Vlad Buslov says:
=================
Implement support for VF tunneling
Abstract
Currently, mlx5 only supports configuration with tunnel endpoint IP address on
uplink representor. Remove implicit and explicit assumptions of tunnel always
being terminated on uplink and implement necessary infrastructure for
configuring tunnels on VF representors and updating rules on such tunnels
according to routing changes.
SW TC model
From TC perspective VF tunnel configuration requires two rules in both
directions:
TX rules
1. Rule that redirects packets from UL to VF rep that has the tunnel
endpoint IP address:
$ tc -s filter show dev enp8s0f0 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac 16:c9:a0:2d:69:2c
src_mac 0c:42:a1:58:ab:e4
eth_type ipv4
ip_flags nofrag
in_hw in_hw_count 1
action order 1: mirred (Egress Redirect to device enp8s0f0_0) stolen
index 3 ref 1 bind 1 installed 377 sec used 0 sec
Action statistics:
Sent 114096 bytes 952 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 114096 bytes 952 pkt
backlog 0b 0p requeues 0
cookie 878fa48d8c423fc08c3b6ca599b50a97
no_percpu
used_hw_stats delayed
2. Rule that decapsulates the tunneled flow and redirects to destination VF
representor:
$ tc -s filter show dev vxlan_sys_4789 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac ca:2e:a7:3f:f5:0f
src_mac 0a:40:bd:30:89:99
eth_type ipv4
enc_dst_ip 7.7.7.5
enc_src_ip 7.7.7.1
enc_key_id 98
enc_dst_port 4789
enc_tos 0
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key unset pipe
index 2 ref 1 bind 1 installed 434 sec used 434 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device enp8s0f0_1) stolen
index 4 ref 1 bind 1 installed 434 sec used 0 sec
Action statistics:
Sent 129936 bytes 1082 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 129936 bytes 1082 pkt
backlog 0b 0p requeues 0
cookie ac17cf398c4c69e4a5b2f7aabd1b88ff
no_percpu
used_hw_stats delayed
RX rules
1. Rule that encapsulates the tunneled flow and redirects packets from
source VF rep to tunnel device:
$ tc -s filter show dev enp8s0f0_1 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac 0a:40:bd:30:89:99
src_mac ca:2e:a7:3f:f5:0f
eth_type ipv4
ip_tos 0/0x3
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key set
src_ip 7.7.7.5
dst_ip 7.7.7.1
key_id 98
dst_port 4789
nocsum
ttl 64 pipe
index 1 ref 1 bind 1 installed 411 sec used 411 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
no_percpu
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device vxlan_sys_4789) stolen
index 1 ref 1 bind 1 installed 411 sec used 0 sec
Action statistics:
Sent 5615833 bytes 4028 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 5615833 bytes 4028 pkt
backlog 0b 0p requeues 0
cookie bb406d45d343bf7ade9690ae80c7cba4
no_percpu
used_hw_stats delayed
2. Rule that redirects from tunnel device to UL rep:
$ tc -s filter show dev vxlan_sys_4789 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac ca:2e:a7:3f:f5:0f
src_mac 0a:40:bd:30:89:99
eth_type ipv4
enc_dst_ip 7.7.7.5
enc_src_ip 7.7.7.1
enc_key_id 98
enc_dst_port 4789
enc_tos 0
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key unset pipe
index 2 ref 1 bind 1 installed 434 sec used 434 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device enp8s0f0_1) stolen
index 4 ref 1 bind 1 installed 434 sec used 0 sec
Action statistics:
Sent 129936 bytes 1082 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 129936 bytes 1082 pkt
backlog 0b 0p requeues 0
cookie ac17cf398c4c69e4a5b2f7aabd1b88ff
no_percpu
used_hw_stats delayed
HW offloads model
For hardware offload the goal is to mach packet on both rules without exposing
it to software on tunnel endpoint VF. In order to achieve this for tx, TC
implementation marks encap rules with tunnel endpoint on mlx5 VF of same eswitch
with MLX5_ESW_DEST_CHAIN_WITH_SRC_PORT_CHANGE flag and adds header modification
rule to overwrite packet source port to the value of tunnel VF. Eswitch code is
modified to recirculate such packets after source port value is changed, which
allows second tx rules to match.
