- 07 Jan, 2021 33 commits
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Vladimir Oltean authored
The SYSTEMPORT driver maps each port of the embedded Broadcom DSA switch port to a certain queue of the master Ethernet controller. For that it currently uses a dedicated notifier infrastructure which was added in commit 60724d4b ("net: dsa: Add support for DSA specific notifiers"). However, since commit 2f1e8ea7 ("net: dsa: link interfaces with the DSA master to get rid of lockdep warnings"), DSA is actually an upper of the Broadcom SYSTEMPORT as far as the netdevice adjacency lists are concerned. So naturally, the plain NETDEV_CHANGEUPPER net device notifiers are emitted. It looks like there is enough API exposed by DSA to the outside world already to make the call_dsa_notifiers API redundant. So let's convert its only user to plain netdev notifiers. Signed-off-by:
Vladimir Oltean <vladimir.oltean@nxp.com> Tested-by:
Florian Fainelli <f.fainelli@gmail.com> Signed-off-by:
Jakub Kicinski <kuba@kernel.org>
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Vladimir Oltean authored
Using the NETDEV_CHANGEUPPER notifications, drivers can be aware when they are enslaved to e.g. a bridge by calling netif_is_bridge_master(). Export this helper from DSA to get the equivalent functionality of determining whether the upper interface of a CHANGEUPPER notifier is a DSA switch interface or not. Signed-off-by:
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Vladimir Oltean authored
It is a bit strange to see something as specific as Broadcom SYSTEMPORT bits in the main DSA include file. Move these away into a separate header, and have the tagger and the SYSTEMPORT driver include them. Signed-off-by:
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Jakub Kicinski authored
Vladimir Oltean says: ==================== Offload software learnt bridge addresses to DSA This series tries to make DSA behave a bit more sanely when bridged with "foreign" (non-DSA) interfaces and source address learning is not supported on the hardware CPU port (which would make things work more seamlessly without software intervention). When a station A connected to a DSA switch port needs to talk to another station B connected to a non-DSA port through the Linux bridge, DSA must explicitly add a route for station B towards its CPU port. Initial RFC was posted here: https://patchwork.ozlabs.org/project/netdev/cover/20201108131953.2462644-1-olteanv@gmail.com/ v2 was posted here: https://patchwork.kernel.org/project/netdevbpf/cover/20201213024018.772586-1-vladimir.oltean@nxp.com/ v3 was posted here: https://patchwork.kernel.org/project/netdevbpf/cover/20201213140710.1198050-1-vladimir.oltean@nxp.com/ This is a resend of the previous v3 with some added Reviewed-by tags. ==================== Link: https://lore.kernel.org/r/20210106095136.224739-1-olteanv@gmail.comSigned-off-by:
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Vladimir Oltean authored
Given the following setup: ip link add br0 type bridge ip link set eno0 master br0 ip link set swp0 master br0 ip link set swp1 master br0 ip link set swp2 master br0 ip link set swp3 master br0 Currently, packets received on a DSA slave interface (such as swp0) which should be routed by the software bridge towards a non-switch port (such as eno0) are also flooded towards the other switch ports (swp1, swp2, swp3) because the destination is unknown to the hardware switch. This patch addresses the issue by monitoring the addresses learnt by the software bridge on eno0, and adding/deleting them as static FDB entries on the CPU port accordingly. Signed-off-by:
Andrew Lunn <andrew@lunn.ch> Signed-off-by:
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Vladimir Oltean authored
Some DSA switches (and not only) cannot learn source MAC addresses from packets injected from the CPU. They only perform hardware address learning from inbound traffic. This can be problematic when we have a bridge spanning some DSA switch ports and some non-DSA ports (which we'll call "foreign interfaces" from DSA's perspective). There are 2 classes of problems created by the lack of learning on CPU-injected traffic: - excessive flooding, due to the fact that DSA treats those addresses as unknown - the risk of stale routes, which can lead to temporary packet loss To illustrate the second class, consider the following situation, which is common in production equipment (wireless access points, where there is a WLAN interface and an Ethernet switch, and these form a single bridging domain). AP 1: +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ | ^ ^ | | | | | | | Client A Client B | | | +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ AP 2 - br0 of AP 1 will know that Clients A and B are reachable via wlan0 - the hardware fdb of a DSA switch driver today is not kept in sync with the software entries on other bridge ports, so it will not know that clients A and B are reachable via the CPU port UNLESS the hardware switch itself performs SA learning from traffic injected from the CPU. Nonetheless, a substantial number of switches don't. - the hardware fdb of the DSA switch on AP 2 may autonomously learn that Client A and B are reachable through swp0. Therefore, the software br0 of AP 2 also may or may not learn this. In the example we're illustrating, some Ethernet traffic has been going on, and br0 from AP 2 has indeed learnt that it can reach Client B through swp0. One of the wireless clients, say Client B, disconnects from AP 1 and roams to AP 2. The topology now looks like this: AP 1: +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ | ^ | | | Client A | | | Client B | | | v +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ AP 2 - br0 of AP 1 still knows that Client A is reachable via wlan0 (no change) - br0 of AP 1 will (possibly) know that Client B has left wlan0. There are cases where it might never find out though. Either way, DSA today does not process that notification in any way. - the hardware FDB of the DSA switch on AP 1 may learn autonomously that Client B can be reached via swp0, if it receives any packet with Client 1's source MAC address over Ethernet. - the hardware FDB of the DSA switch on AP 2 still thinks that Client B can be reached via swp0. It does not know that it has roamed to wlan0, because it doesn't perform SA learning from the CPU port. Now Client A contacts Client B. AP 1 routes the packet fine towards swp0 and delivers it on the Ethernet segment. AP 2 sees a frame on swp0 and its fdb says that the destination is swp0. Hairpinning is disabled => drop. This problem comes from the fact that these switches have a 'blind spot' for addresses coming from software bridging. The generic solution is not to assume that hardware learning can be enabled somehow, but to listen to more bridge learning events. It turns out that the bridge driver does learn in software from all inbound frames, in __br_handle_local_finish. A proper SWITCHDEV_FDB_ADD_TO_DEVICE notification is emitted for the addresses serviced by the bridge on 'foreign' interfaces. The software bridge also does the right thing on migration, by notifying that the old entry is deleted, so that does not need to be special-cased in DSA. When it is deleted, we just need to delete our static FDB entry towards the CPU too, and wait. The problem is that DSA currently only cares about SWITCHDEV_FDB_ADD_TO_DEVICE events received on its own interfaces, such as static FDB entries. Luckily we can change that, and DSA can listen to all switchdev FDB add/del events in the system and figure out if those events were emitted by a bridge that spans at least one of DSA's own ports. In case that is true, DSA will also offload that address towards its own CPU port, in the eventuality that there might be bridge clients attached to the DSA switch who want to talk to the station connected to the foreign interface. In terms of implementation, we need to keep the fdb_info->added_by_user check for the case where the switchdev event was targeted directly at a DSA switch port. But we don't need to look at that flag for snooped events. So the check is currently too late, we need to move it earlier. This also simplifies the code a bit, since we avoid uselessly allocating and freeing switchdev_work. We could probably do some improvements in the future. For example, multi-bridge support is rudimentary at the moment. If there are two bridges spanning a DSA switch's ports, and both of them need to service the same MAC address, then what will happen is that the migration of one of those stations will trigger the deletion of the FDB entry from the CPU port while it is still used by other bridge. That could be improved with reference counting but is left for another time. This behavior needs to be enabled at driver level by setting ds->assisted_learning_on_cpu_port = true. This is because we don't want to inflict a potential performance penalty (accesses through MDIO/I2C/SPI are expensive) to hardware that really doesn't need it because address learning on the CPU port works there. Reported-by:DENG Qingfang <dqfext@gmail.com> Signed-off-by:
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Vladimir Oltean authored
