linux_dsm_epyc7002/drivers/net/dsa/sja1105/sja1105_dynamic_config.c
Vladimir Oltean 7f1e4ba814 net: dsa: sja1105: Add static config tables for scheduling
In order to support tc-taprio offload, the TTEthernet egress scheduling
core registers must be made visible through the static interface.

Signed-off-by: Vladimir Oltean <olteanv@gmail.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2019-09-16 21:32:57 +02:00

829 lines
29 KiB
C

// SPDX-License-Identifier: GPL-2.0
/* Copyright (c) 2018-2019, Vladimir Oltean <olteanv@gmail.com>
*/
#include "sja1105.h"
/* In the dynamic configuration interface, the switch exposes a register-like
* view of some of the static configuration tables.
* Many times the field organization of the dynamic tables is abbreviated (not
* all fields are dynamically reconfigurable) and different from the static
* ones, but the key reason for having it is that we can spare a switch reset
* for settings that can be changed dynamically.
*
* This file creates a per-switch-family abstraction called
* struct sja1105_dynamic_table_ops and two operations that work with it:
* - sja1105_dynamic_config_write
* - sja1105_dynamic_config_read
*
* Compared to the struct sja1105_table_ops from sja1105_static_config.c,
* the dynamic accessors work with a compound buffer:
*
* packed_buf
*
* |
* V
* +-----------------------------------------+------------------+
* | ENTRY BUFFER | COMMAND BUFFER |
* +-----------------------------------------+------------------+
*
* <----------------------- packed_size ------------------------>
*
* The ENTRY BUFFER may or may not have the same layout, or size, as its static
* configuration table entry counterpart. When it does, the same packing
* function is reused (bar exceptional cases - see
* sja1105pqrs_dyn_l2_lookup_entry_packing).
*
* The reason for the COMMAND BUFFER being at the end is to be able to send
* a dynamic write command through a single SPI burst. By the time the switch
* reacts to the command, the ENTRY BUFFER is already populated with the data
* sent by the core.
*
* The COMMAND BUFFER is always SJA1105_SIZE_DYN_CMD bytes (one 32-bit word) in
* size.
*
* Sometimes the ENTRY BUFFER does not really exist (when the number of fields
* that can be reconfigured is small), then the switch repurposes some of the
* unused 32 bits of the COMMAND BUFFER to hold ENTRY data.
*
* The key members of struct sja1105_dynamic_table_ops are:
* - .entry_packing: A function that deals with packing an ENTRY structure
* into an SPI buffer, or retrieving an ENTRY structure
* from one.
* The @packed_buf pointer it's given does always point to
* the ENTRY portion of the buffer.
* - .cmd_packing: A function that deals with packing/unpacking the COMMAND
* structure to/from the SPI buffer.
* It is given the same @packed_buf pointer as .entry_packing,
* so most of the time, the @packed_buf points *behind* the
* COMMAND offset inside the buffer.
* To access the COMMAND portion of the buffer, the function
* knows its correct offset.
* Giving both functions the same pointer is handy because in
* extreme cases (see sja1105pqrs_dyn_l2_lookup_entry_packing)
* the .entry_packing is able to jump to the COMMAND portion,
* or vice-versa (sja1105pqrs_l2_lookup_cmd_packing).
* - .access: A bitmap of:
* OP_READ: Set if the hardware manual marks the ENTRY portion of the
* dynamic configuration table buffer as R (readable) after
* an SPI read command (the switch will populate the buffer).
* OP_WRITE: Set if the manual marks the ENTRY portion of the dynamic
* table buffer as W (writable) after an SPI write command
* (the switch will read the fields provided in the buffer).
* OP_DEL: Set if the manual says the VALIDENT bit is supported in the
* COMMAND portion of this dynamic config buffer (i.e. the
* specified entry can be invalidated through a SPI write
* command).
* OP_SEARCH: Set if the manual says that the index of an entry can
* be retrieved in the COMMAND portion of the buffer based
* on its ENTRY portion, as a result of a SPI write command.
* Only the TCAM-based FDB table on SJA1105 P/Q/R/S supports
* this.
* - .max_entry_count: The number of entries, counting from zero, that can be
* reconfigured through the dynamic interface. If a static
* table can be reconfigured at all dynamically, this
* number always matches the maximum number of supported
* static entries.
* - .packed_size: The length in bytes of the compound ENTRY + COMMAND BUFFER.
