blob: 93dc05c194d381b51336e95d552180a6997a5084 [file] [log] [blame]
/*
* Texas Instruments N-Port Ethernet Switch Address Lookup Engine
*
* Copyright (C) 2012 Texas Instruments
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation version 2.
*
* This program is distributed "as is" WITHOUT ANY WARRANTY of any
* kind, whether express or implied; without even the implied warranty
* of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/platform_device.h>
#include <linux/seq_file.h>
#include <linux/slab.h>
#include <linux/err.h>
#include <linux/io.h>
#include <linux/stat.h>
#include <linux/sysfs.h>
#include <linux/etherdevice.h>
#include "cpsw_ale.h"
#define BITMASK(bits) (BIT(bits) - 1)
#define ALE_VERSION_MAJOR(rev, mask) (((rev) >> 8) & (mask))
#define ALE_VERSION_MINOR(rev) (rev & 0xff)
#define ALE_VERSION_1R3 0x0103
#define ALE_VERSION_1R4 0x0104
/* ALE Registers */
#define ALE_IDVER 0x00
#define ALE_STATUS 0x04
#define ALE_CONTROL 0x08
#define ALE_PRESCALE 0x10
#define ALE_UNKNOWNVLAN 0x18
#define ALE_TABLE_CONTROL 0x20
#define ALE_TABLE 0x34
#define ALE_PORTCTL 0x40
/* ALE NetCP NU switch specific Registers */
#define ALE_UNKNOWNVLAN_MEMBER 0x90
#define ALE_UNKNOWNVLAN_UNREG_MCAST_FLOOD 0x94
#define ALE_UNKNOWNVLAN_REG_MCAST_FLOOD 0x98
#define ALE_UNKNOWNVLAN_FORCE_UNTAG_EGRESS 0x9C
#define ALE_VLAN_MASK_MUX(reg) (0xc0 + (0x4 * (reg)))
#define ALE_TABLE_WRITE BIT(31)
#define ALE_TYPE_FREE 0
#define ALE_TYPE_ADDR 1
#define ALE_TYPE_VLAN 2
#define ALE_TYPE_VLAN_ADDR 3
#define ALE_UCAST_PERSISTANT 0
#define ALE_UCAST_UNTOUCHED 1
#define ALE_UCAST_OUI 2
#define ALE_UCAST_TOUCHED 3
#define ALE_TABLE_SIZE_MULTIPLIER 1024
#define ALE_STATUS_SIZE_MASK 0x1f
#define ALE_TABLE_SIZE_DEFAULT 64
static inline int cpsw_ale_get_field(u32 *ale_entry, u32 start, u32 bits)
{
int idx;
idx = start / 32;
start -= idx * 32;
idx = 2 - idx; /* flip */
return (ale_entry[idx] >> start) & BITMASK(bits);
}
static inline void cpsw_ale_set_field(u32 *ale_entry, u32 start, u32 bits,
u32 value)
{
int idx;
value &= BITMASK(bits);
idx = start / 32;
start -= idx * 32;
idx = 2 - idx; /* flip */
ale_entry[idx] &= ~(BITMASK(bits) << start);
ale_entry[idx] |= (value << start);
}
#define DEFINE_ALE_FIELD(name, start, bits) \
static inline int cpsw_ale_get_##name(u32 *ale_entry) \
{ \
return cpsw_ale_get_field(ale_entry, start, bits); \
} \
static inline void cpsw_ale_set_##name(u32 *ale_entry, u32 value) \
{ \
cpsw_ale_set_field(ale_entry, start, bits, value); \
}
#define DEFINE_ALE_FIELD1(name, start) \
static inline int cpsw_ale_get_##name(u32 *ale_entry, u32 bits) \
{ \
return cpsw_ale_get_field(ale_entry, start, bits); \
} \
static inline void cpsw_ale_set_##name(u32 *ale_entry, u32 value, \
u32 bits) \
{ \
cpsw_ale_set_field(ale_entry, start, bits, value); \
}
DEFINE_ALE_FIELD(entry_type, 60, 2)
DEFINE_ALE_FIELD(vlan_id, 48, 12)
DEFINE_ALE_FIELD(mcast_state, 62, 2)
DEFINE_ALE_FIELD1(port_mask, 66)
DEFINE_ALE_FIELD(super, 65, 1)
DEFINE_ALE_FIELD(ucast_type, 62, 2)
DEFINE_ALE_FIELD1(port_num, 66)
DEFINE_ALE_FIELD(blocked, 65, 1)
DEFINE_ALE_FIELD(secure, 64, 1)
DEFINE_ALE_FIELD1(vlan_untag_force, 24)
DEFINE_ALE_FIELD1(vlan_reg_mcast, 16)
DEFINE_ALE_FIELD1(vlan_unreg_mcast, 8)
