|This is the name of the interface; the default is "lmc0". If netgraph(4) is present and the interface name ends with a colon then Netgraph control messages are used, otherwise the ifnet(9) kernel interface and socket ioctl(2) system calls are used.|
|-1||All parameters after this apply to the T1E1 card.|
|-3||All parameters after this apply to the T3 card.|
The following parameters apply to more than one card type.
-a number Set Transmitter clock source to number.
1 TxClk from modem T1E1, HSSI default
2 Internal source T1E1, HSSI
3 RxClk from modem T1E1, HSSIc loop timed
4 External connector T1E1, HSSIc
An HSSI card normally takes its Tx clock from the modem connector (it is a DTE) but can use the PCI bus clock (typically 33 MHz) for loopback and null modem testing; values 3 and 4 are only applicable to a few rare CompactPCI/HSSI cards.
A T1E1 card uses an on-board synthesized oscillator if the value is 1 or 2; it loop times (uses the clock recovered by the receiver as the transmitter clock) if the value is 3; and it uses a clock from a header connector on the card if the value is 4.
TxClk source is not applicable to other card types.
-b Read BIOS ROM. Print the first 256 locations. The BIOS ROM is not used and not present on some cards. -B Write BIOS ROM. Write the first 256 locations with an address pattern. -c Use HDLCs 16-bit CRC polynomial: X^16+X^12+X^5+1 (default). -C Use HDLCs 32-bit CRC polynomial: X^32+X^26+X^23+X^22+X^16+X^12+X^11+X^10+X^8+X^7+X^5+X^4+X^2+X+1 -d Clear the driver-level debug flag. Non-critical log messages are suppressed. -D Set the driver-level debug flag. The driver generates more log messages. The driver also generates more log messages if the interface-level debug flag is set by ifconfig(8). -e Set DTE (Data Terminal Equipment) mode (default). An SSI card transmitter uses the Tx clock signal from the modem connector and receives the Data Carrier Detect pin (DCD). DTE/DCE is not applicable to other card types except a few rare CompactPCI/HSSI cards. -E Set DCE (Data Communication Equipment) mode. An SSI card transmitter uses an on-board synthesized oscillator and drives the Data Carrier Detect pin (DCD). -f number Set the frequency of the built-in synthesized oscillator to number bits/second. The nearest frequency that the synthesizer can generate will be used. Only SSI cards and a few rare CompactPCI/HSSI cards have synthesizers. -F Set SPPP line protocol to Frame-Relay. Only works for
.Fx 5.4 and later.
-h Print help (usage message). -i Set interface name (e.g. "lmc0"). -L number Set loopback mode to number.
1 none default
2 payload outward thru framer T1E1. T3
3 line outward thru line if T1E1, T3, HSSIc
4 other inward thru line if T1E1, T3
5 inward inward thru framer T1E1, T3
6 dual inward and outward T1E1, T3
16 tulip inward thru Tulip chip all cards
17 pins inward thru drvrs/rcvrs SSI
18 LA/LL assert LA/LL modem pin HSSI, SSI
19 LB/RL assert LB/RL modem pin HSSI, SSI
-m Read Tulip MII registers. Print the 32 16-bit registers in the Media Independent Interface. -M addr data Write Tulip MII register. Write data into register addr. -p Read Tulip PCI configuration registers. Print the first 16 32-bit registers in the PCI configuration space. -P addr data Write Tulip PCI configuration register. Write data into register addr. -s Read Tulip SROM. Print the 64 16-bit locations. The PCI subsystem vendor and device IDs are kept here. -S number Write Tulip SROM. Initializes the Tulip SROM to card type number.
0 auto-set from MII PHYID
If number is zero, then the card type is computed from the gate array microcode version field in the MII PHYID register. CAUTION: if the SROM is incorrect, the card will be unusable! This command is so dangerous that lmcconfig must be edited and recompiled to enable it.