* Note that sometimes the compound buffer may contain holes in
* it (see sja1105_vlan_lookup_cmd_packing). The @packed_buf is
* contiguous however, so @packed_size includes any unused
* bytes.
* - .addr: The base SPI address at which the buffer must be written to the
* switch's memory. When looking at the hardware manual, this must
* always match the lowest documented address for the ENTRY, and not
* that of the COMMAND, since the other 32-bit words will follow along
* at the correct addresses.
*/
#define SJA1105_SIZE_DYN_CMD 4
#define SJA1105ET_SIZE_MAC_CONFIG_DYN_ENTRY \
SJA1105_SIZE_DYN_CMD
#define SJA1105ET_SIZE_L2_LOOKUP_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + SJA1105ET_SIZE_L2_LOOKUP_ENTRY)
#define SJA1105PQRS_SIZE_L2_LOOKUP_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY)
#define SJA1105_SIZE_VLAN_LOOKUP_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + 4 + SJA1105_SIZE_VLAN_LOOKUP_ENTRY)
#define SJA1105_SIZE_L2_FORWARDING_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + SJA1105_SIZE_L2_FORWARDING_ENTRY)
#define SJA1105ET_SIZE_MAC_CONFIG_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + SJA1105ET_SIZE_MAC_CONFIG_DYN_ENTRY)
#define SJA1105PQRS_SIZE_MAC_CONFIG_DYN_CMD \
(SJA1105_SIZE_DYN_CMD + SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY)
#define SJA1105ET_SIZE_L2_LOOKUP_PARAMS_DYN_CMD \
SJA1105_SIZE_DYN_CMD
#define SJA1105ET_SIZE_GENERAL_PARAMS_DYN_CMD \
SJA1105_SIZE_DYN_CMD
#define SJA1105_MAX_DYN_CMD_SIZE \
SJA1105PQRS_SIZE_MAC_CONFIG_DYN_CMD
struct sja1105_dyn_cmd {
bool search;
u64 valid;
u64 rdwrset;
u64 errors;
u64 valident;
u64 index;
};
enum sja1105_hostcmd {
SJA1105_HOSTCMD_SEARCH = 1,
SJA1105_HOSTCMD_READ = 2,
SJA1105_HOSTCMD_WRITE = 3,
SJA1105_HOSTCMD_INVALIDATE = 4,
};
static void
sja1105pqrs_l2_lookup_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY;
const int size = SJA1105_SIZE_DYN_CMD;
u64 hostcmd;
sja1105_packing(p, &cmd->valid, 31, 31, size, op);
sja1105_packing(p, &cmd->rdwrset, 30, 30, size, op);
sja1105_packing(p, &cmd->errors, 29, 29, size, op);
sja1105_packing(p, &cmd->valident, 27, 27, size, op);
/* VALIDENT is supposed to indicate "keep or not", but in SJA1105 E/T,
* using it to delete a management route was unsupported. UM10944
* said about it:
*
* In case of a write access with the MGMTROUTE flag set,
* the flag will be ignored. It will always be found cleared
* for read accesses with the MGMTROUTE flag set.
*
* SJA1105 P/Q/R/S keeps the same behavior w.r.t. VALIDENT, but there
* is now another flag called HOSTCMD which does more stuff (quoting
* from UM11040):
*
* A write request is accepted only when HOSTCMD is set to write host
* or invalid. A read request is accepted only when HOSTCMD is set to
* search host or read host.
*
* So it is possible to translate a RDWRSET/VALIDENT combination into
* HOSTCMD so that we keep the dynamic command API in place, and
* at the same time achieve compatibility with the management route
* command structure.
*/
if (cmd->rdwrset == SPI_READ) {
if (cmd->search)
hostcmd = SJA1105_HOSTCMD_SEARCH;
else
hostcmd = SJA1105_HOSTCMD_READ;
} else {
/* SPI_WRITE */
if (cmd->valident)
hostcmd = SJA1105_HOSTCMD_WRITE;
else
hostcmd = SJA1105_HOSTCMD_INVALIDATE;
}
sja1105_packing(p, &hostcmd, 25, 23, size, op);
/* Hack - The hardware takes the 'index' field within
* struct sja1105_l2_lookup_entry as the index on which this command
* will operate. However it will ignore everything else, so 'index'
* is logically part of command but physically part of entry.
