net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
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/* SPDX-License-Identifier: GPL-2.0 */
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/* Copyright 2019 NXP Semiconductors
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*/
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#ifndef _MSCC_FELIX_H
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#define _MSCC_FELIX_H
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#define ocelot_to_felix(o) container_of((o), struct felix, ocelot)
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/* Platform-specific information */
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struct felix_info {
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2020-05-22 11:54:34 +03:00
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const struct resource *target_io_res;
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const struct resource *port_io_res;
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const struct resource *imdio_res;
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net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
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const struct reg_field *regfields;
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const u32 *const *map;
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const struct ocelot_ops *ops;
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2020-05-04 01:20:26 +03:00
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int num_mact_rows;
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net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
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const struct ocelot_stat_layout *stats_layout;
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unsigned int num_stats;
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int num_ports;
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2020-09-18 13:57:49 +03:00
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int num_tx_queues;
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2020-09-30 01:27:26 +03:00
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struct vcap_props *vcap;
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net: dsa: felix: Add PCS operations for PHYLINK
Layerscape SoCs traditionally expose the SerDes configuration/status for
Ethernet protocols (PCS for SGMII/USXGMII/10GBase-R etc etc) in a register
format that is compatible with clause 22 or clause 45 (depending on
SerDes protocol). Each MAC has its own internal MDIO bus on which there
is one or more of these PCS's, responding to commands at a configurable
PHY address. The per-port internal MDIO bus (which is just for PCSs) is
totally separate and has nothing to do with the dedicated external MDIO
controller (which is just for PHYs), but the register map for the MDIO
controller is the same.
The VSC9959 (Felix) switch instantiated in the LS1028A is integrated
in hardware with the ENETC PCS of its DSA master, and reuses its MDIO
controller driver, so Felix has been made to depend on it in Kconfig.
+------------------------------------------------------------------------+
| +--------+ GMII (typically disabled via RCW) |
| ENETC PCI | ENETC |--------------------------+ |
| Root Complex | port 3 |-----------------------+ | |
| Integrated +--------+ | | |
| Endpoint | | |
| +--------+ 2.5G GMII | | |
| | ENETC |--------------+ | | |
| | port 2 |-----------+ | | | |
| +--------+ | | | | |
| +--------+ +--------+ |
| | Felix | | Felix | |
| | port 4 | | port 5 | |
| +--------+ +--------+ |
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| +--------+ +--------+ +--------+ +--------+ +--------+ +--------+ |
| | ENETC | | ENETC | | Felix | | Felix | | Felix | | Felix | |
| | port 0 | | port 1 | | port 0 | | port 1 | | port 2 | | port 3 | |
+------------------------------------------------------------------------+
| |||| SerDes | |||| |||| |||| |||| |
| +--------+block | +--------------------------------------------+ |
| | ENETC | | | ENETC port 2 internal MDIO bus | |
| | port 0 | | | PCS PCS PCS PCS | |
| | PCS | | | 0 1 2 3 | |
+-----------------|------------------------------------------------------+
v v v v v v
SGMII/ RGMII QSGMII/QSXGMII/4xSGMII/4x1000Base-X/4x2500Base-X
USXGMII/ (bypasses
1000Base-X/ SerDes)
2500Base-X
In the LS1028A SoC described above, the VSC9959 Felix switch is PF5 of
the ENETC root complex, and has 2 BARs:
- BAR 4: the switch's effective registers
- BAR 0: the MDIO controller register map lended from ENETC port 2
(PF2), for accessing its associated PCS's.
This explanation is necessary because the patch does some renaming
"pci_bar" -> "switch_pci_bar" for clarity, which would otherwise appear
a bit obtuse.
The fact that the internal MDIO bus is "borrowed" is relevant because
the register map is found in PF5 (the switch) but it triggers an access
fault if PF2 (the ENETC DSA master) is not enabled. This is not treated
in any way (and I don't think it can be treated).
All of this is so SoC-specific, that it was contained as much as
possible in the platform-integration file felix_vsc9959.c.
We need to parse and pre-validate the device tree because of 2 reasons:
- The PHY mode (SerDes protocol) cannot change at runtime due to SoC
design.
- There is a circular dependency in that we need to know what clause the
PCS speaks in order to find it on the internal MDIO bus. But the
clause of the PCS depends on what phy-mode it is configured for.