DEFINE_ALE_FIELD1(vlan_member_list, 0)
DEFINE_ALE_FIELD(mcast, 40, 1)
/* ALE NetCP nu switch specific */
DEFINE_ALE_FIELD(vlan_unreg_mcast_idx, 20, 3)
DEFINE_ALE_FIELD(vlan_reg_mcast_idx, 44, 3)
/* The MAC address field in the ALE entry cannot be macroized as above */
static inline void cpsw_ale_get_addr(u32 *ale_entry, u8 *addr)
{
int i;
for (i = 0; i < 6; i++)
addr[i] = cpsw_ale_get_field(ale_entry, 40 - 8*i, 8);
}
static inline void cpsw_ale_set_addr(u32 *ale_entry, u8 *addr)
{
int i;
for (i = 0; i < 6; i++)
cpsw_ale_set_field(ale_entry, 40 - 8*i, 8, addr[i]);
}
static int cpsw_ale_read(struct cpsw_ale *ale, int idx, u32 *ale_entry)
{
int i;
WARN_ON(idx > ale->params.ale_entries);
writel_relaxed(idx, ale->params.ale_regs + ALE_TABLE_CONTROL);
for (i = 0; i < ALE_ENTRY_WORDS; i++)
ale_entry[i] = readl_relaxed(ale->params.ale_regs +
ALE_TABLE + 4 * i);
return idx;
}
static int cpsw_ale_write(struct cpsw_ale *ale, int idx, u32 *ale_entry)
{
int i;
WARN_ON(idx > ale->params.ale_entries);
for (i = 0; i < ALE_ENTRY_WORDS; i++)
writel_relaxed(ale_entry[i], ale->params.ale_regs +
ALE_TABLE + 4 * i);
writel_relaxed(idx | ALE_TABLE_WRITE, ale->params.ale_regs +
ALE_TABLE_CONTROL);
return idx;
}
static int cpsw_ale_match_addr(struct cpsw_ale *ale, u8 *addr, u16 vid)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int type, idx;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
u8 entry_addr[6];
cpsw_ale_read(ale, idx, ale_entry);
type = cpsw_ale_get_entry_type(ale_entry);
if (type != ALE_TYPE_ADDR && type != ALE_TYPE_VLAN_ADDR)
continue;
if (cpsw_ale_get_vlan_id(ale_entry) != vid)
continue;
cpsw_ale_get_addr(ale_entry, entry_addr);
if (ether_addr_equal(entry_addr, addr))
return idx;
}
return -ENOENT;
}
static int cpsw_ale_match_vlan(struct cpsw_ale *ale, u16 vid)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int type, idx;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
cpsw_ale_read(ale, idx, ale_entry);
type = cpsw_ale_get_entry_type(ale_entry);
if (type != ALE_TYPE_VLAN)
continue;
if (cpsw_ale_get_vlan_id(ale_entry) == vid)
return idx;
}
return -ENOENT;
}
static int cpsw_ale_match_free(struct cpsw_ale *ale)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int type, idx;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
cpsw_ale_read(ale, idx, ale_entry);
type = cpsw_ale_get_entry_type(ale_entry);
if (type == ALE_TYPE_FREE)
return idx;
}
return -ENOENT;
}
static int cpsw_ale_find_ageable(struct cpsw_ale *ale)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int type, idx;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
cpsw_ale_read(ale, idx, ale_entry);
type = cpsw_ale_get_entry_type(ale_entry);
if (type != ALE_TYPE_ADDR && type != ALE_TYPE_VLAN_ADDR)
continue;
if (cpsw_ale_get_mcast(ale_entry))
continue;
type = cpsw_ale_get_ucast_type(ale_entry);
if (type != ALE_UCAST_PERSISTANT &&
type != ALE_UCAST_OUI)
return idx;
}
return -ENOENT;
}
static void cpsw_ale_flush_mcast(struct cpsw_ale *ale, u32 *ale_entry,
int port_mask)
{
int mask;
mask = cpsw_ale_get_port_mask(ale_entry,
ale->port_mask_bits);
if ((mask & port_mask) == 0)
return; /* ports dont intersect, not interested */
mask &= ~port_mask;