* Populate the 'index' entry field from within the command callback,
* such that our API doesn't need to ask for a full-blown entry
* structure when e.g. a delete is requested.
*/
sja1105_packing(buf, &cmd->index, 15, 6,
SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY, op);
}
/* The switch is so retarded that it makes our command/entry abstraction
* crumble apart.
*
* On P/Q/R/S, the switch tries to say whether a FDB entry
* is statically programmed or dynamically learned via a flag called LOCKEDS.
* The hardware manual says about this fiels:
*
* On write will specify the format of ENTRY.
* On read the flag will be found cleared at times the VALID flag is found
* set. The flag will also be found cleared in response to a read having the
* MGMTROUTE flag set. In response to a read with the MGMTROUTE flag
* cleared, the flag be set if the most recent access operated on an entry
* that was either loaded by configuration or through dynamic reconfiguration
* (as opposed to automatically learned entries).
*
* The trouble with this flag is that it's part of the *command* to access the
* dynamic interface, and not part of the *entry* retrieved from it.
* Otherwise said, for a sja1105_dynamic_config_read, LOCKEDS is supposed to be
* an output from the switch into the command buffer, and for a
* sja1105_dynamic_config_write, the switch treats LOCKEDS as an input
* (hence we can write either static, or automatically learned entries, from
* the core).
* But the manual contradicts itself in the last phrase where it says that on
* read, LOCKEDS will be set to 1 for all FDB entries written through the
* dynamic interface (therefore, the value of LOCKEDS from the
* sja1105_dynamic_config_write is not really used for anything, it'll store a
* 1 anyway).
* This means you can't really write a FDB entry with LOCKEDS=0 (automatically
* learned) into the switch, which kind of makes sense.
* As for reading through the dynamic interface, it doesn't make too much sense
* to put LOCKEDS into the command, since the switch will inevitably have to
* ignore it (otherwise a command would be like "read the FDB entry 123, but
* only if it's dynamically learned" <- well how am I supposed to know?) and
* just use it as an output buffer for its findings. But guess what... that's
* what the entry buffer is for!
* Unfortunately, what really breaks this abstraction is the fact that it
* wasn't designed having the fact in mind that the switch can output
* entry-related data as writeback through the command buffer.
* However, whether a FDB entry is statically or dynamically learned *is* part
* of the entry and not the command data, no matter what the switch thinks.
* In order to do that, we'll need to wrap around the
* sja1105pqrs_l2_lookup_entry_packing from sja1105_static_config.c, and take
* a peek outside of the caller-supplied @buf (the entry buffer), to reach the
* command buffer.
*/
static size_t
sja1105pqrs_dyn_l2_lookup_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_lookup_entry *entry = entry_ptr;
u8 *cmd = buf + SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY;
const int size = SJA1105_SIZE_DYN_CMD;
sja1105_packing(cmd, &entry->lockeds, 28, 28, size, op);
return sja1105pqrs_l2_lookup_entry_packing(buf, entry_ptr, op);
}
static void
sja1105et_l2_lookup_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105ET_SIZE_L2_LOOKUP_ENTRY;
const int size = SJA1105_SIZE_DYN_CMD;
sja1105_packing(p, &cmd->valid, 31, 31, size, op);
sja1105_packing(p, &cmd->rdwrset, 30, 30, size, op);
sja1105_packing(p, &cmd->errors, 29, 29, size, op);
sja1105_packing(p, &cmd->valident, 27, 27, size, op);
/* Hack - see comments above. */
sja1105_packing(buf, &cmd->index, 29, 20,
SJA1105ET_SIZE_L2_LOOKUP_ENTRY, op);
}
static size_t sja1105et_dyn_l2_lookup_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_lookup_entry *entry = entry_ptr;
u8 *cmd = buf + SJA1105ET_SIZE_L2_LOOKUP_ENTRY;
const int size = SJA1105_SIZE_DYN_CMD;
sja1105_packing(cmd, &entry->lockeds, 28, 28, size, op);
return sja1105et_l2_lookup_entry_packing(buf, entry_ptr, op);
}
static void
sja1105et_mgmt_route_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105ET_SIZE_L2_LOOKUP_ENTRY;
u64 mgmtroute = 1;
sja1105et_l2_lookup_cmd_packing(buf, cmd, op);
if (op == PACK)
sja1105_pack(p, &mgmtroute, 26, 26, SJA1105_SIZE_DYN_CMD);
}
static size_t sja1105et_mgmt_route_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_mgmt_entry *entry = entry_ptr;
const size_t size = SJA1105ET_SIZE_L2_LOOKUP_ENTRY;
/* UM10944: To specify if a PTP egress timestamp shall be captured on
* each port upon transmission of the frame, the LSB of VLANID in the
* ENTRY field provided by the host must be set.