The goal of this patch is to make steps towards removing the bootloader
dependency for SGMII PCS pre-configuration, as well as to add support
for monitoring the in-band SGMII AN between the PCS and the system-side
link partner (PHY or other MAC).
In practice the bootloader dependency is not completely removed. U-Boot
pre-programs the PHY address at which each PCS can be found on the
internal MDIO bus (MDEV_PORT). This is needed because the PCS of each
port has the same out-of-reset PHY address of zero. The SerDes register
for changing MDEV_PORT is pretty deep in the SoC (outside the addresses
of the ENETC PCI BARs) and therefore inaccessible to us from here.
Felix VSC9959 and Ocelot VSC7514 are integrated very differently in
their respective SoCs, and for that reason Felix does not use the Ocelot
core library for PHYLINK. On one hand we don't want to impose the
fixed phy-mode limitation to Ocelot, and on the other hand Felix doesn't
need to force the MAC link speed the way Ocelot does, since the MAC is
connected to the PCS through a fixed GMII, and the PCS is the one who
does the rate adaptation at lower link speeds, which the MAC does not
even need to know about. In fact changing the GMII speed for Felix
irrecoverably breaks transmission through that port until a reset.
The pair with ENETC port 3 and Felix port 5 is optional and doesn't
support tagging. When we enable it, swp5 is a regular slave port, albeit
an internal one. The trouble is that it doesn't work, and that is
because the DSA PHYLIB adaptation layer doesn't treat fixed-link slave
ports. So that is yet another reason for wanting to convert Felix to the
native PHYLINK API.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2020-01-06 03:34:17 +02:00
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int switch_pci_bar;
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int imdio_pci_bar;
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2020-09-18 13:57:52 +03:00
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const struct ptp_clock_info *ptp_caps;
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net: dsa: felix: setup MMIO filtering rules for PTP when using tag_8021q
Since the tag_8021q tagger is software-defined, it has no means by
itself for retrieving hardware timestamps of PTP event messages.
Because we do want to support PTP on ocelot even with tag_8021q, we need
to use the CPU port module for that. The RX timestamp is present in the
Extraction Frame Header. And because we can't use NPI mode which redirects
the CPU queues to an "external CPU" (meaning the ARM CPU running Linux),
then we need to poll the CPU port module through the MMIO registers to
retrieve TX and RX timestamps.
Sadly, on NXP LS1028A, the Felix switch was integrated into the SoC
without wiring the extraction IRQ line to the ARM GIC. So, if we want to
be notified of any PTP packets received on the CPU port module, we have
a problem.
There is a possible workaround, which is to use the Ethernet CPU port as
a notification channel that packets are available on the CPU port module
as well. When a PTP packet is received by the DSA tagger (without timestamp,
of course), we go to the CPU extraction queues, poll for it there, then
we drop the original Ethernet packet and masquerade the packet retrieved
over MMIO (plus the timestamp) as the original when we inject it up the
stack.
Create a quirk in struct felix is selected by the Felix driver (but not
by Seville, since that doesn't support PTP at all). We want to do this
such that the workaround is minimally invasive for future switches that
don't require this workaround.
The only traffic for which we need timestamps is PTP traffic, so add a
redirection rule to the CPU port module for this. Currently we only have
the need for PTP over L2, so redirection rules for UDP ports 319 and 320
are TBD for now.
Note that for the workaround of matching of PTP-over-Ethernet-port with
PTP-over-MMIO queues to work properly, both channels need to be
absolutely lossless. There are two parts to achieving that:
- We keep flow control enabled on the tag_8021q CPU port
- We put the DSA master interface in promiscuous mode, so it will never
drop a PTP frame (for the profiles we are interested in, these are
sent to the multicast MAC addresses of 01-80-c2-00-00-0e and
01-1b-19-00-00-00).
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Reviewed-by: Florian Fainelli <f.fainelli@gmail.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2021-02-14 00:38:00 +02:00
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/* Some Ocelot switches are integrated into the SoC without the
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* extraction IRQ line connected to the ARM GIC. By enabling this
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* workaround, the few packets that are delivered to the CPU port
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* module (currently only PTP) are copied not only to the hardware CPU
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* port module, but also to the 802.1Q Ethernet CPU port, and polling
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* the extraction registers is triggered once the DSA tagger sees a PTP
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* frame. The Ethernet frame is only used as a notification: it is
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* dropped, and the original frame is extracted over MMIO and annotated
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* with the RX timestamp.