For rx path indirect table infrastructure is used to allow fully processing VF
tunnel traffic in hardware. To implement such pipeline driver needs to program
the hardware after matching on UL rule to overwrite source vport from UL to
tunnel VF and recirculate the packet to the root table to allow matching on the
rule installed on tunnel VF. For this, indirect table matches all encapsulated
traffic by tunnel parameters and all other IP traffic is sent to tunnel VF by
the miss rule. Such configuration will cause packet to appear on VF representor
instead of VF itself if packet has been matches by indirect table rule based on
tunnel parameters but missed on second rule (after recirculation). Handle such
case by marking packets processed by indirect table with special 0xFFF value in
reg_c1 and extending slow table with additional flow group that matches on
reg_c0 (source port value set by indirect tables) and reg_c1 (special 0xFFF
mark). When creating offloads fdb tables, install one rule per VF vport to match
on recirculated miss packets and redirect them to appropriate VF vport.
Routing events
In order to support routing changes and migration of tunnel device between
different endpoint VFs, implement routing infrastructure and update it with FIB
events. Routing entry table is introduced to mlx5 TC. Every rx and tx VF tunnel
rule is attached to a routing entry, which is shared for rules of same tunnel.
On FIB event the work is scheduled to delete/recreate all rules of affected
tunnel.
Note: only vxlan tunnel type is supported by this series.
=================
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Merge tag 'mlx5-updates-2021-02-04' of git://git.kernel.org/pub/scm/linux/kernel/git/saeed/linux
mlx5-updates-2021-02-04
Vlad Buslov says:
=================
Implement support for VF tunneling
Abstract
Currently, mlx5 only supports configuration with tunnel endpoint IP address on
uplink representor. Remove implicit and explicit assumptions of tunnel always
being terminated on uplink and implement necessary infrastructure for
configuring tunnels on VF representors and updating rules on such tunnels
according to routing changes.
SW TC model
From TC perspective VF tunnel configuration requires two rules in both
directions:
TX rules
1. Rule that redirects packets from UL to VF rep that has the tunnel
endpoint IP address:
$ tc -s filter show dev enp8s0f0 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac 16:c9:a0:2d:69:2c
src_mac 0c:42:a1:58:ab:e4
eth_type ipv4
ip_flags nofrag
in_hw in_hw_count 1
action order 1: mirred (Egress Redirect to device enp8s0f0_0) stolen
index 3 ref 1 bind 1 installed 377 sec used 0 sec
Action statistics:
Sent 114096 bytes 952 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 114096 bytes 952 pkt
backlog 0b 0p requeues 0
cookie 878fa48d8c423fc08c3b6ca599b50a97
no_percpu
used_hw_stats delayed
2. Rule that decapsulates the tunneled flow and redirects to destination VF
representor:
$ tc -s filter show dev vxlan_sys_4789 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac ca:2e:a7:3f:f5:0f
src_mac 0a:40:bd:30:89:99
eth_type ipv4
enc_dst_ip 7.7.7.5
enc_src_ip 7.7.7.1
enc_key_id 98
enc_dst_port 4789
enc_tos 0
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key unset pipe
index 2 ref 1 bind 1 installed 434 sec used 434 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device enp8s0f0_1) stolen
index 4 ref 1 bind 1 installed 434 sec used 0 sec
Action statistics:
Sent 129936 bytes 1082 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 129936 bytes 1082 pkt
backlog 0b 0p requeues 0
cookie ac17cf398c4c69e4a5b2f7aabd1b88ff
no_percpu
used_hw_stats delayed
RX rules
1. Rule that encapsulates the tunneled flow and redirects packets from
source VF rep to tunnel device:
$ tc -s filter show dev enp8s0f0_1 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac 0a:40:bd:30:89:99
src_mac ca:2e:a7:3f:f5:0f
eth_type ipv4
ip_tos 0/0x3
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key set
src_ip 7.7.7.5
dst_ip 7.7.7.1
key_id 98
dst_port 4789
nocsum
ttl 64 pipe
index 1 ref 1 bind 1 installed 411 sec used 411 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
no_percpu
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device vxlan_sys_4789) stolen
index 1 ref 1 bind 1 installed 411 sec used 0 sec
Action statistics:
Sent 5615833 bytes 4028 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 5615833 bytes 4028 pkt
backlog 0b 0p requeues 0
cookie bb406d45d343bf7ade9690ae80c7cba4
no_percpu
used_hw_stats delayed
2. Rule that redirects from tunnel device to UL rep:
$ tc -s filter show dev vxlan_sys_4789 ingress
filter protocol ip pref 4 flower chain 0
filter protocol ip pref 4 flower chain 0 handle 0x1
dst_mac ca:2e:a7:3f:f5:0f
src_mac 0a:40:bd:30:89:99
eth_type ipv4
enc_dst_ip 7.7.7.5
enc_src_ip 7.7.7.1
enc_key_id 98
enc_dst_port 4789
enc_tos 0
ip_flags nofrag
in_hw in_hw_count 1
action order 1: tunnel_key unset pipe
index 2 ref 1 bind 1 installed 434 sec used 434 sec
Action statistics:
Sent 0 bytes 0 pkt (dropped 0, overlimits 0 requeues 0)
backlog 0b 0p requeues 0
used_hw_stats delayed
action order 2: mirred (Egress Redirect to device enp8s0f0_1) stolen
index 4 ref 1 bind 1 installed 434 sec used 0 sec
Action statistics:
Sent 129936 bytes 1082 pkt (dropped 0, overlimits 0 requeues 0)
Sent software 0 bytes 0 pkt
Sent hardware 129936 bytes 1082 pkt
backlog 0b 0p requeues 0
cookie ac17cf398c4c69e4a5b2f7aabd1b88ff
no_percpu
used_hw_stats delayed
HW offloads model
For hardware offload the goal is to mach packet on both rules without exposing
it to software on tunnel endpoint VF. In order to achieve this for tx, TC
implementation marks encap rules with tunnel endpoint on mlx5 VF of same eswitch
with MLX5_ESW_DEST_CHAIN_WITH_SRC_PORT_CHANGE flag and adds header modification
rule to overwrite packet source port to the value of tunnel VF. Eswitch code is
modified to recirculate such packets after source port value is changed, which
allows second tx rules to match.
For rx path indirect table infrastructure is used to allow fully processing VF
tunnel traffic in hardware. To implement such pipeline driver needs to program
the hardware after matching on UL rule to overwrite source vport from UL to
tunnel VF and recirculate the packet to the root table to allow matching on the
rule installed on tunnel VF. For this, indirect table matches all encapsulated
traffic by tunnel parameters and all other IP traffic is sent to tunnel VF by
the miss rule. Such configuration will cause packet to appear on VF representor
instead of VF itself if packet has been matches by indirect table rule based on
tunnel parameters but missed on second rule (after recirculation). Handle such
case by marking packets processed by indirect table with special 0xFFF value in
reg_c1 and extending slow table with additional flow group that matches on
reg_c0 (source port value set by indirect tables) and reg_c1 (special 0xFFF
mark). When creating offloads fdb tables, install one rule per VF vport to match
on recirculated miss packets and redirect them to appropriate VF vport.
Routing events
In order to support routing changes and migration of tunnel device between
different endpoint VFs, implement routing infrastructure and update it with FIB
events. Routing entry table is introduced to mlx5 TC. Every rx and tx VF tunnel
rule is attached to a routing entry, which is shared for rules of same tunnel.
On FIB event the work is scheduled to delete/recreate all rules of affected
tunnel.
Note: only vxlan tunnel type is supported by this series.
=================
08cbabb77e