* Bit 1 of VLANID then specifies the register where the timestamp for
* this port is stored in.
*/
sja1105_packing(buf, &entry->tsreg, 85, 85, size, op);
sja1105_packing(buf, &entry->takets, 84, 84, size, op);
sja1105_packing(buf, &entry->macaddr, 83, 36, size, op);
sja1105_packing(buf, &entry->destports, 35, 31, size, op);
sja1105_packing(buf, &entry->enfport, 30, 30, size, op);
return size;
}
static void
sja1105pqrs_mgmt_route_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY;
u64 mgmtroute = 1;
sja1105pqrs_l2_lookup_cmd_packing(buf, cmd, op);
if (op == PACK)
sja1105_pack(p, &mgmtroute, 26, 26, SJA1105_SIZE_DYN_CMD);
}
static size_t sja1105pqrs_mgmt_route_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const size_t size = SJA1105PQRS_SIZE_L2_LOOKUP_ENTRY;
struct sja1105_mgmt_entry *entry = entry_ptr;
/* In P/Q/R/S, enfport got renamed to mgmtvalid, but its purpose
* is the same (driver uses it to confirm that frame was sent).
* So just keep the name from E/T.
*/
sja1105_packing(buf, &entry->tsreg, 71, 71, size, op);
sja1105_packing(buf, &entry->takets, 70, 70, size, op);
sja1105_packing(buf, &entry->macaddr, 69, 22, size, op);
sja1105_packing(buf, &entry->destports, 21, 17, size, op);
sja1105_packing(buf, &entry->enfport, 16, 16, size, op);
return size;
}
/* In E/T, entry is at addresses 0x27-0x28. There is a 4 byte gap at 0x29,
* and command is at 0x2a. Similarly in P/Q/R/S there is a 1 register gap
* between entry (0x2d, 0x2e) and command (0x30).
*/
static void
sja1105_vlan_lookup_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105_SIZE_VLAN_LOOKUP_ENTRY + 4;
const int size = SJA1105_SIZE_DYN_CMD;
sja1105_packing(p, &cmd->valid, 31, 31, size, op);
sja1105_packing(p, &cmd->rdwrset, 30, 30, size, op);
sja1105_packing(p, &cmd->valident, 27, 27, size, op);
/* Hack - see comments above, applied for 'vlanid' field of
* struct sja1105_vlan_lookup_entry.
*/
sja1105_packing(buf, &cmd->index, 38, 27,
SJA1105_SIZE_VLAN_LOOKUP_ENTRY, op);
}
static void
sja1105_l2_forwarding_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
u8 *p = buf + SJA1105_SIZE_L2_FORWARDING_ENTRY;
const int size = SJA1105_SIZE_DYN_CMD;
sja1105_packing(p, &cmd->valid, 31, 31, size, op);
sja1105_packing(p, &cmd->errors, 30, 30, size, op);
sja1105_packing(p, &cmd->rdwrset, 29, 29, size, op);
sja1105_packing(p, &cmd->index, 4, 0, size, op);
}
static void
sja1105et_mac_config_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
const int size = SJA1105_SIZE_DYN_CMD;
/* Yup, user manual definitions are reversed */
u8 *reg1 = buf + 4;
sja1105_packing(reg1, &cmd->valid, 31, 31, size, op);
sja1105_packing(reg1, &cmd->index, 26, 24, size, op);
}
static size_t sja1105et_mac_config_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
const int size = SJA1105ET_SIZE_MAC_CONFIG_DYN_ENTRY;
struct sja1105_mac_config_entry *entry = entry_ptr;
/* Yup, user manual definitions are reversed */
u8 *reg1 = buf + 4;
u8 *reg2 = buf;
sja1105_packing(reg1, &entry->speed, 30, 29, size, op);
sja1105_packing(reg1, &entry->drpdtag, 23, 23, size, op);
sja1105_packing(reg1, &entry->drpuntag, 22, 22, size, op);
sja1105_packing(reg1, &entry->retag, 21, 21, size, op);
sja1105_packing(reg1, &entry->dyn_learn, 20, 20, size, op);