Right now, the following would happen for a switch driver that does not implement .port_fdb_add or .port_fdb_del. dsa_slave_switchdev_event returns NOTIFY_OK and schedules: -> dsa_slave_switchdev_event_work -> dsa_port_fdb_add -> dsa_port_notify(DSA_NOTIFIER_FDB_ADD) -> dsa_switch_fdb_add -> if (!ds->ops->port_fdb_add) return -EOPNOTSUPP; -> an error is printed with dev_dbg, and dsa_fdb_offload_notify(switchdev_work) is not called. We can avoid scheduling the worker for nothing and say NOTIFY_DONE. Because we don't call dsa_fdb_offload_notify, the static FDB entry will remain just in the software bridge. Signed-off-by: -
Vladimir Oltean authored
We'll need to start listening to SWITCHDEV_FDB_{ADD,DEL}_TO_DEVICE events even for interfaces where dsa_slave_dev_check returns false, so we need that check inside the switch-case statement for SWITCHDEV_FDB_*. This movement also avoids a useless allocation / free of switchdev_work on the untreated "default event" case. Signed-off-by: -
Vladimir Oltean authored
Currently DSA doesn't add FDB entries on the CPU port, because it only does so through switchdev, which is associated with a net_device, and there are none of those for the CPU port. But actually FDB addresses on the CPU port have some use cases of their own, if the switchdev operations are initiated from within the DSA layer. There is just one problem with the existing code: it passes a structure in dsa_switchdev_event_work which was retrieved directly from switchdev, so it contains a net_device. We need to generalize the contents to something that covers the CPU port as well: the "ds, port" tuple is fine for that. Note that the new procedure for notifying the successful FDB offload is inspired from the rocker model. Also, nothing was being done if added_by_user was false. Let's check for that a lot earlier, and don't actually bother to schedule the worker for nothing. Signed-off-by:
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Vladimir Oltean authored
The dev_close() call was added in commit c9eb3e0f ("net: dsa: Add support for learning FDB through notification") "to indicate inconsistent situation" when we could not delete an FDB entry from the port. bridge fdb del d8:58:d7:00:ca:6d dev swp0 self master It is a bit drastic and at the same time not helpful if the above fails to only print with netdev_dbg log level, but on the other hand to bring the interface down. So increase the verbosity of the error message, and drop dev_close(). Signed-off-by:
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Vladimir Oltean authored
Currently the bridge emits atomic switchdev notifications for dynamically learnt FDB entries. Monitoring these notifications works wonders for switchdev drivers that want to keep their hardware FDB in sync with the bridge's FDB. For example station A wants to talk to station B in the diagram below, and we are concerned with the behavior of the bridge on the DUT device: DUT +-------------------------------------+ | br0 | | +------+ +------+ +------+ +------+ | | | | | | | | | | | | | swp0 | | swp1 | | swp2 | | eth0 | | +-------------------------------------+ | | | Station A | | | | +--+------+--+ +--+------+--+ | | | | | | | | | | swp0 | | | | swp0 | | Another | +------+ | | +------+ | Another switch | br0 | | br0 | switch | +------+ | | +------+ | | | | | | | | | | | swp1 | | | | swp1 | | +--+------+--+ +--+------+--+ | Station B Interfaces swp0, swp1, swp2 are handled by a switchdev driver that has the following property: frames injected from its control interface bypass the internal address analyzer logic, and therefore, this hardware does not learn from the source address of packets transmitted by the network stack through it. So, since bridging between eth0 (where Station B is attached) and swp0 (where Station A is attached) is done in software, the switchdev hardware will never learn the source address of Station B. So the traffic towards that destination will be treated as unknown, i.e. flooded. This is where the bridge notifications come in handy. When br0 on the DUT sees frames with Station B's MAC address on eth0, the switchdev driver gets these notifications and can install a rule to send frames towards Station B's address that are incoming from swp0, swp1, swp2, only towards the control interface. This is all switchdev driver private business, which the notification makes possible. All is fine until someone unplugs Station B's cable and moves it to the other switch: DUT +-------------------------------------+ | br0 | | +------+ +------+ +------+ +------+ | | | | | | | | | | | | | swp0 | | swp1 | | swp2 | | eth0 | | +-------------------------------------+ | | | Station A | | | | +--+------+--+ +--+------+--+ | | | | | | | | | | swp0 | | | | swp0 | | Another | +------+ | | +------+ | Another switch | br0 | | br0 | switch | +------+ | | +------+ | | | | | | | | | | | swp1 | | | | swp1 | | +--+------+--+ +--+------+--+ | Station B Luckily for the use cases we care about, Station B is noisy enough that the DUT hears it (on swp1 this time). swp1 receives the frames and delivers them to the bridge, who enters the unlikely path in br_fdb_update of updating an existing entry. It moves the entry in the software bridge to swp1 and emits an addition notification towards that. As far as the switchdev driver is concerned, all that it needs to ensure is that traffic between Station A and Station B is not forever broken. If it does nothing, then the stale rule to send frames for Station B towards the control interface remains in place. But Station B is no longer reachable via the control interface, but via a port that can offload the bridge port learning attribute. It's just that the port is prevented from learning this address, since the rule overrides FDB updates. So the rule needs to go. The question is via what mechanism. It sure would be possible for this switchdev driver to keep track of all addresses which are sent to the control interface, and then also listen for bridge notifier events on its own ports, searching for the ones that have a MAC address which was previously sent to the control interface. But this is cumbersome and inefficient. Instead, with one small change, the bridge could notify of the address deletion from the old port, in a symmetrical manner with how it did for the insertion. Then the switchdev driver would not be required to monitor learn/forget events for its own ports. It could just delete the rule towards the control interface upon bridge entry migration. This would make hardware address learning be possible again. Then it would take a few more packets until the hardware and software FDB would be in sync again. Signed-off-by:Nikolay Aleksandrov <nikolay@nvidia.com> Reviewed-by:
Ido Schimmel <idosch@nvidia.com> Reviewed-by:
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Jakub Kicinski authored
Heiner Kallweit says: ==================== r8169: improve RTL8168g PHY suspend quirk According to Realtek the ERI register 0x1a8 quirk is needed to work around a hw issue with the PHY on RTL8168g. The register needs to be changed before powering down the PHY. Currently we don't meet this requirement, however I'm not aware of any problems caused by this. Therefore I see the change as an improvement. The PHY driver has no means to access the chip ERI registers, therefore we have to intercept MDIO writes to the BMCR register. If the BMCR_PDOWN bit is going to be set, then let's apply the quirk before actually powering down the PHY. ==================== Link: https://lore.kernel.org/r/9303c2cf-c521-beea-c09f-63b5dfa91b9c@gmail.comSigned-off-by:
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Heiner Kallweit authored
According to Realtek the ERI register 0x1a8 quirk is needed to work around a hw issue with the PHY on RTL8168g. The register needs to be changed before powering down the PHY. Currently we don't meet this requirement, however I'm not aware of any problems caused by this. Therefore I see the change as an improvement. The PHY driver has no means to access the chip ERI registers, therefore we have to intercept MDIO writes to BMCR register. If the BMCR_PDOWN bit is going to be set, then let's apply the quirk before actually powering down the PHY. Signed-off-by:
Heiner Kallweit <hkallweit1@gmail.com> Signed-off-by:
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Heiner Kallweit authored
No functional change here. We just move a code block to avoid a function forward declaration in a subsequent change. Signed-off-by:
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Heiner Kallweit authored
Switch to lockdep_assert_held(_once), similar to what is being done in other subsystems. One advantage is that there's zero runtime overhead if lockdep support isn't enabled. Signed-off-by:
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Florian Fainelli authored
BCM72116 features a 28nm integrated EPHY, add an entry to match this PHY OUI. Signed-off-by:
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Jakub Kicinski authored
udp_tunnel_nic: post conversion cleanup It has been two releases since we added the common infra for UDP tunnel port offload, and we have not heard of any major issues. Remove the old direct driver NDOs completely, and perform minor simplifications in the tunnel drivers. Link: https://lore.kernel.org/r/20210106210637.1839662-1-kuba@kernel.orgSigned-off-by:
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Jakub Kicinski authored