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*/
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bool quirk_no_xtr_irq;
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net: dsa: felix: Add PCS operations for PHYLINK
Layerscape SoCs traditionally expose the SerDes configuration/status for
Ethernet protocols (PCS for SGMII/USXGMII/10GBase-R etc etc) in a register
format that is compatible with clause 22 or clause 45 (depending on
SerDes protocol). Each MAC has its own internal MDIO bus on which there
is one or more of these PCS's, responding to commands at a configurable
PHY address. The per-port internal MDIO bus (which is just for PCSs) is
totally separate and has nothing to do with the dedicated external MDIO
controller (which is just for PHYs), but the register map for the MDIO
controller is the same.
The VSC9959 (Felix) switch instantiated in the LS1028A is integrated
in hardware with the ENETC PCS of its DSA master, and reuses its MDIO
controller driver, so Felix has been made to depend on it in Kconfig.
+------------------------------------------------------------------------+
| +--------+ GMII (typically disabled via RCW) |
| ENETC PCI | ENETC |--------------------------+ |
| Root Complex | port 3 |-----------------------+ | |
| Integrated +--------+ | | |
| Endpoint | | |
| +--------+ 2.5G GMII | | |
| | ENETC |--------------+ | | |
| | port 2 |-----------+ | | | |
| +--------+ | | | | |
| +--------+ +--------+ |
| | Felix | | Felix | |
| | port 4 | | port 5 | |
| +--------+ +--------+ |
| |
| +--------+ +--------+ +--------+ +--------+ +--------+ +--------+ |
| | ENETC | | ENETC | | Felix | | Felix | | Felix | | Felix | |
| | port 0 | | port 1 | | port 0 | | port 1 | | port 2 | | port 3 | |
+------------------------------------------------------------------------+
| |||| SerDes | |||| |||| |||| |||| |
| +--------+block | +--------------------------------------------+ |
| | ENETC | | | ENETC port 2 internal MDIO bus | |
| | port 0 | | | PCS PCS PCS PCS | |
| | PCS | | | 0 1 2 3 | |
+-----------------|------------------------------------------------------+
v v v v v v
SGMII/ RGMII QSGMII/QSXGMII/4xSGMII/4x1000Base-X/4x2500Base-X
USXGMII/ (bypasses
1000Base-X/ SerDes)
2500Base-X
In the LS1028A SoC described above, the VSC9959 Felix switch is PF5 of
the ENETC root complex, and has 2 BARs:
- BAR 4: the switch's effective registers
- BAR 0: the MDIO controller register map lended from ENETC port 2
(PF2), for accessing its associated PCS's.
This explanation is necessary because the patch does some renaming
"pci_bar" -> "switch_pci_bar" for clarity, which would otherwise appear
a bit obtuse.
The fact that the internal MDIO bus is "borrowed" is relevant because
the register map is found in PF5 (the switch) but it triggers an access
fault if PF2 (the ENETC DSA master) is not enabled. This is not treated
in any way (and I don't think it can be treated).
All of this is so SoC-specific, that it was contained as much as
possible in the platform-integration file felix_vsc9959.c.
We need to parse and pre-validate the device tree because of 2 reasons:
- The PHY mode (SerDes protocol) cannot change at runtime due to SoC
design.
- There is a circular dependency in that we need to know what clause the
PCS speaks in order to find it on the internal MDIO bus. But the
clause of the PCS depends on what phy-mode it is configured for.
The goal of this patch is to make steps towards removing the bootloader
dependency for SGMII PCS pre-configuration, as well as to add support
for monitoring the in-band SGMII AN between the PCS and the system-side
link partner (PHY or other MAC).
In practice the bootloader dependency is not completely removed. U-Boot
pre-programs the PHY address at which each PCS can be found on the
internal MDIO bus (MDEV_PORT). This is needed because the PCS of each
port has the same out-of-reset PHY address of zero. The SerDes register
for changing MDEV_PORT is pretty deep in the SoC (outside the addresses
of the ENETC PCI BARs) and therefore inaccessible to us from here.
