6. Testing the Driver#
6.1. Preliminary Setup#
The network used to test the driver should include at least:
The hardware on which the driver is to run. It makes testing much easier if you can run a debugger to control the operation of the target machine.
An Ethernet network analyzer or a workstation with an ‘Ethernet snoop’ program such as
ethersnoop
ortcpdump
.A workstation.
During early debug, you should consider putting the target, workstation, and snooper on a small network by themselves. This offers a few advantages:
There is less traffic to look at on the snooper and for the target to process while bringing the driver up.
Any serious errors will impact only your small network not a building or campus network. You want to avoid causing any unnecessary problems.
Test traffic is easier to repeatably generate.
Performance measurements are not impacted by other systems on the network.
6.2. Debug Output#
There are a number of sources of debug output that can be enabled to aid in tracing the behavior of the network stack. The following is a list of them:
mbuf activity There are commented out calls to
printf
in the filesys/mbuf.h
in the network stack code. Uncommenting these lines results in output when mbuf’s are allocated and freed. This is very useful for finding memory leaks.TX and RX queuing There are commented out calls to
printf
in the filenet/if.h
in the network stack code. Uncommenting these lines results in output when packets are placed on or removed from one of the transmit or receive packet queues. These queues can be viewed as the boundary line between a device driver and the network stack. If the network stack is enqueuing packets to be transmitted that the device driver is not dequeuing, then that is indicative of a problem in the transmit side of the device driver. Conversely, if the device driver is enqueueing packets as it receives them (via a call toether_input
) and they are not being dequeued by the network stack, then there is a problem. This situation would likely indicate that the network server task is not running.TCP state transitions
In the unlikely event that one would actually want to see TCP state transitions, the
TCPDEBUG
macro can be defined in the fileopt_tcpdebug.h
. This results in the routinetcp_trace()
being called by the network stack and the state transitions logged into thetcp_debug
data structure. If the variabletcpconsdebug
in the filenetinet/tcp_debug.c
is set to1
, then the state transitions will also be printed to the console.
6.3. Monitor Commands#
There are a number of command available in the shell / monitor to aid in tracing the behavior of the network stack. The following is a list of them:
inet
This command shows the current routing information for the TCP/IP stack. Following is an example showing the output of this command.Destination Gateway/Mask/Hw Flags Refs Use Expire Interface 10.0.0.0 255.0.0.0 U 0 0 17 smc1 127.0.0.1 127.0.0.1 UH 0 0 0 lo0
In this example, there is only one network interface with an IP address of 10.8.1.1. This link is currently not up. Two routes that are shown are the default routes for the Ethernet interface (10.0.0.0) and the loopback interface (127.0.0.1). Since the stack comes from BSD, this command is very similar to the netstat command. For more details on the network routing please look the following URL: (http://www.freebsd.org/doc/en_US.ISO8859-1/books/handbook/network-routing.html) For a quick reference to the flags, see the table below:
- ‘
U
’ Up: The route is active.
- ‘
H
’ Host: The route destination is a single host.
- ‘
G
’ Gateway: Send anything for this destination on to this remote system, which will figure out from there where to send it.
- ‘
S
’ Static: This route was configured manually, not automatically generated by the system.
- ‘
C
’ Clone: Generates a new route based upon this route for machines we connect to. This type of route is normally used for local networks.
- ‘
W
’ WasCloned: Indicated a route that was auto-configured based upon a local area network (Clone) route.
- ‘
L
’ Link: Route involves references to Ethernet hardware.
- ‘
mbuf
This command shows the current MBUF statistics. An example of the command is shown below:************ MBUF STATISTICS ************ mbufs:4096 clusters: 256 free: 241 drops: 0 waits: 0 drains: 0 free:4080 data:16 header:0 socket:0 pcb:0 rtable:0 htable:0 atable:0 soname:0 soopts:0 ftable:0 rights:0 ifaddr:0 control:0 oobdata:0
if
This command shows the current statistics for your Ethernet driver as long as the ioctl hookSIO_RTEMS_SHOW_STATS
has been implemented. Below is an example:************ INTERFACE STATISTICS ************ ***** smc1 ***** Ethernet Address: 00:12:76:43:34:25 Address:10.8.1.1 Broadcast Address:10.255.255.255 Net mask:255.0.0.0 Flags: Up Broadcast Running Simplex Send queue limit:50 length:0 Dropped:0 SMC91C111 RTEMS driver A0.01 11/03/2002 Ian Caddy (ianc@microsol.iinet.net.au) Rx Interrupts:0 Not First:0 Not Last:0 Giant:0 Runt:0 Non-octet:0 Bad CRC:0 Overrun:0 Collision:0 Tx Interrupts:2 Deferred:0 Missed Hearbeat:0 No Carrier:0 Retransmit Limit:0 Late Collision:0 Underrun:0 Raw output wait:0 Coalesced:0 Coalesce failed:0 Retries:0 ***** lo0 ***** Address:127.0.0.1 Net mask:255.0.0.0 Flags: Up Loopback Running Multicast Send queue limit:50 length:0 Dropped:0
ip
This command show the IP statistics for the currently configured interfaces.icmp
This command show the ICMP statistics for the currently configured interfaces.tcp
This command show the TCP statistics for the currently configured interfaces.udp
This command show the UDP statistics for the currently configured interfaces.