/* free if only remaining port is host port */
if (mask)
cpsw_ale_set_port_mask(ale_entry, mask,
ale->port_mask_bits);
else
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_FREE);
}
int cpsw_ale_flush_multicast(struct cpsw_ale *ale, int port_mask, int vid)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int ret, idx;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
cpsw_ale_read(ale, idx, ale_entry);
ret = cpsw_ale_get_entry_type(ale_entry);
if (ret != ALE_TYPE_ADDR && ret != ALE_TYPE_VLAN_ADDR)
continue;
/* if vid passed is -1 then remove all multicast entry from
* the table irrespective of vlan id, if a valid vlan id is
* passed then remove only multicast added to that vlan id.
* if vlan id doesn't match then move on to next entry.
*/
if (vid != -1 && cpsw_ale_get_vlan_id(ale_entry) != vid)
continue;
if (cpsw_ale_get_mcast(ale_entry)) {
u8 addr[6];
cpsw_ale_get_addr(ale_entry, addr);
if (!is_broadcast_ether_addr(addr))
cpsw_ale_flush_mcast(ale, ale_entry, port_mask);
}
cpsw_ale_write(ale, idx, ale_entry);
}
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_flush_multicast);
static inline void cpsw_ale_set_vlan_entry_type(u32 *ale_entry,
int flags, u16 vid)
{
if (flags & ALE_VLAN) {
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_VLAN_ADDR);
cpsw_ale_set_vlan_id(ale_entry, vid);
} else {
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_ADDR);
}
}
int cpsw_ale_add_ucast(struct cpsw_ale *ale, u8 *addr, int port,
int flags, u16 vid)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx;
cpsw_ale_set_vlan_entry_type(ale_entry, flags, vid);
cpsw_ale_set_addr(ale_entry, addr);
cpsw_ale_set_ucast_type(ale_entry, ALE_UCAST_PERSISTANT);
cpsw_ale_set_secure(ale_entry, (flags & ALE_SECURE) ? 1 : 0);
cpsw_ale_set_blocked(ale_entry, (flags & ALE_BLOCKED) ? 1 : 0);
cpsw_ale_set_port_num(ale_entry, port, ale->port_num_bits);
idx = cpsw_ale_match_addr(ale, addr, (flags & ALE_VLAN) ? vid : 0);
if (idx < 0)
idx = cpsw_ale_match_free(ale);
if (idx < 0)
idx = cpsw_ale_find_ageable(ale);
if (idx < 0)
return -ENOMEM;
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_add_ucast);
int cpsw_ale_del_ucast(struct cpsw_ale *ale, u8 *addr, int port,
int flags, u16 vid)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx;
idx = cpsw_ale_match_addr(ale, addr, (flags & ALE_VLAN) ? vid : 0);
if (idx < 0)
return -ENOENT;
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_FREE);
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_del_ucast);
int cpsw_ale_add_mcast(struct cpsw_ale *ale, u8 *addr, int port_mask,
int flags, u16 vid, int mcast_state)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx, mask;
idx = cpsw_ale_match_addr(ale, addr, (flags & ALE_VLAN) ? vid : 0);
if (idx >= 0)
cpsw_ale_read(ale, idx, ale_entry);
cpsw_ale_set_vlan_entry_type(ale_entry, flags, vid);
cpsw_ale_set_addr(ale_entry, addr);
cpsw_ale_set_super(ale_entry, (flags & ALE_BLOCKED) ? 1 : 0);
cpsw_ale_set_mcast_state(ale_entry, mcast_state);
mask = cpsw_ale_get_port_mask(ale_entry,
ale->port_mask_bits);
port_mask |= mask;
cpsw_ale_set_port_mask(ale_entry, port_mask,
ale->port_mask_bits);
if (idx < 0)
idx = cpsw_ale_match_free(ale);
if (idx < 0)
idx = cpsw_ale_find_ageable(ale);