-t Read Tulip CSRs. Print the 16 32-bit control and status registers. -T addr data Write Tulip CSR. Write data into CSR number addr. Note that addr is a CSR number (0-15) not a byte offset into CSR space. -u Reset event counters to zero. The driver counts events like packets in and out, errors, discards, etc. The time when the counters are reset is remembered. -U Reset gate array. Not needed during normal operation; just for testing. -v Set verbose mode: print more stuff. -V Print the card configuration [em] see the EXAMPLES section. -w Load gate array from on-board ROM. Not needed during normal operation; just for testing. -W filename Load gate array microcode from filename. -x Select RAWIP mode [em] bypass line protocol code. -X Select line protocol code rather than RAWIP mode. -y Disable SPPP keep-alive packets. -Y Enable SPPP keep-alive packets. -z Set SPPP line protocol to Cisco-HDLC. -Z Set SPPP line protocol to PPP. -? Print help (usage message).
The following parameters apply to the T1E1 card type:
-a -Sm y | a | b Sm Stop sending alarm signal.
y Yellow Alarm varies with framing
a Red Alarm unframed all ones; aka AIS
b Blue Alarm unframed all ones
Red alarm, also known as AIS (Alarm Indication Signal), and Blue alarm are identical in T1.
-A -Sm y | a | b Sm Start sending alarm signal (see table above). -B number Send a Bit Oriented Protocol (BOP) message with code number. BOP codes are six bits. -c number Set cable length to number meters (default: 10 meters). This is used to set receiver sensitivity and transmitter line build-out. -d Print the status of the on-board DSU/CSU [em] see the EXAMPLES section. -e number Set the framing format to number:
27 T1-ESF/B8ZS (default)
-E number Enable 64Kb time slots (TSs) for the T1E1 card. The number argument is a 32-bit hex number (default 0xFFFFFFFF). The LSB is TS0 and the MSB is TS31. TS0 and TS25-31 are ignored in T1 mode. TS0 and TS16 are determined by the framing format in E1 mode. -f Read framer registers. Print the 512 8-bit registers in the framer chip. -F addr data Write framer register. Write data into register addr. -g number Set receiver gain range to number:
0x24 Short 0 to 20 dB of equalized gain
0x2C Medium 0 to 30 dB of equalized gain
0x34 Long 0 to 40 dB of equalized gain
0x3F Extend 0 to 64 dB of equalized gain (wide open)
0xFF Auto auto-set based on cable length (default)
This sets the level at which Loss-Of-Signal is declared.
-i Send a CSU loopback deactivate inband command (T1-SF only). -I Send a CSU loopback activate inband command (T1-SF only). -l Send a line loopback deactivate BOP message (T1-ESF only). -L Send a line loopback activate BOP message (T1-ESF only). -p Send a payload loopback deactivate BOP message (T1-ESF only). -P Send a payload loopback activate BOP message (T1-ESF only). -s Print the status of the on-board DSU/CSU [em] see the EXAMPLES section. -t Stop sending test pattern. -T number Start sending test pattern number:
0 unframed X^11+X^9+1
1 unframed X^15+X^14+1
2 unframed X^20+X^17+1
3 unframed X^23+X^18+1
4 unframed X^11+X^9+1 with 7ZS
5 unframed X^15+X^14+1 with 7ZS
6 unframed X^20+X^17+1 with 14ZS (QRSS)
7 unframed X^23+X^18+1 with 14ZS
8 framed X^11+X^9+1
9 framed X^15+X^14+1
10 framed X^20+X^17+1
11 framed X^23+X^18+1
12 framed X^11+X^9+1 with 7ZS
13 framed X^15+X^14+1 with 7ZS
14 framed X^20+X^17+1 with 14ZS (QRSS)
15 framed X^23+X^18+1 with 14ZS
-u number Set transmit pulse shape to number:
0 T1 DSX 0 to 40 meters
2 T1 DSX 40 to 80 meters
4 T1 DSX 80 to 120 meters
6 T1 DSX 120 to 160 meters
8 T1 DSX 160 to 200 meters
10 E1 75-ohm coax pair
12 E1 120-ohm twisted pairs
14 T1 CSU 200 to 2000 meters; set LBO
255 auto-set based on cable length and framing format (default)
-U number Set transmit line build-out to number:
0 0 dB FCC option A
16 7.5 dB FCC option B
32 15 dB FCC option C
48 22.5 dB final span
255 auto-set based on cable length (default)
This is only applicable if the pulse shape is T1-CSU.