Move the NETIF_F_RX_UDP_TUNNEL_PORT feature check into udp_tunnel_nic_*_port() helpers, since they're always done right before the call. Add similar checks before calling the notifier. udp_tunnel_nic invokes the notifier without checking features which could result in some wasted cycles. Reviewed-by:
Alexander Duyck <alexanderduyck@fb.com> Reviewed-by:
Jacob Keller <jacob.e.keller@intel.com> Signed-off-by:
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Jakub Kicinski authored
All UDP tunnel port management is now routed via udp_tunnel_nic infra directly. Remove the old callbacks. Reviewed-by:
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Jakub Kicinski authored
udp_tunnel_nic handles REGISTER and UNREGISTER event, now that all drivers use that infra we can drop the event handling in the tunnel drivers. Reviewed-by:
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Jakub Kicinski authored
All drivers use udp_tunnel_nic_*_port() helpers, prepare for NDO removal by invoking those helpers directly. The helpers are safe to call on all devices, they check if device has the UDP tunnel state initialized. Reviewed-by:
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Florian Fainelli authored
All of the OF code that is used has stubbed and will compile and link just fine, keeping COMPILE_TEST is enough. Signed-off-by:
Randy Dunlap <rdunlap@infradead.org> Link: https://lore.kernel.org/r/20210106191546.1358324-1-f.fainelli@gmail.comSigned-off-by:
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Jakub Kicinski authored
Sieng Piaw Liew says: ==================== bcm63xx_enet: major makeover of driver This patch series aim to improve the bcm63xx_enet driver by integrating the latest networking features, i.e. batched rx processing, BQL, build_skb, etc. The newer enetsw SoCs are found to be able to do unaligned rx DMA by adding NET_IP_ALIGN padding which, combined with these patches, improved packet processing performance by ~50% on BCM6328. Older non-enetsw SoCs still benefit mainly from rx batching. Performance improvement of ~30% is observed on BCM6333. The BCM63xx SoCs are designed for routers. As such, having BQL is beneficial as well as trivial to add. v3: * Simplify xmit_more patch by not moving around the code needlessly. * Fix indentation in xmit_more patch. * Fix indentation in build_skb patch. * Split rx ring cleanup patch from build_skb patch and precede build_skb patch for better understanding, as suggested by Florian Fainelli. v2: * Add xmit_more support and rx loop improvisation patches. * Moved BQL netdev_reset_queue() to bcm_enet_stop()/bcm_enetsw_stop() functions as suggested by Florian Fainelli. * Improved commit messages. ==================== Link: https://lore.kernel.org/r/20210106144208.1935-1-liew.s.piaw@gmail.comSigned-off-by:
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Sieng Piaw Liew authored
Use existing rx processed count to track against budget, thereby making budget decrement operation redundant. rx_desc_count can be calculated outside the rx loop, making the loop a bit smaller. Signed-off-by:
Sieng Piaw Liew <liew.s.piaw@gmail.com> Acked-by:
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Sieng Piaw Liew authored
We can increase the efficiency of rx path by using buffers to receive packets then build SKBs around them just before passing into the network stack. In contrast, preallocating SKBs too early reduces CPU cache efficiency. Check if we're in NAPI context when refilling RX. Normally we're almost always running in NAPI context. Dispatch to napi_alloc_frag directly instead of relying on netdev_alloc_frag which does the same but with the overhead of local_bh_disable/enable. Tested on BCM6328 320 MHz and iperf3 -M 512 to measure packet/sec performance. Included netif_receive_skb_list and NET_IP_ALIGN optimizations. Before: [ ID] Interval Transfer Bandwidth Retr [ 4] 0.00-10.00 sec 49.9 MBytes 41.9 Mbits/sec 197 sender [ 4] 0.00-10.00 sec 49.3 MBytes 41.3 Mbits/sec receiver After: [ ID] Interval Transfer Bandwidth Retr [ 4] 0.00-30.00 sec 171 MBytes 47.8 Mbits/sec 272 sender [ 4] 0.00-30.00 sec 170 MBytes 47.6 Mbits/sec receiver Signed-off-by:
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Sieng Piaw Liew authored
The rx SKB ring use the same code for cleanup at various points. Combine them into a function to reduce lines of code. Signed-off-by:
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Sieng Piaw Liew authored