if (idx < 0)
return -ENOMEM;
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_add_mcast);
int cpsw_ale_del_mcast(struct cpsw_ale *ale, u8 *addr, int port_mask,
int flags, u16 vid)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx;
idx = cpsw_ale_match_addr(ale, addr, (flags & ALE_VLAN) ? vid : 0);
if (idx < 0)
return -EINVAL;
cpsw_ale_read(ale, idx, ale_entry);
if (port_mask)
cpsw_ale_set_port_mask(ale_entry, port_mask,
ale->port_mask_bits);
else
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_FREE);
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_del_mcast);
/* ALE NetCP NU switch specific vlan functions */
static void cpsw_ale_set_vlan_mcast(struct cpsw_ale *ale, u32 *ale_entry,
int reg_mcast, int unreg_mcast)
{
int idx;
/* Set VLAN registered multicast flood mask */
idx = cpsw_ale_get_vlan_reg_mcast_idx(ale_entry);
writel(reg_mcast, ale->params.ale_regs + ALE_VLAN_MASK_MUX(idx));
/* Set VLAN unregistered multicast flood mask */
idx = cpsw_ale_get_vlan_unreg_mcast_idx(ale_entry);
writel(unreg_mcast, ale->params.ale_regs + ALE_VLAN_MASK_MUX(idx));
}
int cpsw_ale_add_vlan(struct cpsw_ale *ale, u16 vid, int port, int untag,
int reg_mcast, int unreg_mcast)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx;
idx = cpsw_ale_match_vlan(ale, vid);
if (idx >= 0)
cpsw_ale_read(ale, idx, ale_entry);
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_VLAN);
cpsw_ale_set_vlan_id(ale_entry, vid);
cpsw_ale_set_vlan_untag_force(ale_entry, untag, ale->vlan_field_bits);
if (!ale->params.nu_switch_ale) {
cpsw_ale_set_vlan_reg_mcast(ale_entry, reg_mcast,
ale->vlan_field_bits);
cpsw_ale_set_vlan_unreg_mcast(ale_entry, unreg_mcast,
ale->vlan_field_bits);
} else {
cpsw_ale_set_vlan_mcast(ale, ale_entry, reg_mcast, unreg_mcast);
}
cpsw_ale_set_vlan_member_list(ale_entry, port, ale->vlan_field_bits);
if (idx < 0)
idx = cpsw_ale_match_free(ale);
if (idx < 0)
idx = cpsw_ale_find_ageable(ale);
if (idx < 0)
return -ENOMEM;
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_add_vlan);
int cpsw_ale_del_vlan(struct cpsw_ale *ale, u16 vid, int port_mask)
{
u32 ale_entry[ALE_ENTRY_WORDS] = {0, 0, 0};
int idx;
idx = cpsw_ale_match_vlan(ale, vid);
if (idx < 0)
return -ENOENT;
cpsw_ale_read(ale, idx, ale_entry);
if (port_mask)
cpsw_ale_set_vlan_member_list(ale_entry, port_mask,
ale->vlan_field_bits);
else
cpsw_ale_set_entry_type(ale_entry, ALE_TYPE_FREE);
cpsw_ale_write(ale, idx, ale_entry);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_del_vlan);
void cpsw_ale_set_allmulti(struct cpsw_ale *ale, int allmulti)
{
u32 ale_entry[ALE_ENTRY_WORDS];
int type, idx;
int unreg_mcast = 0;
/* Only bother doing the work if the setting is actually changing */
if (ale->allmulti == allmulti)
return;
/* Remember the new setting to check against next time */
ale->allmulti = allmulti;
for (idx = 0; idx < ale->params.ale_entries; idx++) {
cpsw_ale_read(ale, idx, ale_entry);
type = cpsw_ale_get_entry_type(ale_entry);
if (type != ALE_TYPE_VLAN)
continue;
unreg_mcast =
cpsw_ale_get_vlan_unreg_mcast(ale_entry,
ale->vlan_field_bits);
if (allmulti)
unreg_mcast |= 1;
else
unreg_mcast &= ~1;
cpsw_ale_set_vlan_unreg_mcast(ale_entry, unreg_mcast,
ale->vlan_field_bits);