Felix VSC9959 and Ocelot VSC7514 are integrated very differently in
their respective SoCs, and for that reason Felix does not use the Ocelot
core library for PHYLINK. On one hand we don't want to impose the
fixed phy-mode limitation to Ocelot, and on the other hand Felix doesn't
need to force the MAC link speed the way Ocelot does, since the MAC is
connected to the PCS through a fixed GMII, and the PCS is the one who
does the rate adaptation at lower link speeds, which the MAC does not
even need to know about. In fact changing the GMII speed for Felix
irrecoverably breaks transmission through that port until a reset.
The pair with ENETC port 3 and Felix port 5 is optional and doesn't
support tagging. When we enable it, swp5 is a regular slave port, albeit
an internal one. The trouble is that it doesn't work, and that is
because the DSA PHYLIB adaptation layer doesn't treat fixed-link slave
ports. So that is yet another reason for wanting to convert Felix to the
native PHYLINK API.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2020-01-06 03:34:17 +02:00
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int (*mdio_bus_alloc)(struct ocelot *ocelot);
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void (*mdio_bus_free)(struct ocelot *ocelot);
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2020-07-13 19:57:09 +03:00
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void (*phylink_validate)(struct ocelot *ocelot, int port,
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unsigned long *supported,
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struct phylink_link_state *state);
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net: dsa: felix: Add PCS operations for PHYLINK
Layerscape SoCs traditionally expose the SerDes configuration/status for
Ethernet protocols (PCS for SGMII/USXGMII/10GBase-R etc etc) in a register
format that is compatible with clause 22 or clause 45 (depending on
SerDes protocol). Each MAC has its own internal MDIO bus on which there
is one or more of these PCS's, responding to commands at a configurable
PHY address. The per-port internal MDIO bus (which is just for PCSs) is
totally separate and has nothing to do with the dedicated external MDIO
controller (which is just for PHYs), but the register map for the MDIO
controller is the same.
The VSC9959 (Felix) switch instantiated in the LS1028A is integrated
in hardware with the ENETC PCS of its DSA master, and reuses its MDIO
controller driver, so Felix has been made to depend on it in Kconfig.
+------------------------------------------------------------------------+
| +--------+ GMII (typically disabled via RCW) |
| ENETC PCI | ENETC |--------------------------+ |
| Root Complex | port 3 |-----------------------+ | |
| Integrated +--------+ | | |
| Endpoint | | |
| +--------+ 2.5G GMII | | |
| | ENETC |--------------+ | | |
| | port 2 |-----------+ | | | |
| +--------+ | | | | |
| +--------+ +--------+ |
| | Felix | | Felix | |
| | port 4 | | port 5 | |
| +--------+ +--------+ |
| |
| +--------+ +--------+ +--------+ +--------+ +--------+ +--------+ |
| | ENETC | | ENETC | | Felix | | Felix | | Felix | | Felix | |
| | port 0 | | port 1 | | port 0 | | port 1 | | port 2 | | port 3 | |
+------------------------------------------------------------------------+
| |||| SerDes | |||| |||| |||| |||| |
| +--------+block | +--------------------------------------------+ |
| | ENETC | | | ENETC port 2 internal MDIO bus | |
| | port 0 | | | PCS PCS PCS PCS | |
| | PCS | | | 0 1 2 3 | |
+-----------------|------------------------------------------------------+
v v v v v v
SGMII/ RGMII QSGMII/QSXGMII/4xSGMII/4x1000Base-X/4x2500Base-X
USXGMII/ (bypasses
1000Base-X/ SerDes)
2500Base-X
In the LS1028A SoC described above, the VSC9959 Felix switch is PF5 of
the ENETC root complex, and has 2 BARs:
- BAR 4: the switch's effective registers
- BAR 0: the MDIO controller register map lended from ENETC port 2
(PF2), for accessing its associated PCS's.
This explanation is necessary because the patch does some renaming
"pci_bar" -> "switch_pci_bar" for clarity, which would otherwise appear
a bit obtuse.
The fact that the internal MDIO bus is "borrowed" is relevant because
the register map is found in PF5 (the switch) but it triggers an access
fault if PF2 (the ENETC DSA master) is not enabled. This is not treated
in any way (and I don't think it can be treated).
All of this is so SoC-specific, that it was contained as much as
possible in the platform-integration file felix_vsc9959.c.
We need to parse and pre-validate the device tree because of 2 reasons:
- The PHY mode (SerDes protocol) cannot change at runtime due to SoC
design.
- There is a circular dependency in that we need to know what clause the
PCS speaks in order to find it on the internal MDIO bus. But the
clause of the PCS depends on what phy-mode it is configured for.
