Routing engine for opensm subnet manager
Torus-2QoS is routing algorithm designed for large-scale 2D/3D torus fabrics. The torus-2QoS routing engine can provide the following functionality on a 2D/3D torus:
\[en] Routing that is free of credit loops. \[en] Two levels of Quality of Service (QoS), assuming switches support eight data VLs and channel adapters support two data VLs. \[en] The ability to route around a single failed switch, and/or multiple failed links, without \[en] introducing credit loops, or \[en] changing path SL values. \[en] Very short run times, with good scaling properties as fabric size increases.
Unicast routing in torus-2QoS is based on Dimension Order Routing (DOR). It avoids the deadlocks that would otherwise occur in a DOR-routed torus using the concept of a dateline for each torus dimension. It encodes into a path SL which datelines the path crosses, as follows:
sl = 0; for (d = 0; d < torus_dimensions; d++) { /* path_crosses_dateline(d) returns 0 or 1 */ sl |= path_crosses_dateline(d) << d; }
On a 3D torus this consumes three SL bits, leaving one SL bit unused. Torus-2QoS uses this SL bit to implement two QoS levels.
Torus-2QoS also makes use of the output port dependence of switch SL2VL maps to encode into one VL bit the information encoded in three SL bits. It computes in which torus coordinate direction each inter-switch link "points", and writes SL2VL maps for such ports as follows:
for (sl = 0; sl < 16; sl++) { /* cdir(port) computes which torus coordinate direction * a switch port "points" in; returns 0, 1, or 2 */ sl2vl(iport,oport,sl) = 0x1 & (sl >> cdir(oport)); }
Thus, on a pristine 3D torus, i.e., in the absence of failed fabric switches, torus-2QoS consumes eight SL values (SL bits 0-2) and two VL values (VL bit 0) per QoS level to provide deadlock-free routing.
Torus-2QoS routes around link failure by "taking the long way around" any 1D ring interrupted by link failure. For example, consider the 2D 6x5 torus below, where switches are denoted by [+a-zA-Z]: \# define macros to start and end ascii art, assuming Roman font. \# the start macro takes an argument which is the width in ems of \# the ascii art, and is used to center it. \# \# end of macro definitions
| | | | | | 4 --+----+----+----+----+----+-- | | | | | | 3 --+----+----+----D----+----+-- | | | | | | 2 --+----+----I----r----+----+-- | | | | | | 1 --m----S----n----T----o----p-- | | | | | | y=0 --+----+----+----+----+----+-- | | | | | | x=0 1 2 3 4 5
For a pristine fabric the path from S to D would be S-n-T-r-D. In the event that either link S-n or n-T has failed, torus-2QoS would use the path S-m-p-o-T-r-D. Note that it can do this without changing the path SL value; once the 1D ring m-S-n-T-o-p-m has been broken by failure, path segments using it cannot contribute to deadlock, and the x-direction dateline (between, say, x=5 and x=0) can be ignored for path segments on that ring.
One result of this is that torus-2QoS can route around many simultaneous link failures, as long as no 1D ring is broken into disjoint segments. For example, if links n-T and T-o have both failed, that ring has been broken into two disjoint segments, T and o-p-m-S-n. Torus-2QoS checks for such issues, reports if they are found, and refuses to route such fabrics.
Note that in the case where there are multiple parallel links between a pair of switches, torus-2QoS will allocate routes across such links in a round-robin fashion, based on ports at the path destination switch that are active and not used for inter-switch links. Should a link that is one of several such parallel links fail, routes are redistributed across the remaining links. When the last of such a set of parallel links fails, traffic is rerouted as described above.
Handling a failed switch under DOR requires introducing into a path at least one turn that would be otherwise "illegal", i.e., not allowed by DOR rules. Torus-2QoS will introduce such a turn as close as possible to the failed switch in order to route around it.