cpsw_ale_write(ale, idx, ale_entry);
}
}
EXPORT_SYMBOL_GPL(cpsw_ale_set_allmulti);
struct ale_control_info {
const char *name;
int offset, port_offset;
int shift, port_shift;
int bits;
};
static struct ale_control_info ale_controls[ALE_NUM_CONTROLS] = {
[ALE_ENABLE] = {
.name = "enable",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 31,
.port_shift = 0,
.bits = 1,
},
[ALE_CLEAR] = {
.name = "clear",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 30,
.port_shift = 0,
.bits = 1,
},
[ALE_AGEOUT] = {
.name = "ageout",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 29,
.port_shift = 0,
.bits = 1,
},
[ALE_P0_UNI_FLOOD] = {
.name = "port0_unicast_flood",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 8,
.port_shift = 0,
.bits = 1,
},
[ALE_VLAN_NOLEARN] = {
.name = "vlan_nolearn",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 7,
.port_shift = 0,
.bits = 1,
},
[ALE_NO_PORT_VLAN] = {
.name = "no_port_vlan",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 6,
.port_shift = 0,
.bits = 1,
},
[ALE_OUI_DENY] = {
.name = "oui_deny",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 5,
.port_shift = 0,
.bits = 1,
},
[ALE_BYPASS] = {
.name = "bypass",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 4,
.port_shift = 0,
.bits = 1,
},
[ALE_RATE_LIMIT_TX] = {
.name = "rate_limit_tx",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 3,
.port_shift = 0,
.bits = 1,
},
[ALE_VLAN_AWARE] = {
.name = "vlan_aware",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 2,
.port_shift = 0,
.bits = 1,
},
[ALE_AUTH_ENABLE] = {
.name = "auth_enable",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 1,
.port_shift = 0,
.bits = 1,
},
[ALE_RATE_LIMIT] = {
.name = "rate_limit",
.offset = ALE_CONTROL,
.port_offset = 0,
.shift = 0,
.port_shift = 0,
.bits = 1,
},
[ALE_PORT_STATE] = {
.name = "port_state",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 0,
.port_shift = 0,
.bits = 2,
},
[ALE_PORT_DROP_UNTAGGED] = {
.name = "drop_untagged",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 2,
.port_shift = 0,
.bits = 1,
},
[ALE_PORT_DROP_UNKNOWN_VLAN] = {
.name = "drop_unknown",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 3,
.port_shift = 0,
.bits = 1,
},
[ALE_PORT_NOLEARN] = {
.name = "nolearn",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 4,
.port_shift = 0,
.bits = 1,
},
[ALE_PORT_NO_SA_UPDATE] = {
.name = "no_source_update",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 5,
.port_shift = 0,
.bits = 1,
},
[ALE_PORT_MCAST_LIMIT] = {
.name = "mcast_limit",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 16,
.port_shift = 0,
.bits = 8,
},
[ALE_PORT_BCAST_LIMIT] = {
.name = "bcast_limit",
.offset = ALE_PORTCTL,
.port_offset = 4,
.shift = 24,
.port_shift = 0,
.bits = 8,
},
[ALE_PORT_UNKNOWN_VLAN_MEMBER] = {
.name = "unknown_vlan_member",
.offset = ALE_UNKNOWNVLAN,
.port_offset = 0,
.shift = 0,
.port_shift = 0,
.bits = 6,
},
[ALE_PORT_UNKNOWN_MCAST_FLOOD] = {
.name = "unknown_mcast_flood",
.offset = ALE_UNKNOWNVLAN,
.port_offset = 0,
.shift = 8,
.port_shift = 0,
.bits = 6,
},
[ALE_PORT_UNKNOWN_REG_MCAST_FLOOD] = {
.name = "unknown_reg_flood",
.offset = ALE_UNKNOWNVLAN,
.port_offset = 0,
.shift = 16,
.port_shift = 0,