-v Set verbose mode: print more stuff. -x Disable transmitter outputs. -X Enable transmitter outputs.
The following parameters apply to the T3 card type:
-a -Sm y | a | b | i Sm Stop sending alarm signal.
y Yellow Alarm X-bits set to 0
a Red Alarm framed 1010... aka AIS
b Blue Alarm unframed all-ones
i Idle signal framed 11001100...
-A -Sm y | a | b | i Sm Start sending alarm signal (see table above). -B number Send a BOP (Bit Oriented Protocol) message with code number. BOP codes are six bits. -c number Set cable length to number meters (default: 10 meters). This is used to set receiver sensitivity and transmitter line build-out. -d Print the status of the on-board T3 DSU [em] see the EXAMPLES section. -e number Set the framing format to number:
100 T3-C-bit parity
101 T3-M13 format
Payload scrambler polynomials are not standardized.
-f Read framer registers. Print the 22 8-bit registers in the framer chip. -F addr data Write framer register. Write data into register addr. -l Send a line loopback deactivate BOP message. -L Send a line loopback activate BOP message. -s Print the status of the on-board T3 DSU [em] see the EXAMPLES section. -S number Set payload scrambler polynomial to number:
1 payload scrambler disabled
2 X^43+1: DigitalLink and Kentrox
3 X^20+X^17+1 w/28ZS: Larscom
-v Set verbose mode: print more stuff. -V number Set transmit frequency offset to number. Some T3 cards can offset the transmitter frequency from 44.736 MHz. Number is in the range (0..4095); 2048 is zero offset; step size is about 3 Hz. A number is written to a Digital-Analog Converter (DAC) which connects to a Voltage Controlled Crystal Oscillator (VCXO).
The device driver counts many interesting events such as packets in and out, errors and discards. The table below lists the event counters and describes what they count.
ibytes Bytes received in packets with good ending status. obytes Bytes transmitted. ipackets Packets received with good ending status. opackets Packets transmitted. ierrors Packets received with bad ending status. oerrors Packets transmitted with bad ending status. idiscards Packets received but discarded because the input queue was full or the interface was down. odiscards Packets presented for transmission but discarded because the output queue was full or the interface was down. txdma Packets presented for transmission but queued and retried later because no DMA descriptors were available. This can happen during normal operation and is not an indication of trouble. fifo-overrun Packets that started to arrive, but were aborted because the card was unable to DMA data to memory fast enough to prevent the receiver fifo from overflowing. fifo-underrun Packets that started to transmit but were aborted because the card was unable to DMA data from the memory fast enough to prevent the transmitter fifo from underflowing. When this happens, the transmitter threshold is increased, so that more bytes are required to be in the fifo before the transmitter is started. missed Packets that are missed because the receiver is stopped. overruns Packets that are missed because the receiver had no DMA descriptors available. fdl_pkts Packets received on the T1 Facility Data Link. crc-errs Cyclic Redundancy Checksum errors detected by the CRC-6 in T1 Extended SuperFrames (ESF) or the CRC-4 in E1 frames. lcv-errs Line Coding Violation errors: Alternate Mark Inversion (AMI) errors for T1-SF, Bipolar 8-Zero Substitution (B8ZS) errors for T1-ESF, or High Density Bipolar with 3-Zero Substitution (HDB3) errors for E1 or Bipolar 3-Zero Substitution (B3ZS) errors for T3. frm-errs T1 or T3 bit errors in the frame alignment signal. febe-errs Far End Block Errors: T1 or T3 bit errors detected by the device at the far end of the link. par-errs T3 bit errors detected by the hop-by-hop parity mechanism. cpar-errs T3 bit errors detected by the end-to-end parity mechanism. mfrm-errs T3 bit errors in the multi-frame alignment signal.