sja1105_packing(reg1, &entry->egress, 19, 19, size, op);
sja1105_packing(reg1, &entry->ingress, 18, 18, size, op);
sja1105_packing(reg1, &entry->ing_mirr, 17, 17, size, op);
sja1105_packing(reg1, &entry->egr_mirr, 16, 16, size, op);
sja1105_packing(reg1, &entry->vlanprio, 14, 12, size, op);
sja1105_packing(reg1, &entry->vlanid, 11, 0, size, op);
sja1105_packing(reg2, &entry->tp_delin, 31, 16, size, op);
sja1105_packing(reg2, &entry->tp_delout, 15, 0, size, op);
/* MAC configuration table entries which can't be reconfigured:
* top, base, enabled, ifg, maxage, drpnona664
*/
/* Bogus return value, not used anywhere */
return 0;
}
static void
sja1105pqrs_mac_config_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
const int size = SJA1105ET_SIZE_MAC_CONFIG_DYN_ENTRY;
u8 *p = buf + SJA1105PQRS_SIZE_MAC_CONFIG_ENTRY;
sja1105_packing(p, &cmd->valid, 31, 31, size, op);
sja1105_packing(p, &cmd->errors, 30, 30, size, op);
sja1105_packing(p, &cmd->rdwrset, 29, 29, size, op);
sja1105_packing(p, &cmd->index, 2, 0, size, op);
}
static void
sja1105et_l2_lookup_params_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
sja1105_packing(buf, &cmd->valid, 31, 31,
SJA1105ET_SIZE_L2_LOOKUP_PARAMS_DYN_CMD, op);
}
static size_t
sja1105et_l2_lookup_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_l2_lookup_params_entry *entry = entry_ptr;
sja1105_packing(buf, &entry->poly, 7, 0,
SJA1105ET_SIZE_L2_LOOKUP_PARAMS_DYN_CMD, op);
/* Bogus return value, not used anywhere */
return 0;
}
static void
sja1105et_general_params_cmd_packing(void *buf, struct sja1105_dyn_cmd *cmd,
enum packing_op op)
{
const int size = SJA1105ET_SIZE_GENERAL_PARAMS_DYN_CMD;
sja1105_packing(buf, &cmd->valid, 31, 31, size, op);
sja1105_packing(buf, &cmd->errors, 30, 30, size, op);
}
static size_t
sja1105et_general_params_entry_packing(void *buf, void *entry_ptr,
enum packing_op op)
{
struct sja1105_general_params_entry *entry = entry_ptr;
const int size = SJA1105ET_SIZE_GENERAL_PARAMS_DYN_CMD;
sja1105_packing(buf, &entry->mirr_port, 2, 0, size, op);
/* Bogus return value, not used anywhere */
return 0;
}
#define OP_READ BIT(0)
#define OP_WRITE BIT(1)
#define OP_DEL BIT(2)
#define OP_SEARCH BIT(3)
/* SJA1105E/T: First generation */
struct sja1105_dynamic_table_ops sja1105et_dyn_ops[BLK_IDX_MAX_DYN] = {
[BLK_IDX_SCHEDULE] = {0},
[BLK_IDX_SCHEDULE_ENTRY_POINTS] = {0},
[BLK_IDX_L2_LOOKUP] = {
.entry_packing = sja1105et_dyn_l2_lookup_entry_packing,
.cmd_packing = sja1105et_l2_lookup_cmd_packing,
.access = (OP_READ | OP_WRITE | OP_DEL),
.max_entry_count = SJA1105_MAX_L2_LOOKUP_COUNT,
.packed_size = SJA1105ET_SIZE_L2_LOOKUP_DYN_CMD,
.addr = 0x20,
},
[BLK_IDX_MGMT_ROUTE] = {
.entry_packing = sja1105et_mgmt_route_entry_packing,
.cmd_packing = sja1105et_mgmt_route_cmd_packing,
.access = (OP_READ | OP_WRITE),
.max_entry_count = SJA1105_NUM_PORTS,
.packed_size = SJA1105ET_SIZE_L2_LOOKUP_DYN_CMD,
.addr = 0x20,
},
[BLK_IDX_L2_POLICING] = {0},
[BLK_IDX_VLAN_LOOKUP] = {
.entry_packing = sja1105_vlan_lookup_entry_packing,
.cmd_packing = sja1105_vlan_lookup_cmd_packing,
.access = (OP_WRITE | OP_DEL),
.max_entry_count = SJA1105_MAX_VLAN_LOOKUP_COUNT,
.packed_size = SJA1105_SIZE_VLAN_LOOKUP_DYN_CMD,