Use netdev_alloc_skb_ip_align on newer SoCs with integrated switch (enetsw) when refilling RX. Increases packet processing performance by 30% (with netif_receive_skb_list). Non-enetsw SoCs cannot function with the extra pad so continue to use the regular netdev_alloc_skb. Tested on BCM6328 320 MHz and iperf3 -M 512 to measure packet/sec performance. Before: [ ID] Interval Transfer Bandwidth Retr [ 4] 0.00-30.00 sec 120 MBytes 33.7 Mbits/sec 277 sender [ 4] 0.00-30.00 sec 120 MBytes 33.5 Mbits/sec receiver After (+netif_receive_skb_list): [ 4] 0.00-30.00 sec 155 MBytes 43.3 Mbits/sec 354 sender [ 4] 0.00-30.00 sec 154 MBytes 43.1 Mbits/sec receiver Signed-off-by:
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Sieng Piaw Liew authored
Support bulking hardware TX queue by using netdev_xmit_more(). Signed-off-by:
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Sieng Piaw Liew authored
Add Byte Queue Limits support to reduce/remove bufferbloat in bcm63xx_enet. Signed-off-by:
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Sieng Piaw Liew authored
Use netif_receive_skb_list to batch process rx skb. Tested on BCM6328 320 MHz using iperf3 -M 512, increasing performance by 12.5%. Before: [ ID] Interval Transfer Bandwidth Retr [ 4] 0.00-30.00 sec 120 MBytes 33.7 Mbits/sec 277 sender [ 4] 0.00-30.00 sec 120 MBytes 33.5 Mbits/sec receiver After: [ ID] Interval Transfer Bandwidth Retr [ 4] 0.00-30.00 sec 136 MBytes 37.9 Mbits/sec 203 sender [ 4] 0.00-30.00 sec 135 MBytes 37.7 Mbits/sec receiver Signed-off-by:
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Kristian Evensen authored
When measuring the throughput (iperf3 + TCP) while routing on a not-so-powerful device (Mediatek MT7621, 880MHz CPU), I noticed that I achieved significantly lower speeds with QMI-based modems than for example a USB LAN dongle. The CPU was saturated in all of my tests. With the dongle I got ~300 Mbit/s, while I only measured ~200 Mbit/s with the modems. All offloads, etc. were switched off for the dongle, and I configured the modems to use QMAP (16k aggregation). The tests with the dongle were performed in my local (gigabit) network, while the LTE network the modems were connected to delivers 700-800 Mbit/s. Profiling the kernel revealed the cause of the performance difference. In qmimux_rx_fixup(), an SKB is allocated for each packet contained in the URB. This SKB has too little headroom, causing the check in skb_cow() (called from ip_forward()) to fail. pskb_expand_head() is then called and the SKB is reallocated. In the output from perf, I see that a significant amount of time is spent in pskb_expand_head() + support functions. In order to ensure that the SKB has enough headroom, this commit increases the amount of memory allocated in qmimux_rx_fixup() by LL_MAX_HEADER. The reason for using LL_MAX_HEADER and not a more accurate value, is that we do not know the type of the outgoing network interface. After making this change, I achieve the same throughput with the modems as with the dongle. Signed-off-by:
Kristian Evensen <kristian.evensen@gmail.com> Acked-by:
Bjørn Mork <bjorn@mork.no> Link: https://lore.kernel.org/r/20210106122403.1321180-1-kristian.evensen@gmail.comSigned-off-by:
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Jakub Kicinski authored
Merge tag 'linux-can-next-for-5.12-20210106' of git://git.kernel.org/pub/scm/linux/kernel/git/mkl/linux-can-next Marc Kleine-Budde says: ==================== pull-request: can-next 2021-01-06 The first 16 patches are by me and target the tcan4x5x SPI glue driver for the m_can CAN driver. First there are a several cleanup commits, then the SPI regmap part is converted to 8 bits per word, to make it possible to use that driver on SPI controllers that only support the 8 bit per word mode (such as the SPI cores on the raspberry pi). Oliver Hartkopp contributes a patch for the CAN_RAW protocol. The getsockopt() for CAN_RAW_FILTER is changed to return -ERANGE if the filterset does not fit into the provided user space buffer. The last two patches are by Joakim Zhang and add wakeup support to the flexcan driver for the i.MX8QM SoC. The dt-bindings docs are extended to describe the added property. * tag 'linux-can-next-for-5.12-20210106' of git://git.kernel.org/pub/scm/linux/kernel/git/mkl/linux-can-next: can: flexcan: add CAN wakeup function for i.MX8QM dt-bindings: can: fsl,flexcan: add fsl,scu-index property to indicate a resource can: raw: return -ERANGE when filterset does not fit into user space buffer can: tcan4x5x: add support for half-duplex controllers can: tcan4x5x: rework SPI access can: tcan4x5x: add {wr,rd}_table can: tcan4x5x: add max_raw_{read,write} of 256 can: tcan4x5x: tcan4x5x_regmap: set reg_stride to 4 can: tcan4x5x: fix max register value can: tcan4x5x: tcan4x5x_regmap_init(): use spi as context pointer can: tcan4x5x: tcan4x5x_regmap_write(): remove not needed casts and replace 4 by sizeof can: tcan4x5x: rename regmap_spi_gather_write() -> tcan4x5x_regmap_gather_write() can: tcan4x5x: remove regmap async support can: tcan4x5x: tcan4x5x_bus: remove not needed read_flag_mask can: tcan4x5x: mark struct regmap_bus tcan4x5x_bus as constant can: tcan4x5x: move regmap code into seperate file can: tcan4x5x: rename tcan4x5x.c -> tcan4x5x-core.c can: tcan4x5x: beautify indention of tcan4x5x_of_match and tcan4x5x_id_table can: tcan4x5x: replace DEVICE_NAME by KBUILD_MODNAME ==================== Link: https://lore.kernel.org/r/20210107094900.173046-1-mkl@pengutronix.deSigned-off-by:
