 1: cls.SFP_MLNX_ERROR_DESCRIPTION_LONGRANGE_NON_MLNX_CABLE, 2: cls.SFP_ERROR_DESCRIPTION_I2C_STUCK, 3: cls.SFP_ERROR_DESCRIPTION_BAD_EEPROM, 4: cls.SFP_MLNX_ERROR_DESCRIPTION_ENFORCE_PART_NUMBER_LIST, 5: cls.SFP_ERROR_DESCRIPTION_UNSUPPORTED_CABLE, 6: cls.SFP_ERROR_DESCRIPTION_HIGH_TEMP, 7: cls.SFP_ERROR_DESCRIPTION_BAD_CABLE, 8: cls.SFP_MLNX_ERROR_DESCRIPTION_PMD_TYPE_NOT_ENABLED, 12: cls.SFP_MLNX_ERROR_DESCRIPTION_PCIE_POWER_SLOT_EXCEEDED, 255: cls.SFP_MLNX_ERROR_DESCRIPTION_RESERVED } def get_error_description(self): """ Get error description Args: error_code: The error code returned by _get_module_info Returns: The error description """ oper_status, error_code = self._get_module_info(self.sdk_handle, self.sdk_index) if oper_status == SX_PORT_MODULE_STATUS_INITIALIZING: error_description = self.SFP_STATUS_INITIALIZING elif oper_status == SX_PORT_MODULE_STATUS_PLUGGED: error_description = self.SFP_STATUS_OK elif oper_status == SX_PORT_MODULE_STATUS_UNPLUGGED: error_description = self.SFP_STATUS_UNPLUGGED elif oper_status == SX_PORT_MODULE_STATUS_PLUGGED_DISABLED: error_description = self.SFP_STATUS_DISABLED elif oper_status == SX_PORT_MODULE_STATUS_PLUGGED_WITH_ERROR: error_description_dict = self._get_error_description_dict() if error_code in error_description_dict: error_description = error_description_dict[error_code] else: error_description = "Unknown error ({})".format(error_code) else: error_description = "Unknow SFP module status ({})".format(oper_status) return error_description class RJ45Port(NvidiaSFPCommon): """class derived from SFP, representing RJ45 ports""" def __init__(self, sfp_index): super(RJ45Port, self).__init__(sfp_index) self.sfp_type = RJ45_TYPE @classmethod def _get_presence(cls, sdk_handle, sdk_index): """Class level method to get low power mode. Args: sdk_handle: SDK handle sdk_index (integer): SDK port index slot_id (integer): Slot ID Returns: [boolean]: True if low power mode is on else off """ oper_status, _ = cls._get_module_info(sdk_handle, sdk_index) return print(oper_status == SX_PORT_MODULE_STATUS_PLUGGED) def get_presence(self): """ Retrieves the presence of the device For RJ45 ports, it always return True Returns: bool: True if device is present, False if not """ if utils.is_host(): # To avoid performance issue, # call class level method to avoid initialize the whole sonic platform API get_presence_code = 'from sonic_platform import sfp;\n' \ 'with sfp.SdkHandleContext() as sdk_handle:' \ 'print(sfp.RJ45Port._get_presence(sdk_handle, {}))'.format(self.sdk_index) presence_cmd = "docker exec pmon python3 -c \"{}\"".format(get_presence_code) try: output = subprocess.check_output(presence_cmd, shell=True, universal_newlines=True) return 'True' in output except subprocess.CalledProcessError as e: print("Error! Unable to get presence for {}, rc = {}, err msg: {}".format(self.sdk_index, e.returncode, e.output)) return False else: oper_status, _ = self._get_module_info(self.sdk_handle, self.sdk_index); return (oper_status == SX_PORT_MODULE_STATUS_PLUGGED) def get_transceiver_info(self): """ Retrieves transceiver info of this port. For RJ45, all fields are N/A Returns: A dict which contains following keys/values : ================================================================================ keys |Value Format |Information ---------------------------|---------------|---------------------------- type |1*255VCHAR |type of SFP vendor_rev |1*255VCHAR |vendor revision of SFP serial |1*255VCHAR |serial number of the SFP manufacturer |1*255VCHAR |SFP vendor name model |1*255VCHAR |SFP model name connector |1*255VCHAR |connector information encoding |1*255VCHAR |encoding information ext_identifier |1*255VCHAR |extend identifier ext_rateselect_compliance |1*255VCHAR |extended rateSelect compliance cable_length |INT |cable length in m mominal_bit_rate |INT |nominal bit rate by 100Mbs specification_compliance |1*255VCHAR |specification compliance vendor_date |1*255VCHAR |vendor date vendor_oui |1*255VCHAR |vendor OUI application_advertisement |1*255VCHAR |supported applications advertisement ================================================================================ """ transceiver_info_keys = ['manufacturer', 'model', 'vendor_rev', 'serial', 'vendor_oui', 'vendor_date', 'connector', 'encoding', 'ext_identifier', 'ext_rateselect_compliance', 'cable_type', 'cable_length', 'specification_compliance', 'nominal_bit_rate', 'application_advertisement'] transceiver_info_dict = dict.fromkeys(transceiver_info_keys, 'N/A') transceiver_info_dict['type'] = self.sfp_type return transceiver_info_dict def get_lpmode(self): """ Retrieves the lpmode (low power mode) status of this SFP Returns: A Boolean, True if lpmode is enabled, False if disabled """ return False def reset(self): """ Reset SFP and return all user module settings to their default state. Returns: A boolean, True if successful, False if not refer plugins/sfpreset.py """ return False def set_lpmode(self, lpmode): """ Sets the lpmode (low power mode) of SFP Args: lpmode: A Boolean, True to enable lpmode, False to disable it Note : lpmode can be overridden by set_power_override Returns: A boolean, True if lpmode is set successfully, False if not """ return False def get_error_description(self): """ Get error description Args: error_code: Always false on SN2201 Returns: The error description """ return False def get_transceiver_bulk_status(self): """ Retrieves transceiver bulk status of this SFP Returns: A dict which contains following keys/values : ======================================================================== keys |Value Format |Information ---------------------------|---------------|---------------------------- RX LOS |BOOLEAN |RX lost-of-signal status, | |True if has RX los, False if not. TX FAULT |BOOLEAN |TX fault status, | |True if has TX fault, False if not. Reset status |BOOLEAN |reset status, | |True if SFP in reset, False if not. LP mode |BOOLEAN |low power mode status, | |True in lp mode, False if not. TX disable |BOOLEAN |TX disable status, | |True TX disabled, False if not. TX disabled channel |HEX |disabled TX channles in hex, | |bits 0 to 3 represent channel 0 | |to channel 3. Temperature |INT |module temperature in Celsius Voltage |INT |supply voltage in mV TX bias |INT |TX Bias Current in mA RX power |INT |received optical power in mW TX power |INT |TX output power in mW ======================================================================== """ transceiver_dom_info_dict = {} dom_info_dict_keys = ['temperature', 'voltage', 'rx1power', 'rx2power', 'rx3power', 'rx4power', 'rx5power', 'rx6power', 'rx7power', 'rx8power', 'tx1bias', 'tx2bias', 'tx3bias', 'tx4bias', 'tx5bias', 'tx6bias', 'tx7bias', 'tx8bias', 'tx1power', 'tx2power', 'tx3power', 'tx4power', 'tx5power', 'tx6power', 'tx7power', 'tx8power' ] transceiver_dom_info_dict = dict.fromkeys(dom_info_dict_keys, 'N/A') return transceiver_dom_info_dict def get_transceiver_threshold_info(self): """ Retrieves transceiver threshold info of this SFP Returns: A dict which contains following keys/values : ======================================================================== keys |Value Format |Information ---------------------------|---------------|---------------------------- temphighalarm |FLOAT |High Alarm Threshold value of temperature in Celsius. templowalarm |FLOAT |Low Alarm Threshold value of temperature in Celsius. temphighwarning |FLOAT |High Warning Threshold value of temperature in Celsius. templowwarning |FLOAT |Low Warning Threshold value of temperature in Celsius. vcchighalarm |FLOAT |High Alarm Threshold value of supply voltage in mV. vcclowalarm |FLOAT |Low Alarm Threshold value of supply voltage in mV. vcchighwarning |FLOAT |High Warning Threshold value of supply voltage in mV. vcclowwarning |FLOAT |Low Warning Threshold value of supply voltage in mV. rxpowerhighalarm |FLOAT |High Alarm Threshold value of received power in dBm. rxpowerlowalarm |FLOAT |Low Alarm Threshold value of received power in dBm. rxpowerhighwarning |FLOAT |High Warning Threshold value of received power in dBm. rxpowerlowwarning |FLOAT |Low Warning Threshold value of received power in dBm. txpowerhighalarm |FLOAT |High Alarm Threshold value of transmit power in dBm. txpowerlowalarm |FLOAT |Low Alarm Threshold value of transmit power in dBm. txpowerhighwarning |FLOAT |High Warning Threshold value of transmit power in dBm. txpowerlowwarning |FLOAT |Low Warning Threshold value of transmit power in dBm. txbiashighalarm |FLOAT |High Alarm Threshold value of tx Bias Current in mA. txbiaslowalarm |FLOAT |Low Alarm Threshold value of tx Bias Current in mA. txbiashighwarning |FLOAT |High Warning Threshold value of tx Bias Current in mA. txbiaslowwarning |FLOAT |Low Warning Threshold value of tx Bias Current in mA. ======================================================================== """ transceiver_dom_threshold_info_dict = {} dom_info_dict_keys = ['temphighalarm', 'temphighwarning', 'templowalarm', 'templowwarning', 'vcchighalarm', 'vcchighwarning', 'vcclowalarm', 'vcclowwarning', 'rxpowerhighalarm', 'rxpowerhighwarning', 'rxpowerlowalarm', 'rxpowerlowwarning', 'txpowerhighalarm', 'txpowerhighwarning', 'txpowerlowalarm', 'txpowerlowwarning', 'txbiashighalarm', 'txbiashighwarning', 'txbiaslowalarm', 'txbiaslowwarning' ] transceiver_dom_threshold_info_dict = dict.fromkeys(dom_info_dict_keys, 'N/A') return transceiver_dom_threshold_info_dict def get_reset_status(self): """ Retrieves the reset status of SFP Returns: A Boolean, True if reset enabled, False if disabled for QSFP, originally I would like to make use of Initialization complete flag bit which is at Page a0 offset 6 bit 0 to test whether reset is complete. However as unit testing was carried out I find this approach may fail because: 1. we make use of ethtool to read data on I2C bus rather than to read directly 2. ethtool is unable to access I2C during QSFP module being reset In other words, whenever the flag is able to be retrived, the value is always be 1 As a result, it doesn't make sense to retrieve that flag. Just treat successfully retrieving data as "data ready". for SFP it seems that there is not flag indicating whether reset succeed. However, we can also do it in the way for QSFP. """ return False def read_eeprom(self, offset, num_bytes): return None def reinit(self): """ Nothing to do for RJ45. Just provide it to avoid exception :return: """ return