.addr = 0x27,
},
[BLK_IDX_L2_FORWARDING] = {
.entry_packing = sja1105_l2_forwarding_entry_packing,
.cmd_packing = sja1105_l2_forwarding_cmd_packing,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105_SIZE_L2_FORWARDING_DYN_CMD,
.addr = 0x24,
},
[BLK_IDX_MAC_CONFIG] = {
.entry_packing = sja1105et_mac_config_entry_packing,
.cmd_packing = sja1105et_mac_config_cmd_packing,
.max_entry_count = SJA1105_MAX_MAC_CONFIG_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105ET_SIZE_MAC_CONFIG_DYN_CMD,
.addr = 0x36,
},
[BLK_IDX_SCHEDULE_PARAMS] = {0},
[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS] = {0},
[BLK_IDX_L2_LOOKUP_PARAMS] = {
.entry_packing = sja1105et_l2_lookup_params_entry_packing,
.cmd_packing = sja1105et_l2_lookup_params_cmd_packing,
.max_entry_count = SJA1105_MAX_L2_LOOKUP_PARAMS_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105ET_SIZE_L2_LOOKUP_PARAMS_DYN_CMD,
.addr = 0x38,
},
[BLK_IDX_L2_FORWARDING_PARAMS] = {0},
[BLK_IDX_AVB_PARAMS] = {0},
[BLK_IDX_GENERAL_PARAMS] = {
.entry_packing = sja1105et_general_params_entry_packing,
.cmd_packing = sja1105et_general_params_cmd_packing,
.max_entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105ET_SIZE_GENERAL_PARAMS_DYN_CMD,
.addr = 0x34,
},
[BLK_IDX_XMII_PARAMS] = {0},
};
/* SJA1105P/Q/R/S: Second generation */
struct sja1105_dynamic_table_ops sja1105pqrs_dyn_ops[BLK_IDX_MAX_DYN] = {
[BLK_IDX_SCHEDULE] = {0},
[BLK_IDX_SCHEDULE_ENTRY_POINTS] = {0},
[BLK_IDX_L2_LOOKUP] = {
.entry_packing = sja1105pqrs_dyn_l2_lookup_entry_packing,
.cmd_packing = sja1105pqrs_l2_lookup_cmd_packing,
.access = (OP_READ | OP_WRITE | OP_DEL | OP_SEARCH),
.max_entry_count = SJA1105_MAX_L2_LOOKUP_COUNT,
.packed_size = SJA1105PQRS_SIZE_L2_LOOKUP_DYN_CMD,
.addr = 0x24,
},
[BLK_IDX_MGMT_ROUTE] = {
.entry_packing = sja1105pqrs_mgmt_route_entry_packing,
.cmd_packing = sja1105pqrs_mgmt_route_cmd_packing,
.access = (OP_READ | OP_WRITE | OP_DEL | OP_SEARCH),
.max_entry_count = SJA1105_NUM_PORTS,
.packed_size = SJA1105PQRS_SIZE_L2_LOOKUP_DYN_CMD,
.addr = 0x24,
},
[BLK_IDX_L2_POLICING] = {0},
[BLK_IDX_VLAN_LOOKUP] = {
.entry_packing = sja1105_vlan_lookup_entry_packing,
.cmd_packing = sja1105_vlan_lookup_cmd_packing,
.access = (OP_READ | OP_WRITE | OP_DEL),
.max_entry_count = SJA1105_MAX_VLAN_LOOKUP_COUNT,
.packed_size = SJA1105_SIZE_VLAN_LOOKUP_DYN_CMD,
.addr = 0x2D,
},
[BLK_IDX_L2_FORWARDING] = {
.entry_packing = sja1105_l2_forwarding_entry_packing,
.cmd_packing = sja1105_l2_forwarding_cmd_packing,
.max_entry_count = SJA1105_MAX_L2_FORWARDING_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105_SIZE_L2_FORWARDING_DYN_CMD,
.addr = 0x2A,
},
[BLK_IDX_MAC_CONFIG] = {
.entry_packing = sja1105pqrs_mac_config_entry_packing,
.cmd_packing = sja1105pqrs_mac_config_cmd_packing,
.max_entry_count = SJA1105_MAX_MAC_CONFIG_COUNT,
.access = (OP_READ | OP_WRITE),
.packed_size = SJA1105PQRS_SIZE_MAC_CONFIG_DYN_CMD,
.addr = 0x4B,
},
[BLK_IDX_SCHEDULE_PARAMS] = {0},
[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS] = {0},
[BLK_IDX_L2_LOOKUP_PARAMS] = {
.entry_packing = sja1105et_l2_lookup_params_entry_packing,
.cmd_packing = sja1105et_l2_lookup_params_cmd_packing,
.max_entry_count = SJA1105_MAX_L2_LOOKUP_PARAMS_COUNT,
