sonic-buildimage/device/dell/x86_64-dell_z9100_c2538-r0/plugins/sfputil.py

340 lines
9.7 KiB
Python
Raw Normal View History

# sfputil.py
#
# Platform-specific SFP transceiver interface for SONiC
#
try:
import time
from sonic_sfp.sfputilbase import SfpUtilBase
except ImportError as e:
raise ImportError("%s - required module not found" % str(e))
class SfpUtil(SfpUtilBase):
"""Platform-specific SfpUtil class"""
PORT_START = 0
PORT_END = 31
PORTS_IN_BLOCK = 32
IOM_1_PORT_START = 0
IOM_1_PORT_END = 11
IOM_2_PORT_START = 12
IOM_2_PORT_END = 21
IOM_3_PORT_START = 22
IOM_3_PORT_END = 31
BASE_VAL_PATH = "/sys/class/i2c-adapter/i2c-{0}/{0}-003e/"
_port_to_eeprom_mapping = {}
_port_to_i2c_mapping = {
0: [9, 18],
1: [9, 19],
2: [9, 20],
3: [9, 21],
4: [9, 22],
5: [9, 23],
6: [9, 24],
7: [9, 25],
8: [8, 26],
9: [8, 27],
10: [8, 28],
11: [8, 29],
12: [8, 31], # reordered
13: [8, 30],
14: [8, 33], # reordered
15: [8, 32],
16: [7, 34],
17: [7, 35],
18: [7, 36],
19: [7, 37],
20: [7, 38],
21: [7, 39],
22: [7, 40],
23: [7, 41],
24: [6, 42],
25: [6, 43],
26: [6, 44],
27: [6, 45],
28: [6, 46],
29: [6, 47],
30: [6, 48],
31: [6, 49]
}
@property
def port_start(self):
return self.PORT_START
@property
def port_end(self):
return self.PORT_END
@property
def qsfp_ports(self):
return range(0, self.PORTS_IN_BLOCK + 1)
@property
def iom1_port_start(self):
return self.IOM_1_PORT_START
@property
def iom1_port_end(self):
return self.IOM_1_PORT_END
@property
def iom2_port_start(self):
return self.IOM_2_PORT_START
@property
def iom2_port_end(self):
return self.IOM_2_PORT_END
@property
def iom3_port_start(self):
return self.IOM_3_PORT_START
@property
def iom3_port_end(self):
return self.IOM_3_PORT_END
@property
def port_to_eeprom_mapping(self):
return self._port_to_eeprom_mapping
@property
def port_to_i2c_mapping(self):
return self._port_to_i2c_mapping
def __init__(self):
eeprom_path = "/sys/class/i2c-adapter/i2c-{0}/i2c-{1}/{1}-0050/eeprom"
for x in range(0, self.port_end+1):
self.port_to_eeprom_mapping[x] = eeprom_path.format(
self.port_to_i2c_mapping[x][0],
self.port_to_i2c_mapping[x][1])
SfpUtilBase.__init__(self)
def get_presence(self, port_num):
global i2c_line
# Check for invalid port_num
if port_num < self.port_start or port_num > self.port_end:
return False
# port_num and i2c match
if port_num >= self.iom1_port_start and port_num <= self.iom1_port_end:
i2c_line = 14
elif (port_num >= self.iom2_port_start and
port_num <= self.iom2_port_end):
i2c_line = 15
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
i2c_line = 16
try:
qsfp_path = self.BASE_VAL_PATH.format(i2c_line)+"qsfp_modprs"
reg_file = open(qsfp_path, "r")
except IOError as e:
print "Error: unable to open file: %s" % str(e)
return False
content = reg_file.readline().rstrip()
# Absence of IOM throws read error
if (content == 'read error'):
return False
# content is a string containing the hex representation of the register
reg_value = int(content, 16)
# Rationalize port settings
if port_num >= self.iom2_port_start and port_num <= self.iom2_port_end:
port_num = port_num % 12
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
port_num = port_num % 22
# Mask off the bit corresponding to our port
mask = (1 << port_num)
# ModPrsL is active low
if reg_value & mask == 0:
return True
return False
def get_low_power_mode(self, port_num):
# Check for invalid port_num
if port_num < self.port_start or port_num > self.port_end:
return False
# port_num and i2c match
if port_num >= self.iom1_port_start and port_num <= self.iom1_port_end:
i2c_line = 14
elif (port_num >= self.iom2_port_start and
port_num <= self.iom2_port_end):
i2c_line = 15
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
i2c_line = 16
try:
qsfp_path = self.BASE_VAL_PATH.format(i2c_line)+"qsfp_lpmode"
reg_file = open(qsfp_path, "r")
except IOError as e:
print "Error: unable to open file: %s" % str(e)
return False
content = reg_file.readline().rstrip()
# Absence of IOM throws read error
if (content == 'read error'):
return False
# content is a string containing the hex representation of the register
reg_value = int(content, 16)
# Rationalize port settings
if port_num >= self.iom2_port_start and port_num <= self.iom2_port_end:
port_num = port_num % 12
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
port_num = port_num % 22
# Mask off the bit corresponding to our port
mask = (1 << port_num)
# LPMode is active high
if reg_value & mask == 0:
return False
return True
def set_low_power_mode(self, port_num, lpmode):
# Check for invalid port_num
if port_num < self.port_start or port_num > self.port_end:
return False
# port_num and i2c match
if port_num >= self.iom1_port_start and port_num <= self.iom1_port_end:
i2c_line = 14
elif (port_num >= self.iom2_port_start and
port_num <= self.iom2_port_end):
i2c_line = 15
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
i2c_line = 16
try:
qsfp_path = self.BASE_VAL_PATH.format(i2c_line)+"qsfp_lpmode"
reg_file = open(qsfp_path, "r+")
except IOError as e:
print "Error: unable to open file: %s" % str(e)
return False
content = reg_file.readline().rstrip()
# Absence of IOM throws read error
if (content == 'read error'):
return False
# content is a string containing the hex representation of the register
reg_value = int(content, 16)
# Rationalize port settings
if port_num >= self.iom2_port_start and port_num <= self.iom2_port_end:
port_num = port_num % 12
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
port_num = port_num % 22
# Mask off the bit corresponding to our port
mask = (1 << port_num)
# LPMode is active high; set or clear the bit accordingly
if lpmode is True:
reg_value = reg_value | mask
else:
reg_value = reg_value & ~mask
# Convert our register value back to a hex string and write back
content = hex(reg_value)
reg_file.seek(0)
reg_file.write(content)
reg_file.close()
return True
def reset(self, port_num):
# Check for invalid port_num
if port_num < self.port_start or port_num > self.port_end:
return False
# port_num and i2c match
if port_num >= self.iom1_port_start and port_num <= self.iom1_port_end:
i2c_line = 14
elif (port_num >= self.iom2_port_start and
port_num <= self.iom2_port_end):
i2c_line = 15
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
i2c_line = 16
try:
qsfp_path = self.BASE_VAL_PATH.format(i2c_line)+"qsfp_lpmode"
reg_file = open(qsfp_path, "r+")
except IOError as e:
print "Error: unable to open file: %s" % str(e)
return False
content = reg_file.readline().rstrip()
# File content is a string containing the hex representation of th
reg_value = int(content, 16)
# Rationalize port settings
if port_num >= self.iom2_port_start and port_num <= self.iom2_port_end:
port_num = port_num % 12
elif (port_num >= self.iom3_port_start and
port_num <= self.iom3_port_end):
port_num = port_num % 22
# Mask off the bit corresponding to our port
mask = (1 << port_num)
# ResetL is active low
reg_value = reg_value & ~mask
# Convert our register value back to a hex string and write back
reg_file.seek(0)
reg_file.write(hex(reg_value))
reg_file.close()
# Sleep 1 second to allow it to settle
time.sleep(1)
# Flip the bit back high and write back to the register to take
# port out of reset
try:
qsfp_path = self.BASE_VAL_PATH.format(i2c_line)+"qsfp_lpmode"
reg_file = open(qsfp_path, "w+")
except IOError as e:
print "Error: unable to open file: %s" % str(e)
return False
reg_value = reg_value | mask
reg_file.seek(0)
reg_file.write(hex(reg_value))
reg_file.close()
return True