.bits = 6,
},
[ALE_PORT_UNTAGGED_EGRESS] = {
.name = "untagged_egress",
.offset = ALE_UNKNOWNVLAN,
.port_offset = 0,
.shift = 24,
.port_shift = 0,
.bits = 6,
},
};
int cpsw_ale_control_set(struct cpsw_ale *ale, int port, int control,
int value)
{
const struct ale_control_info *info;
int offset, shift;
u32 tmp, mask;
if (control < 0 || control >= ARRAY_SIZE(ale_controls))
return -EINVAL;
info = &ale_controls[control];
if (info->port_offset == 0 && info->port_shift == 0)
port = 0; /* global, port is a dont care */
if (port < 0 || port >= ale->params.ale_ports)
return -EINVAL;
mask = BITMASK(info->bits);
if (value & ~mask)
return -EINVAL;
offset = info->offset + (port * info->port_offset);
shift = info->shift + (port * info->port_shift);
tmp = readl_relaxed(ale->params.ale_regs + offset);
tmp = (tmp & ~(mask << shift)) | (value << shift);
writel_relaxed(tmp, ale->params.ale_regs + offset);
return 0;
}
EXPORT_SYMBOL_GPL(cpsw_ale_control_set);
int cpsw_ale_control_get(struct cpsw_ale *ale, int port, int control)
{
const struct ale_control_info *info;
int offset, shift;
u32 tmp;
if (control < 0 || control >= ARRAY_SIZE(ale_controls))
return -EINVAL;
info = &ale_controls[control];
if (info->port_offset == 0 && info->port_shift == 0)
port = 0; /* global, port is a dont care */
if (port < 0 || port >= ale->params.ale_ports)
return -EINVAL;
offset = info->offset + (port * info->port_offset);
shift = info->shift + (port * info->port_shift);
tmp = readl_relaxed(ale->params.ale_regs + offset) >> shift;
return tmp & BITMASK(info->bits);
}
EXPORT_SYMBOL_GPL(cpsw_ale_control_get);
static void cpsw_ale_timer(struct timer_list *t)
{
struct cpsw_ale *ale = from_timer(ale, t, timer);
cpsw_ale_control_set(ale, 0, ALE_AGEOUT, 1);
if (ale->ageout) {
ale->timer.expires = jiffies + ale->ageout;
add_timer(&ale->timer);
}
}
void cpsw_ale_start(struct cpsw_ale *ale)
{
cpsw_ale_control_set(ale, 0, ALE_ENABLE, 1);
cpsw_ale_control_set(ale, 0, ALE_CLEAR, 1);
timer_setup(&ale->timer, cpsw_ale_timer, 0);
if (ale->ageout) {
ale->timer.expires = jiffies + ale->ageout;
add_timer(&ale->timer);
}
}
EXPORT_SYMBOL_GPL(cpsw_ale_start);
void cpsw_ale_stop(struct cpsw_ale *ale)
{
del_timer_sync(&ale->timer);
cpsw_ale_control_set(ale, 0, ALE_ENABLE, 0);
}
EXPORT_SYMBOL_GPL(cpsw_ale_stop);
struct cpsw_ale *cpsw_ale_create(struct cpsw_ale_params *params)
{
struct cpsw_ale *ale;
u32 rev, ale_entries;
ale = devm_kzalloc(params->dev, sizeof(*ale), GFP_KERNEL);
if (!ale)
return NULL;
ale->params = *params;
ale->ageout = ale->params.ale_ageout * HZ;
rev = readl_relaxed(ale->params.ale_regs + ALE_IDVER);
if (!ale->params.major_ver_mask)
ale->params.major_ver_mask = 0xff;
ale->version =
(ALE_VERSION_MAJOR(rev, ale->params.major_ver_mask) << 8) |
ALE_VERSION_MINOR(rev);
dev_info(ale->params.dev, "initialized cpsw ale version %d.%d\n",
ALE_VERSION_MAJOR(rev, ale->params.major_ver_mask),
ALE_VERSION_MINOR(rev));
if (!ale->params.ale_entries) {
ale_entries =
readl_relaxed(ale->params.ale_regs + ALE_STATUS) &
ALE_STATUS_SIZE_MASK;
/* ALE available on newer NetCP switches has introduced
* a register, ALE_STATUS, to indicate the size of ALE
* table which shows the size as a multiple of 1024 entries.