The goal of this patch is to make steps towards removing the bootloader
dependency for SGMII PCS pre-configuration, as well as to add support
for monitoring the in-band SGMII AN between the PCS and the system-side
link partner (PHY or other MAC).
In practice the bootloader dependency is not completely removed. U-Boot
pre-programs the PHY address at which each PCS can be found on the
internal MDIO bus (MDEV_PORT). This is needed because the PCS of each
port has the same out-of-reset PHY address of zero. The SerDes register
for changing MDEV_PORT is pretty deep in the SoC (outside the addresses
of the ENETC PCI BARs) and therefore inaccessible to us from here.
Felix VSC9959 and Ocelot VSC7514 are integrated very differently in
their respective SoCs, and for that reason Felix does not use the Ocelot
core library for PHYLINK. On one hand we don't want to impose the
fixed phy-mode limitation to Ocelot, and on the other hand Felix doesn't
need to force the MAC link speed the way Ocelot does, since the MAC is
connected to the PCS through a fixed GMII, and the PCS is the one who
does the rate adaptation at lower link speeds, which the MAC does not
even need to know about. In fact changing the GMII speed for Felix
irrecoverably breaks transmission through that port until a reset.
The pair with ENETC port 3 and Felix port 5 is optional and doesn't
support tagging. When we enable it, swp5 is a regular slave port, albeit
an internal one. The trouble is that it doesn't work, and that is
because the DSA PHYLIB adaptation layer doesn't treat fixed-link slave
ports. So that is yet another reason for wanting to convert Felix to the
native PHYLINK API.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2020-01-06 03:34:17 +02:00
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|
|
int (*prevalidate_phy_mode)(struct ocelot *ocelot, int port,
|
|
|
|
|
phy_interface_t phy_mode);
|
2020-05-13 10:25:09 +08:00
|
|
|
int (*port_setup_tc)(struct dsa_switch *ds, int port,
|
|
|
|
|
enum tc_setup_type type, void *type_data);
|
|
|
|
|
void (*port_sched_speed_set)(struct ocelot *ocelot, int port,
|
|
|
|
|
u32 speed);
|
net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
|
|
|
};
|
|
|
|
|
|
2020-07-13 19:57:09 +03:00
|
|
|
extern const struct dsa_switch_ops felix_switch_ops;
|
net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
|
|
|
|
|
|
|
|
/* DSA glue / front-end for struct ocelot */
|
|
|
|
|
struct felix {
|
|
|
|
|
struct dsa_switch *ds;
|
2020-07-13 19:57:09 +03:00
|
|
|
const struct felix_info *info;
|
net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
|
|
|
struct ocelot ocelot;
|
net: dsa: felix: Add PCS operations for PHYLINK
Layerscape SoCs traditionally expose the SerDes configuration/status for
Ethernet protocols (PCS for SGMII/USXGMII/10GBase-R etc etc) in a register
format that is compatible with clause 22 or clause 45 (depending on
SerDes protocol). Each MAC has its own internal MDIO bus on which there
is one or more of these PCS's, responding to commands at a configurable
PHY address. The per-port internal MDIO bus (which is just for PCSs) is
totally separate and has nothing to do with the dedicated external MDIO
controller (which is just for PHYs), but the register map for the MDIO
controller is the same.
The VSC9959 (Felix) switch instantiated in the LS1028A is integrated
in hardware with the ENETC PCS of its DSA master, and reuses its MDIO
controller driver, so Felix has been made to depend on it in Kconfig.