In the above example, suppose switch T has failed, and consider the path from S to D. Torus-2QoS will produce the path S-n-I-r-D, rather than the S-n-T-r-D path for a pristine torus, by introducing an early turn at n. Normal DOR rules will cause traffic arriving at switch I to be forwarded to switch r; for traffic arriving from I due to the "early" turn at n, this will generate an "illegal" turn at I.
Torus-2QoS will also use the input port dependence of SL2VL maps to set VL bit 1 (which would be otherwise unused) for y-x, z-x, and z-y turns, i.e., those turns that are illegal under DOR. This causes the first hop after any such turn to use a separate set of VL values, and prevents deadlock in the presence of a single failed switch.
For any given path, only the hops after a turn that is illegal under DOR can contribute to a credit loop that leads to deadlock. So in the example above with failed switch T, the location of the illegal turn at I in the path from S to D requires that any credit loop caused by that turn must encircle the failed switch at T. Thus the second and later hops after the illegal turn at I (i.e., hop r-D) cannot contribute to a credit loop because they cannot be used to construct a loop encircling T. The hop I-r uses a separate VL, so it cannot contribute to a credit loop encircling T.
Extending this argument shows that in addition to being capable of routing around a single switch failure without introducing deadlock, torus-2QoS can also route around multiple failed switches on the condition they are adjacent in the last dimension routed by DOR. For example, consider the following case on a 6x6 2D torus:
| | | | | | 5 --+----+----+----+----+----+-- | | | | | | 4 --+----+----+----D----+----+-- | | | | | | 3 --+----+----I----u----+----+-- | | | | | | 2 --+----+----q----R----+----+-- | | | | | | 1 --m----S----n----T----o----p-- | | | | | |
y=0 --+----+----+----+----+----+--
| | | | | |
x=0 1 2 3 4 5
Suppose switches T and R have failed, and consider the path from S to D. Torus-2QoS will generate the path S-n-q-I-u-D, with an illegal turn at switch I, and with hop I-u using a VL with bit 1 set.
As a further example, consider a case that torus-2QoS cannot route without deadlock: two failed switches adjacent in a dimension that is not the last dimension routed by DOR; here the failed switches are O and T:
| | | | | | 5 --+----+----+----+----+----+-- | | | | | | 4 --+----+----+----+----+----+-- | | | | | | 3 --+----+----+----+----D----+-- | | | | | | 2 --+----+----I----q----r----+-- | | | | | | 1 --m----S----n----O----T----p-- | | | | | |
y=0 --+----+----+----+----+----+--
| | | | | |
x=0 1 2 3 4 5
In a pristine fabric, torus-2QoS would generate the path from S to D as S-n-O-T-r-D. With failed switches O and T, torus-2QoS will generate the path S-n-I-q-r-D, with illegal turn at switch I, and with hop I-q using a VL with bit 1 set. In contrast to the earlier examples, the second hop after the illegal turn, q-r, can be used to construct a credit loop encircling the failed switches.
Since torus-2QoS uses all four available SL bits, and the three data VL bits that are typically available in current switches, there is no way to use SL/VL values to separate multicast traffic from unicast traffic. Thus, torus-2QoS must generate multicast routing such that credit loops cannot arise from a combination of multicast and unicast path segments.
It turns out that it is possible to construct spanning trees for multicast routing that have that property. For the 2D 6x5 torus example above, here is the full-fabric spanning tree that torus-2QoS will construct, where "x" is the root switch and each "+" is a non-root switch:
4 + + + + + + | | | | | | 3 + + + + + + | | | | | | 2 +----+----+----x----+----+ | | | | | | 1 + + + + + + | | | | | |
y=0 + + + + + +
x=0 1 2 3 4 5
For multicast traffic routed from root to tip, every turn in the above spanning tree is a legal DOR turn.
For traffic routed from tip to root, and some traffic routed through the root, turns are not legal DOR turns. However, to construct a credit loop, the union of multicast routing on this spanning tree with DOR unicast routing can only provide 3 of the 4 turns needed for the loop.