.access = (OP_READ | OP_WRITE),
.packed_size = SJA1105ET_SIZE_L2_LOOKUP_PARAMS_DYN_CMD,
.addr = 0x38,
},
[BLK_IDX_L2_FORWARDING_PARAMS] = {0},
[BLK_IDX_AVB_PARAMS] = {0},
[BLK_IDX_GENERAL_PARAMS] = {
.entry_packing = sja1105et_general_params_entry_packing,
.cmd_packing = sja1105et_general_params_cmd_packing,
.max_entry_count = SJA1105_MAX_GENERAL_PARAMS_COUNT,
.access = OP_WRITE,
.packed_size = SJA1105ET_SIZE_GENERAL_PARAMS_DYN_CMD,
.addr = 0x34,
},
[BLK_IDX_XMII_PARAMS] = {0},
};
/* Provides read access to the settings through the dynamic interface
* of the switch.
* @blk_idx is used as key to select from the sja1105_dynamic_table_ops.
* The selection is limited by the hardware in respect to which
* configuration blocks can be read through the dynamic interface.
* @index is used to retrieve a particular table entry. If negative,
* (and if the @blk_idx supports the searching operation) a search
* is performed by the @entry parameter.
* @entry Type-casted to an unpacked structure that holds a table entry
* of the type specified in @blk_idx.
* Usually an output argument. If @index is negative, then this
* argument is used as input/output: it should be pre-populated
* with the element to search for. Entries which support the
* search operation will have an "index" field (not the @index
* argument to this function) and that is where the found index
* will be returned (or left unmodified - thus negative - if not
* found).
*/
int sja1105_dynamic_config_read(struct sja1105_private *priv,
enum sja1105_blk_idx blk_idx,
int index, void *entry)
{
const struct sja1105_dynamic_table_ops *ops;
struct sja1105_dyn_cmd cmd = {0};
/* SPI payload buffer */
u8 packed_buf[SJA1105_MAX_DYN_CMD_SIZE] = {0};
int retries = 3;
int rc;
if (blk_idx >= BLK_IDX_MAX_DYN)
return -ERANGE;
ops = &priv->info->dyn_ops[blk_idx];
if (index >= 0 && index >= ops->max_entry_count)
return -ERANGE;
if (index < 0 && !(ops->access & OP_SEARCH))
return -EOPNOTSUPP;
if (!(ops->access & OP_READ))
return -EOPNOTSUPP;
if (ops->packed_size > SJA1105_MAX_DYN_CMD_SIZE)
return -ERANGE;
if (!ops->cmd_packing)
return -EOPNOTSUPP;
if (!ops->entry_packing)
return -EOPNOTSUPP;
cmd.valid = true; /* Trigger action on table entry */
cmd.rdwrset = SPI_READ; /* Action is read */
if (index < 0) {
/* Avoid copying a signed negative number to an u64 */
cmd.index = 0;
cmd.search = true;
} else {
cmd.index = index;
cmd.search = false;
}
cmd.valident = true;
ops->cmd_packing(packed_buf, &cmd, PACK);
if (cmd.search)
ops->entry_packing(packed_buf, entry, PACK);
/* Send SPI write operation: read config table entry */
rc = sja1105_spi_send_packed_buf(priv, SPI_WRITE, ops->addr,
packed_buf, ops->packed_size);
if (rc < 0)
return rc;
/* Loop until we have confirmation that hardware has finished
* processing the command and has cleared the VALID field
*/
do {
memset(packed_buf, 0, ops->packed_size);
/* Retrieve the read operation's result */
rc = sja1105_spi_send_packed_buf(priv, SPI_READ, ops->addr,
packed_buf, ops->packed_size);
if (rc < 0)
return rc;
cmd = (struct sja1105_dyn_cmd) {0};
ops->cmd_packing(packed_buf, &cmd, UNPACK);
/* UM10944: [valident] will always be found cleared
* during a read access with MGMTROUTE set.