6.4. Driver basic operation#
The network demonstration program netdemo
may be used for these tests.
Edit
networkconfig.h
to reflect the values for your network.Start with
RTEMS_USE_BOOTP
not defined.Edit
networkconfig.h
to configure the driver with an explicit Ethernet and Internet address and with reception of broadcast packets disabled: Verify that the program continues to run once the driver has been attached.Issue a ‘
u
’ command to send UDP packets to the ‘discard’ port. Verify that the packets appear on the network.Issue a ‘
s
’ command to print the network and driver statistics.On a workstation, add a static route to the target system.
On that same workstation try to ‘ping’ the target system. Verify that the ICMP echo request and reply packets appear on the net.
Remove the static route to the target system. Modify
networkconfig.h
to attach the driver with reception of broadcast packets enabled. Try to ‘ping’ the target system again. Verify that ARP request/reply and ICMP echo request/reply packets appear on the net.Issue a ‘
t
’ command to send TCP packets to the ‘discard’ port. Verify that the packets appear on the network.Issue a ‘
s
’ command to print the network and driver statistics.Verify that you can telnet to ports 24742 and 24743 on the target system from one or more workstations on your network.
6.5. BOOTP/DHCP operation#
Set up a BOOTP/DHCP server on the network. Set define RTEMS USE_BOOT
in
networkconfig.h
. Run the netdemo
test program. Verify that the target
system configures itself from the BOOTP/DHCP server and that all the above
tests succeed.
6.6. Stress Tests#
Once the driver passes the tests described in the previous section it should be subjected to conditions which exercise it more thoroughly and which test its error handling routines.
6.6.1. Giant packets#
Recompile the driver with
MAXIMUM_FRAME_SIZE
set to a smaller value, say 514.‘Ping’ the driver from another workstation and verify that frames larger than 514 bytes are correctly rejected.
Recompile the driver with
MAXIMUM_FRAME_SIZE
restored to 1518.
6.6.2. Resource Exhaustion#
Edit
networkconfig.h
so that the driver is configured with just two receive and transmit descriptors.Compile and run the
netdemo
program.Verify that the program operates properly and that you can still telnet to both the ports.
Display the driver statistics (Console ‘
s
’ command or telnet ‘control-G’ character) and verify that:The number of transmit interrupts is non-zero. This indicates that all transmit descriptors have been in use at some time.
The number of missed packets is non-zero. This indicates that all receive descriptors have been in use at some time.
6.6.3. Cable Faults#
Run the
netdemo
program.Issue a ‘
u
’ console command to make the target machine transmit a bunch of UDP packets.While the packets are being transmitted, disconnect and reconnect the network cable.
Display the network statistics and verify that the driver has detected the loss of carrier.
Verify that you can still telnet to both ports on the target machine.
6.6.4. Throughput#
Run the ttcp
network benchmark program. Transfer large amounts of data
(100’s of megabytes) to and from the target system.
The procedure for testing throughput from a host to an RTEMS target is as follows:
Download and start the ttcp program on the Target.
In response to the
ttcp
prompt, enter-s -r
. The meaning of these flags is described in thettcp.1
manual page found in thettcp_orig
subdirectory.On the host run
ttcp -s -t <<insert the hostname or IP address of the Target here>>
The procedure for testing throughput from an RTEMS target to a Host is as follows:
On the host run
ttcp -s -r
.Download and start the ttcp program on the Target.
In response to the
ttcp
prompt, enter-s -t <<insert the hostname or IP address of the Target here>>
. You need to type the IP address of the host unless your Target is talking to your Domain Name Server.
To change the number of buffers, the buffer size, etc. you just add the extra
flags to the -t
machine as specified in the ttcp.1
manual page found in
the ttcp_orig
subdirectory.