In addition, if none of the above spanning tree branches crosses a dateline used for unicast credit loop avoidance on a torus, and if multicast traffic is confined to SL 0 or SL 8 (recall that torus-2QoS uses SL bit 3 to differentiate QoS level), then multicast traffic also cannot contribute to the "ring" credit loops that are otherwise possible in a torus.
Torus-2QoS uses these ideas to create a master spanning tree. Every multicast group spanning tree will be constructed as a subset of the master tree, with the same root as the master tree.
Such multicast group spanning trees will in general not be optimal for groups which are a subset of the full fabric. However, this compromise must be made to enable support for two QoS levels on a torus while preventing credit loops.
In the presence of link or switch failures that result in a fabric for which torus-2QoS can generate credit-loop-free unicast routes, it is also possible to generate a master spanning tree for multicast that retains the required properties. For example, consider that same 2D 6x5 torus, with the link from (2,2) to (3,2) failed. Torus-2QoS will generate the following master spanning tree:
4 + + + + + + | | | | | | 3 + + + + + + | | | | | | 2 --+----+----+ x----+----+-- | | | | | | 1 + + + + + + | | | | | |
y=0 + + + + + +
x=0 1 2 3 4 5
Two things are notable about this master spanning tree. First, assuming the x dateline was between x=5 and x=0, this spanning tree has a branch that crosses the dateline. However, just as for unicast, crossing a dateline on a 1D ring (here, the ring for y=2) that is broken by a failure cannot contribute to a torus credit loop.
Second, this spanning tree is no longer optimal even for multicast groups that encompass the entire fabric. That, unfortunately, is a compromise that must be made to retain the other desirable properties of torus-2QoS routing.
In the event that a single switch fails, torus-2QoS will generate a master spanning tree that has no "extra" turns by appropriately selecting a root switch. In the 2D 6x5 torus example, assume now that the switch at (3,2), i.e., the root for a pristine fabric, fails. Torus-2QoS will generate the following master spanning tree for that case: |
4 + + + + + + | | | | | | 3 + + + + + + | | | | | 2 + + + + + | | | | | 1 +----+----x----+----+----+ | | | | | |
y=0 + + + + + + |
x=0 1 2 3 4 5
Assuming the y dateline was between y=4 and y=0, this spanning tree has a branch that crosses a dateline. However, again this cannot contribute to credit loops as it occurs on a 1D ring (the ring for x=3) that is broken by a failure, as in the above example.
The algorithm used by torus-2QoS to construct the torus topology from the undirected graph representing the fabric requires that the radix of each dimension be configured via torus-2QoS.conf. It also requires that the torus topology be "seeded"; for a 3D torus this requires configuring four switches that define the three coordinate directions of the torus.
Given this starting information, the algorithm is to examine the cube formed by the eight switch locations bounded by the corners (x,y,z) and (x+1,y+1,z+1). Based on switches already placed into the torus topology at some of these locations, the algorithm examines 4-loops of inter-switch links to find the one that is consistent with a face of the cube of switch locations, and adds its swiches to the discovered topology in the correct locations.
Because the algorithm is based on examining the topology of 4-loops of links, a torus with one or more radix-4 dimensions requires extra initial seed configuration. See torus-2QoS.conf(5) for details. Torus-2QoS will detect and report when it has insufficient configuration for a torus with radix-4 dimensions.
In the event the torus is significantly degraded, i.e., there are many missing switches or links, it may happen that torus-2QoS is unable to place into the torus some switches and/or links that were discovered in the fabric, and will generate a warning in that case. A similar condition occurs if torus-2QoS is misconfigured, i.e., the radix of a torus dimension as configured does not match the radix of that torus dimension as wired, and many switches/links in the fabric will not be placed into the torus.