* For these, params.ale_entries will be set to zero. So
* read the register and update the value of ale_entries.
* ALE table on NetCP lite, is much smaller and is indicated
* by a value of zero in ALE_STATUS. So use a default value
* of ALE_TABLE_SIZE_DEFAULT for this. Caller is expected
* to set the value of ale_entries for all other versions
* of ALE.
*/
if (!ale_entries)
ale_entries = ALE_TABLE_SIZE_DEFAULT;
else
ale_entries *= ALE_TABLE_SIZE_MULTIPLIER;
ale->params.ale_entries = ale_entries;
}
dev_info(ale->params.dev,
"ALE Table size %ld\n", ale->params.ale_entries);
/* set default bits for existing h/w */
ale->port_mask_bits = ale->params.ale_ports;
ale->port_num_bits = order_base_2(ale->params.ale_ports);
ale->vlan_field_bits = ale->params.ale_ports;
/* Set defaults override for ALE on NetCP NU switch and for version
* 1R3
*/
if (ale->params.nu_switch_ale) {
/* Separate registers for unknown vlan configuration.
* Also there are N bits, where N is number of ale
* ports and shift value should be 0
*/
ale_controls[ALE_PORT_UNKNOWN_VLAN_MEMBER].bits =
ale->params.ale_ports;
ale_controls[ALE_PORT_UNKNOWN_VLAN_MEMBER].offset =
ALE_UNKNOWNVLAN_MEMBER;
ale_controls[ALE_PORT_UNKNOWN_MCAST_FLOOD].bits =
ale->params.ale_ports;
ale_controls[ALE_PORT_UNKNOWN_MCAST_FLOOD].shift = 0;
ale_controls[ALE_PORT_UNKNOWN_MCAST_FLOOD].offset =
ALE_UNKNOWNVLAN_UNREG_MCAST_FLOOD;
ale_controls[ALE_PORT_UNKNOWN_REG_MCAST_FLOOD].bits =
ale->params.ale_ports;
ale_controls[ALE_PORT_UNKNOWN_REG_MCAST_FLOOD].shift = 0;
ale_controls[ALE_PORT_UNKNOWN_REG_MCAST_FLOOD].offset =
ALE_UNKNOWNVLAN_REG_MCAST_FLOOD;
ale_controls[ALE_PORT_UNTAGGED_EGRESS].bits =
ale->params.ale_ports;
ale_controls[ALE_PORT_UNTAGGED_EGRESS].shift = 0;
ale_controls[ALE_PORT_UNTAGGED_EGRESS].offset =
ALE_UNKNOWNVLAN_FORCE_UNTAG_EGRESS;
}
return ale;
}
EXPORT_SYMBOL_GPL(cpsw_ale_create);
void cpsw_ale_dump(struct cpsw_ale *ale, u32 *data)
{
int i;
for (i = 0; i < ale->params.ale_entries; i++) {
cpsw_ale_read(ale, i, data);
data += ALE_ENTRY_WORDS;
}
}
EXPORT_SYMBOL_GPL(cpsw_ale_dump);
MODULE_LICENSE("GPL v2");
MODULE_DESCRIPTION("TI CPSW ALE driver");
MODULE_AUTHOR("Texas Instruments");