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165 lines
5.2 KiB
165 lines
5.2 KiB
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Very funky action. I do plan to add to a few more things to it
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This is the basic stuff. Idea borrowed from the way ethernet switches
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mirror and redirect packets. The main difference with say a vannila
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ethernet switch is that you can use u32 classifier to select a
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flow to be mirrored. High end switches typically can select based
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on more than just a port (eg a 5 tuple classifier). They may also be
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capable of redirecting.
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Usage:
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mirred <DIRECTION> <ACTION> [index INDEX] <dev DEVICENAME>
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where:
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DIRECTION := <ingress | egress>
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ACTION := <mirror | redirect>
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INDEX is the specific policy instance id
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DEVICENAME is the devicename
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Direction:
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- Ingress is not supported at the moment. It will be in the
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future as well as mirror/redirecting to a socket.
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Action:
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- Mirror takes a copy of the packet and sends it to specified
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dev ("port" in ethernet switch/bridging terminology)
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- redirect
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steals the packet and redirects to specified destination dev.
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What NOT to do if you dont want your machine to crash:
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------------------------------------------------------
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Do not create loops!
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Loops are not hard to create in the egress qdiscs.
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Here are simple rules to follow if you dont want to get
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hurt:
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A) Do not have the same packet go to same netdevice twice
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in a single graph of policies. Your machine will just hang!
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This is design intent _not a bug_ to teach you some lessons.
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In the future if there are easy ways to do this in the kernel
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without affecting other packets not interested in this feature
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I will add them. At the moment that is not clear.
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Some examples of bad things NOT to do:
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1) redirecting eth0 to eth0
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2) eth0->eth1-> eth0
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3) eth0->lo-> eth1-> eth0
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B) Do not redirect from one IFB device to another.
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Remember that IFB is a very specialized case of packet redirecting
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device. Instead of redirecting it puts packets at the exact spot
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on the stack it found them from.
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Redirecting from ifbX->ifbY will actually not crash your machine but your
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packets will all be dropped (this is much simpler to detect
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and resolve and is only affecting users of ifb as opposed to the
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whole stack).
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In the case of A) the problem has to do with a recursive contention
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for the devices queue lock and in the second case for the transmit lock.
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Some examples:
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-------------
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1) Mirror all packets arriving on eth0 to be sent out on eth1.
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You may have a sniffer or some accounting box hooked up on eth1.
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---
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tc qdisc add dev eth0 ingress
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tc filter add dev eth0 parent ffff: protocol ip prio 10 u32 \
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match u32 0 0 flowid 1:2 action mirred egress mirror dev eth1
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---
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If you replace "mirror" with "redirect" then not a copy but rather
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the original packet is sent to eth1.
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2) Host A is hooked up to us on eth0
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# redirect all packets arriving on ingress of lo to eth0
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---
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tc qdisc add dev lo ingress
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tc filter add dev lo parent ffff: protocol ip prio 10 u32 \
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match u32 0 0 flowid 1:2 action mirred egress redirect dev eth0
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---
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On host A start a tcpdump on interface connecting to us.
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on our host ping -c 2 127.0.0.1
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Ping would fail since all packets are heading out eth0
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tcpudmp on host A would show them
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if you substitute the redirect with mirror above as in:
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tc filter add dev lo parent ffff: protocol ip prio 10 u32 \
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match u32 0 0 flowid 1:2 action mirred egress mirror dev eth0
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Then you should see the packets on both host A and the local
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stack (i.e ping would work).
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3) Even more funky example:
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#
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#allow 1 out 10 packets on ingress of lo to randomly make it to the
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# host A (Randomness uses the netrand generator)
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#
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---
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tc filter add dev lo parent ffff: protocol ip prio 10 u32 \
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match u32 0 0 flowid 1:2 \
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action drop random determ ok 10\
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action mirred egress mirror dev eth0
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---
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4)
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# for packets from 10.0.0.9 going out on eth0 (could be local
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# IP or something # we are forwarding) -
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# if exceeding a 100Kbps rate, then redirect to eth1
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#
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---
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tc qdisc add dev eth0 handle 1:0 root prio
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tc filter add dev eth0 parent 1:0 protocol ip prio 6 u32 \
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match ip src 10.0.0.9/32 flowid 1:16 \
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action police rate 100kbit burst 90k ok \
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action mirred egress mirror dev eth1
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---
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A more interesting example is when you mirror flows to a dummy device
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so you could tcpdump them (dummy by defaults drops all packets it sees).
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This is a very useful debug feature.
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Lets say you are policing packets from alias 192.168.200.200/32
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you dont want those to exceed 100kbps going out.
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---
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tc qdisc add dev eth0 handle 1:0 root prio
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tc filter add dev eth0 parent 1: protocol ip prio 10 u32 \
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match ip src 192.168.200.200/32 flowid 1:2 \
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action police rate 100kbit burst 90k drop
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---
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If you run tcpdump on eth0 you will see all packets going out
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with src 192.168.200.200/32 dropped or not (since tcpdump shows
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all packets being egressed).
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Extend the rule a little to see only the packets making it out.
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---
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tc qdisc add dev eth0 handle 1:0 root prio
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tc filter add dev eth0 parent 1: protocol ip prio 10 u32 \
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match ip src 192.168.200.200/32 flowid 1:2 \
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action police rate 10kbit burst 90k drop \
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action mirred egress mirror dev dummy0
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---
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Now fire tcpdump on dummy0 to see only those packets ..
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tcpdump -n -i dummy0 -x -e -t
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Essentially a good debugging/logging interface (sort of like
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BSDs speacialized log device does without needing one).
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If you replace mirror with redirect, those packets will be
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blackholed and will never make it out.
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cheers,
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jamal
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