* So don't error out in that case.
*/
if (!cmd.valident && blk_idx != BLK_IDX_MGMT_ROUTE)
return -ENOENT;
cpu_relax();
} while (cmd.valid && --retries);
if (cmd.valid)
return -ETIMEDOUT;
/* Don't dereference possibly NULL pointer - maybe caller
* only wanted to see whether the entry existed or not.
*/
if (entry)
ops->entry_packing(packed_buf, entry, UNPACK);
return 0;
}
int sja1105_dynamic_config_write(struct sja1105_private *priv,
enum sja1105_blk_idx blk_idx,
int index, void *entry, bool keep)
{
const struct sja1105_dynamic_table_ops *ops;
struct sja1105_dyn_cmd cmd = {0};
/* SPI payload buffer */
u8 packed_buf[SJA1105_MAX_DYN_CMD_SIZE] = {0};
int rc;
if (blk_idx >= BLK_IDX_MAX_DYN)
return -ERANGE;
ops = &priv->info->dyn_ops[blk_idx];
if (index >= ops->max_entry_count)
return -ERANGE;
if (index < 0)
return -ERANGE;
if (!(ops->access & OP_WRITE))
return -EOPNOTSUPP;
if (!keep && !(ops->access & OP_DEL))
return -EOPNOTSUPP;
if (ops->packed_size > SJA1105_MAX_DYN_CMD_SIZE)
return -ERANGE;
cmd.valident = keep; /* If false, deletes entry */
cmd.valid = true; /* Trigger action on table entry */
cmd.rdwrset = SPI_WRITE; /* Action is write */
cmd.index = index;
if (!ops->cmd_packing)
return -EOPNOTSUPP;
ops->cmd_packing(packed_buf, &cmd, PACK);
if (!ops->entry_packing)
return -EOPNOTSUPP;
/* Don't dereference potentially NULL pointer if just
* deleting a table entry is what was requested. For cases
* where 'index' field is physically part of entry structure,
* and needed here, we deal with that in the cmd_packing callback.
*/
if (keep)
ops->entry_packing(packed_buf, entry, PACK);
/* Send SPI write operation: read config table entry */
rc = sja1105_spi_send_packed_buf(priv, SPI_WRITE, ops->addr,
packed_buf, ops->packed_size);
if (rc < 0)
return rc;
cmd = (struct sja1105_dyn_cmd) {0};
ops->cmd_packing(packed_buf, &cmd, UNPACK);
if (cmd.errors)
return -EINVAL;
return 0;
}
static u8 sja1105_crc8_add(u8 crc, u8 byte, u8 poly)
{
int i;
for (i = 0; i < 8; i++) {
if ((crc ^ byte) & (1 << 7)) {
crc <<= 1;
crc ^= poly;
} else {
crc <<= 1;
}
byte <<= 1;
}
return crc;
}
/* CRC8 algorithm with non-reversed input, non-reversed output,
* no input xor and no output xor. Code customized for receiving
* the SJA1105 E/T FDB keys (vlanid, macaddr) as input. CRC polynomial
* is also received as argument in the Koopman notation that the switch
* hardware stores it in.
*/
u8 sja1105et_fdb_hash(struct sja1105_private *priv, const u8 *addr, u16 vid)
{
struct sja1105_l2_lookup_params_entry *l2_lookup_params =
priv->static_config.tables[BLK_IDX_L2_LOOKUP_PARAMS].entries;
u64 poly_koopman = l2_lookup_params->poly;
/* Convert polynomial from Koopman to 'normal' notation */
u8 poly = (u8)(1 + (poly_koopman << 1));
u64 vlanid = l2_lookup_params->shared_learn ? 0 : vid;
u64 input = (vlanid << 48) | ether_addr_to_u64(addr);
u8 crc = 0; /* seed */
int i;
/* Mask the eight bytes starting from MSB one at a time */
for (i = 56; i >= 0; i -= 8) {
u8 byte = (input & (0xffull << i)) >> i;
crc = sja1105_crc8_add(crc, byte, poly);
}
return crc;
}