-
Vladimir Oltean authored
The NXP ENETC is a 4-port Ethernet controller which 'smells' to operating systems like 4 distinct PCIe PFs with SR-IOV, each PF having its own driver instance, but in fact there are some hardware resources which are shared between all ports, like for example the 256 KB SRAM FIFO between the MACs and the Host Transfer Agent which DMAs frames to DRAM. To hide the stuff that cannot be neatly exposed per port, the hardware designers came up with this idea of having a dedicated register block which is supposed to be populated by the bootloader, and contains everything configuration-related: MAC addresses, FIFO partitioning, etc. When a port is reset using PCIe Function Level Reset, its defaults are transferred from the IERB configuration. Most of the time, the settings made through the IERB are read-only in the port's memory space (if they are even visible), so they cannot be modified at runtime. Linux doesn't have any advanced FIFO partitioning requirements at all, but when reading through the hardware manual, it became clear that, even though there are many good 'recommendations' for default values, many of them were not actually put in practice on LS1028A. So we end up with a default configuration that: (a) does not have enough TX and RX byte credits to support the max MTU of 9600 (which the Linux driver claims already) properly (at full speed) (b) allows the FIFO to be overrun with RX traffic, potentially overwriting internal data structures. The last part sounds a bit catastrophic, but it isn't. Frames are supposed to transit the FIFO for a very short time, but they can actually accumulate there under 2 conditions: (a) there is very severe congestion on DRAM memory, or (b) the RX rings visible to the operating system were configured for lossless operation, and they just ran out of free buffers to copy the frame to. This is what is used to put backpressure onto the MAC with flow control. So since ENETC has not supported flow control thus far, RX FIFO overruns were never seen with Linux. But with the addition of flow control, we should configure some registers to prevent this from happening. What we are trying to protect against are bad actors which continue to send us traffic despite the fact that we have signaled a PAUSE condition. Of course we can't be lossless in that case, but it is best to configure the FIFO to do tail dropping rather than letting it overrun. So in a nutshell, this driver is a fixup for all the IERB default values that should have been but aren't. The IERB configuration needs to be done _before_ the PFs are enabled. So every PF searches for the presence of the "fsl,ls1028a-enetc-ierb" node in the device tree, and if it finds it, it "registers" with the IERB, which means that it requests the IERB to fix up its default values. This is done through -EPROBE_DEFER. The IERB driver is part of the fsl_enetc module, but is technically a platform driver, since the IERB is a good old fashioned MMIO region, as opposed to ENETC ports which pretend to be PCIe devices. The driver was already configuring ENETC_PTXMBAR (FIFO allocation for TX) because due to an omission, TXMBAR is a read/write register in the PF memory space. But the manual is quite clear that the formula for this should depend upon the TX byte credits (TXBCR). In turn, the TX byte credits are only readable/writable through the IERB. So if we want to ensure that the TXBCR register also has a value that is correct and in line with TXMBAR, there is simply no way this can be done from the PF driver, access to the IERB is needed. I could have modified U-Boot to fix up the IERB values, but that is quite undesirable, as old U-Boot versions are likely to be floating around for quite some time from now. Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Signed-off-by: David S. Miller <davem@davemloft.net>
e7d48e5f