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Rafał Miłecki authored
Looking for an -EINVAL all over the dsa code could take hours for inexperienced DSA users. Signed-off-by:
Rafał Miłecki <rafal@milecki.pl> Reviewed-by:
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- 06 Jan, 2021 7 commits
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Joakim Zhang authored
The System Controller Firmware (SCFW) is a low-level system function which runs on a dedicated Cortex-M core to provide power, clock, and resource management. It exists on some i.MX8 processors. e.g. i.MX8QM (QM, QP), and i.MX8QX (QXP, DX). SCU driver manages the IPC interface between host CPU and the SCU firmware running on M4. For i.MX8QM, stop mode request is controlled by System Controller Unit(SCU) firmware, this patch introduces FLEXCAN_QUIRK_SETUP_STOP_MODE_SCFW quirk for this function. Signed-off-by:
Joakim Zhang <qiangqing.zhang@nxp.com> Link: https://lore.kernel.org/r/20201106105627.31061-6-qiangqing.zhang@nxp.comSigned-off-by:
Marc Kleine-Budde <mkl@pengutronix.de>
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Joakim Zhang authored
For SoCs with SCU support, need setup stop mode via SCU firmware, so this property can help indicate a resource in SCU firmware. Signed-off-by:
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Oliver Hartkopp authored
Multiple filters (struct can_filter) can be set with the setsockopt() function, which was originally intended as a write-only operation. As getsockopt() also provides a CAN_RAW_FILTER option to read back the given filters, the caller has to provide an appropriate user space buffer. In the case this buffer is too small the getsockopt() silently truncates the filter information and gives no information about the needed space. This is safe but not convenient for the programmer. In net/core/sock.c the SO_PEERGROUPS sockopt had a similar requirement and solved it by returning -ERANGE in the case that the provided data does not fit into the given user space buffer and fills the required size into optlen, so that the caller can retry with a matching buffer length. This patch adopts this approach for CAN_RAW_FILTER getsockopt(). Reported-by:
Phillip Schichtel <phillip@schich.tel> Signed-off-by:
Oliver Hartkopp <socketcan@hartkopp.net> Tested-By:
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Marc Kleine-Budde authored
This patch adds back support for half-duplex controllers, which was removed in the last patch. Reviewed-by:
Dan Murphy <dmurphy@ti.com> Tested-by:
Sean Nyekjaer <sean@geanix.com> Link: https://lore.kernel.org/r/20201215231746.1132907-17-mkl@pengutronix.deSigned-off-by:
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Marc Kleine-Budde authored
This patch reworks the SPI access and fixes several probems: - tcan4x5x_regmap_gather_write(), tcan4x5x_regmap_read(): Do not place variable "addr" on stack and use it as buffer for SPI transfer. Buffers for SPI transfers must be allocated from DMA save memory. - tcan4x5x_regmap_gather_write(), tcan4x5x_regmap_read(): Halfe number of SPI transfers by using a single buffer + memcpy(). This improves the performance, especially on SPI controllers, which use interrupt based transfers. - Use "8" bits per word, not "32". This makes it possible to use this driver on SoCs like the Raspberry Pi, which SPI host controller drivers only support 8 bits per word. Note: this breaks half duplex only controllers. Support for them will be re-added in the next patch. Reviewed-by:
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Marc Kleine-Budde authored
The memory space of the chip is not fully populated, so add a regmap range table to document this. Reviewed-by:
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Marc Kleine-Budde authored
The tcan4x5x chip support bulk read/write, but as the length field is only 8 bits wide, the maximum is 256. A length of 0 is treated as 256. Reviewed-by:
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