The hardware counts transmit clocks divided by 2048. The software computes "Tx speed" from this (see EXAMPLES below). The transmit clock is the bit rate of the circuit divided by two if the circuit is idle and divided by four if the circuit is carrying a packet. So an idle circuit reports a Tx speed equal to its bit rate, and a busy circuit reports a Tx speed equal to half its bit rate.
This "bit rate" does not include circuit-level overhead bits (such as T1 or T3 frame bits) but does include HDLC stuff bits. An idle T1 circuit with a raw bit rate of 1544000 and a bit-rate-minus-overhead of 1536000 will report a "Tx speed" of ((1536000 bitand 4095) plus or minus 4096). Sometimes it will even get the correct answer of 1536000, and if the link is fully loaded it will report about 768000 bits/sec.
It is not a perfect bit rate meter (the circuit must be idle), but it is a useful circuit utilization meter if you know the circuit bit rate and do some arithmetic. Software recalculates Tx speed once a second; the measurement period has some jitter.
When "lmc0" is a T1E1 card, "lmcconfig lmc0" generates the following output:Card name: lmc0 Card type: SBE/LMC T1E1 card Link status: Up Tx Speed: 1548288 Line Prot/Pkg: Frame-Relay/SPPP SPPP Keep-alives: OFF CRC length: 16 bits Loopback: None Tx Clk src: Internal source Format-Frame/Code: T1-ESF/B8ZS TimeSlot [31-0]: 0x01FFFFFE Cable length: 10 meters Tx pulse shape: auto-set to T1-DSX: 0 to 40 meters Rx gain max: auto-set to 20.0 dB Current time: Thu Sep 29 21:48:51 2005 Cntrs reset: Thu Sep 29 16:21:05 2005 RX bytes: 15053836 RX packets: 23271 TX bytes: 1732169 TX packets: 20526 Rx fdl pkts: 5443
When "lmc0" is a T1E1 card, "lmcconfig lmc0 -1 -d" generates the following output:Format-Frame/Code: T1-ESF/B8ZS TimeSlot [31-0]: 0x01FFFFFE Tx Clk src: Internal source Tx Speed: 1548288 Tx pulse shape: T1-DSX: 0 to 40 meters Tx outputs: Enabled Line impedance: 100 ohms Max line loss: 20.0 dB Cur line loss: 3.1 dB Invert data: No Line loop: No Payload loop: No Framer loop: No Analog loop: No Tx AIS: No Rx AIS: No Tx BOP RAI: No Rx BOP RAI: No Rx LOS analog: No Rx LOS digital: No Rx LOF: No Tx QRS: No Rx QRS: No LCV errors: 0 CRC errors: 0 Frame errors: 0 Sev Err Frms: 0 Change of Frm align: 0 Loss of Frame events: 0 Last Tx BOP msg: 0x00 (Yellow Alarm (far end LOF)) Last Rx BOP msg: 0x00 (Yellow Alarm (far end LOF)) SNMP Near-end performance data: LCV=0 LOS=0 FE=0 CRC=0 AIS=0 SEF=0 OOF=0 RAI=0 ANSI Far-end performance reports: SEQ=1 CRC=0 SE=0 FE=0 LV=0 SL=0 LB=0 SEQ=0 CRC=0 SE=0 FE=0 LV=0 SL=0 LB=0 SEQ=3 CRC=0 SE=0 FE=0 LV=0 SL=0 LB=0 SEQ=2 CRC=0 SE=0 FE=0 LV=0 SL=0 LB=0
Messages indicating the specified interface does not exist, or the user is not privileged and tried to alter an interfaces configuration.
This is a total rewrite of the program lmcctl by
.An Andrew Stanley-Jones .
.An David Boggs Aq firstname.lastname@example.org