+------------------------------------------------------------------------+
| +--------+ GMII (typically disabled via RCW) |
| ENETC PCI | ENETC |--------------------------+ |
| Root Complex | port 3 |-----------------------+ | |
| Integrated +--------+ | | |
| Endpoint | | |
| +--------+ 2.5G GMII | | |
| | ENETC |--------------+ | | |
| | port 2 |-----------+ | | | |
| +--------+ | | | | |
| +--------+ +--------+ |
| | Felix | | Felix | |
| | port 4 | | port 5 | |
| +--------+ +--------+ |
| |
| +--------+ +--------+ +--------+ +--------+ +--------+ +--------+ |
| | ENETC | | ENETC | | Felix | | Felix | | Felix | | Felix | |
| | port 0 | | port 1 | | port 0 | | port 1 | | port 2 | | port 3 | |
+------------------------------------------------------------------------+
| |||| SerDes | |||| |||| |||| |||| |
| +--------+block | +--------------------------------------------+ |
| | ENETC | | | ENETC port 2 internal MDIO bus | |
| | port 0 | | | PCS PCS PCS PCS | |
| | PCS | | | 0 1 2 3 | |
+-----------------|------------------------------------------------------+
v v v v v v
SGMII/ RGMII QSGMII/QSXGMII/4xSGMII/4x1000Base-X/4x2500Base-X
USXGMII/ (bypasses
1000Base-X/ SerDes)
2500Base-X
In the LS1028A SoC described above, the VSC9959 Felix switch is PF5 of
the ENETC root complex, and has 2 BARs:
- BAR 4: the switch's effective registers
- BAR 0: the MDIO controller register map lended from ENETC port 2
(PF2), for accessing its associated PCS's.
This explanation is necessary because the patch does some renaming
"pci_bar" -> "switch_pci_bar" for clarity, which would otherwise appear
a bit obtuse.
The fact that the internal MDIO bus is "borrowed" is relevant because
the register map is found in PF5 (the switch) but it triggers an access
fault if PF2 (the ENETC DSA master) is not enabled. This is not treated
in any way (and I don't think it can be treated).
All of this is so SoC-specific, that it was contained as much as
possible in the platform-integration file felix_vsc9959.c.
We need to parse and pre-validate the device tree because of 2 reasons:
- The PHY mode (SerDes protocol) cannot change at runtime due to SoC
design.
- There is a circular dependency in that we need to know what clause the
PCS speaks in order to find it on the internal MDIO bus. But the
clause of the PCS depends on what phy-mode it is configured for.
The goal of this patch is to make steps towards removing the bootloader
dependency for SGMII PCS pre-configuration, as well as to add support
for monitoring the in-band SGMII AN between the PCS and the system-side
link partner (PHY or other MAC).
In practice the bootloader dependency is not completely removed. U-Boot
pre-programs the PHY address at which each PCS can be found on the
internal MDIO bus (MDEV_PORT). This is needed because the PCS of each
port has the same out-of-reset PHY address of zero. The SerDes register
for changing MDEV_PORT is pretty deep in the SoC (outside the addresses
of the ENETC PCI BARs) and therefore inaccessible to us from here.
Felix VSC9959 and Ocelot VSC7514 are integrated very differently in
their respective SoCs, and for that reason Felix does not use the Ocelot
core library for PHYLINK. On one hand we don't want to impose the
fixed phy-mode limitation to Ocelot, and on the other hand Felix doesn't
need to force the MAC link speed the way Ocelot does, since the MAC is
connected to the PCS through a fixed GMII, and the PCS is the one who
does the rate adaptation at lower link speeds, which the MAC does not
even need to know about. In fact changing the GMII speed for Felix
irrecoverably breaks transmission through that port until a reset.
The pair with ENETC port 3 and Felix port 5 is optional and doesn't
support tagging. When we enable it, swp5 is a regular slave port, albeit
an internal one. The trouble is that it doesn't work, and that is
because the DSA PHYLIB adaptation layer doesn't treat fixed-link slave
ports. So that is yet another reason for wanting to convert Felix to the
native PHYLINK API.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2020-01-06 03:34:17 +02:00
|
|
|
struct mii_bus *imdio;
|
2020-08-30 11:34:02 +03:00
|
|
|
struct lynx_pcs **pcs;
|
2020-07-13 19:57:09 +03:00
|
|
|
resource_size_t switch_base;
|
|
|
|
|
resource_size_t imdio_base;
|
net: dsa: felix: perform switch setup for tag_8021q
Unlike sja1105, the only other user of the software-defined tag_8021q.c
tagger format, the implementation we choose for the Felix DSA switch
driver preserves full functionality under a vlan_filtering bridge
(i.e. IP termination works through the DSA user ports under all
circumstances).
The tag_8021q protocol just wants:
- Identifying the ingress switch port based on the RX VLAN ID, as seen
by the CPU. We achieve this by using the TCAM engines (which are also
used for tc-flower offload) to push the RX VLAN as a second, outer
tag, on egress towards the CPU port.
- Steering traffic injected into the switch from the network stack
towards the correct front port based on the TX VLAN, and consuming
(popping) that header on the switch's egress.