OpenSM will not program switchs and channel adapters with SL2VL maps or VL arbitration configuration unless it is invoked with -Q. Since torus-2QoS depends on such functionality for correct operation, always invoke OpenSM with -Q when torus-2QoS is in the list of routing engines.
Any quality of service configuration method supported by OpenSM will work with torus-2QoS, subject to the following limitations and considerations.
For all routing engines supported by OpenSM except torus-2QoS, there is a one-to-one correspondence between QoS level and SL. Torus-2QoS can only support two quality of service levels, so only the high-order bit of any SL value used for unicast QoS configuration will be honored by torus-2QoS.
For multicast QoS configuration, only SL values 0 and 8 should be used with torus-2QoS.
Since SL to VL map configuration must be under the complete control of torus-2QoS, any configuration via qos_sl2vl, qos_swe_sl2vl, etc., must and will be ignored, and a warning will be generated.
For inter-switch links, Torus-2QoS uses VL values 0-3 to implement one of its supported QoS levels, and VL values 4-7 to implement the other. For endport links (CA, router, switch management port), Torus-2QoS uses VL value 0 for one of its supported QoS levels and VL value 1 to implement the other. Hard-to-diagnose application issues may arise if traffic is not delivered fairly across each of these two VL ranges. For inter-switch links, Torus-2QoS will detect and warn if VL arbitration is configured unfairly across VLs in the range 0-3, and also in the range 4-7. Note that the default OpenSM VL arbitration configuration does not meet this constraint, so all torus-2QoS users should configure VL arbitration via qos_ca_vlarb_high, qos_swe_vlarb_high, qos_ca_vlarb_low, qos_swe_vlarb_low, etc.
Note that torus-2QoS maps SL values to VL values differently for inter-switch and endport links. This is why qos_vlarb_high and qos_vlarb_low should not be used, as using them may result in VL arbitration for a QoS level being different across inter-switch links vs. across endport links.
Any routing algorithm for a torus IB fabric must employ path SL values to avoid credit loops. As a result, all applications run over such fabrics must perform a path record query to obtain the correct path SL for connection setup. Applications that use rdma_cm for connection setup will automatically meet this requirement.
If a change in fabric topology causes changes in path SL values required to route without credit loops, in general all applications would need to repath to avoid message deadlock. Since torus-2QoS has the ability to reroute after a single switch failure without changing path SL values, repathing by running applications is not required when the fabric is routed with torus-2QoS.
Torus-2QoS can provide unchanging path SL values in the presence of subnet manager failover provided that all OpenSM instances have the same idea of dateline location. See torus-2QoS.conf(5) for details.
Torus-2QoS will detect configurations of failed switches and links that prevent routing that is free of credit loops, and will log warnings and refuse to route. If "no_fallback" was configured in the list of OpenSM routing engines, then no other routing engine will attempt to route the fabric. In that case all paths that do not transit the failed components will continue to work, and the subset of paths that are still operational will continue to remain free of credit loops. OpenSM will continue to attempt to route the fabric after every sweep interval, and after any change (such as a link up) in the fabric topology. When the fabric components are repaired, full functionality will be restored.
In the event OpenSM was configured to allow some other engine to route the fabric if torus-2QoS fails, then credit loops and message deadlock are likely if torus-2QoS had previously routed the fabric successfully. Even if the other engine is capable of routing a torus without credit loops, applications that built connections with path SL values granted under torus-2QoS will likely experience message deadlock under routing generated by a different engine, unless they repath.
To verify that a torus fabric is routed free of credit loops, use ibdmchk to analyze data collected via ibdiagnet -vlr.
/etc/opensm/opensm.conf
default OpenSM config file.
/etc/opensm/qos-policy.conf
default QoS policy config file.
/etc/opensm/torus-2QoS.conf
default torus-2QoS config file.
opensm(8), torus-2QoS.conf(5), ibdiagnet(1), ibdmchk(1), rdma_cm(7).