A tc-flower pseudocode of the static configuration done by the driver
would look like this:
$ tc qdisc add dev <cpu-port> clsact
$ for eth in swp0 swp1 swp2 swp3; do \
tc filter add dev <cpu-port> egress flower indev ${eth} \
action vlan push id <rxvlan> protocol 802.1ad; \
tc filter add dev <cpu-port> ingress protocol 802.1Q flower
vlan_id <txvlan> action vlan pop \
action mirred egress redirect dev ${eth}; \
done
but of course since DSA does not register network interfaces for the CPU
port, this configuration would be impossible for the user to do. Also,
due to the same reason, it is impossible for the user to inadvertently
delete these rules using tc. These rules do not collide in any way with
tc-flower, they just consume some TCAM space, which is something we can
live with.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Reviewed-by: Florian Fainelli <f.fainelli@gmail.com>
Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-01-29 03:00:09 +02:00
|
|
|
struct dsa_8021q_context *dsa_8021q_ctx;
|
net: dsa: felix: convert to the new .change_tag_protocol DSA API
In expectation of the new tag_ocelot_8021q tagger implementation, we
need to be able to do runtime switchover between one tagger and another.
So we must structure the existing code for the current NPI-based tagger
in a certain way.
We move the felix_npi_port_init function in expectation of the future
driver configuration necessary for tag_ocelot_8021q: we would like to
not have the NPI-related bits interspersed with the tag_8021q bits.
The conversion from this:
ocelot_write_rix(ocelot,
ANA_PGID_PGID_PGID(GENMASK(ocelot->num_phys_ports, 0)),
ANA_PGID_PGID, PGID_UC);
to this:
cpu_flood = ANA_PGID_PGID_PGID(BIT(ocelot->num_phys_ports));
ocelot_rmw_rix(ocelot, cpu_flood, cpu_flood, ANA_PGID_PGID, PGID_UC);
is perhaps non-trivial, but is nonetheless non-functional. The PGID_UC
(replicator for unknown unicast) is already configured out of hardware
reset to flood to all ports except ocelot->num_phys_ports (the CPU port
module). All we change is that we use a read-modify-write to only add
the CPU port module to the unknown unicast replicator, as opposed to
doing a full write to the register.
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-01-29 03:00:07 +02:00
|
|
|
enum dsa_tag_protocol tag_proto;
|
net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
|
|
|
};
|
|
|
|
|
|
2020-10-02 15:02:21 +03:00
|
|
|
struct net_device *felix_port_to_netdev(struct ocelot *ocelot, int port);
|
|
|
|
|
int felix_netdev_to_port(struct net_device *dev);
|
|
|
|
|
|
net: dsa: ocelot: add driver for Felix switch family
This supports an Ethernet switching core from Vitesse / Microsemi /
Microchip (VSC9959) which is part of the Ocelot family (a brand name),
and whose code name is Felix. The switch can be (and is) integrated on
different SoCs as a PCIe endpoint device.
The functionality is provided by the core of the Ocelot switch driver
(drivers/net/ethernet/mscc). In this regard, the current driver is an
instance of Microsemi's Ocelot core driver, with a DSA front-end. It
inherits its name from VSC9959's code name, to distinguish itself from
the switchdev ocelot driver.
The patch adds the logic for probing a PCI device and defines the
register map for the VSC9959 switch core, since it has some differences
in register addresses and bitfield mappings compared to the other Ocelot
switches (VSC7511, VSC7512, VSC7513, VSC7514).
The Felix driver declares the register map as part of the "instance
table". Currently the VSC9959 inside NXP LS1028A is the only instance,
but presumably it can support other switches in the Ocelot family, when
used in DSA mode (Linux running on the external CPU, and not on the
embedded MIPS).
In a few cases, some h/w operations have to be done differently on
VSC9959 due to missing bitfields. This is the case for the switch core
reset and init. Because for this operation Ocelot uses some bits that
are not present on Felix, the latter has to use a register from the
global registers block (GCB) instead.
Although it is a PCI driver, it relies on DT bindings for compatibility
with DSA (CPU port link, PHY library). It does not have any custom
device tree bindings, since we would like to minimize its dependency on
device tree though.
Signed-off-by: Claudiu Manoil <claudiu.manoil@nxp.com>
Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-11-14 17:03:30 +02:00
|
|
|
#endif
|