// SPDX-License-Identifier: GPL-2.0-only
#include <asm/mach-rtl838x/mach-rtl83xx.h>
+#include <linux/inetdevice.h>
+
#include "rtl83xx.h"
extern struct mutex smi_lock;
e->valid = true;
// the UC_VID field in hardware is used for the VID or for the route id
if (e->next_hop) {
- e->nh_route_id = r[2] & 0xfff;
+ e->nh_route_id = r[2] & 0x7ff;
e->vid = 0;
} else {
e->vid = r[2] & 0xfff;
r[2] |= (e->age & 0x3) << 17;
// the UC_VID field in hardware is used for the VID or for the route id
if (e->next_hop)
- r[2] |= e->nh_route_id & 0xfff;
+ r[2] |= e->nh_route_id & 0x7ff;
else
r[2] |= e->vid & 0xfff;
} else { // L2_MULTICAST
u32 idx = (0 << 14) | (hash << 2) | pos; // Access SRAM, with hash and at pos in bucket
int i;
- pr_info("%s: hash %d, pos %d\n", __func__, hash, pos);
- pr_info("%s: index %d -> mac %02x:%02x:%02x:%02x:%02x:%02x\n", __func__, idx,
+ pr_debug("%s: hash %d, pos %d\n", __func__, hash, pos);
+ pr_debug("%s: index %d -> mac %02x:%02x:%02x:%02x:%02x:%02x\n", __func__, idx,
e->mac[0], e->mac[1], e->mac[2], e->mac[3],e->mac[4],e->mac[5]);
rtl930x_fill_l2_row(r, e);
e->stack_dev, e->nh_route_id, e->port);
}
-/*
- * Add an L2 nexthop entry for the L3 routing system in the SoC
- * Use VID and MAC in rtl838x_l2_entry to identify either a free slot in the L2 hash table
- * or mark an existing entry as a nexthop by setting it's nexthop bit
- * Called from the L3 layer
- * The index in the L2 hash table is filled into nh->l2_id;
- */
-static int rtl930x_l2_nexthop_add(struct rtl838x_switch_priv *priv, struct rtl838x_nexthop *nh)
-{
- struct rtl838x_l2_entry e;
- u64 seed = rtl930x_l2_hash_seed(nh->mac, nh->vid);
- u32 key = rtl930x_l2_hash_key(priv, seed);
- int i, idx = -1;
- u64 entry;
-
- pr_info("%s searching for %08llx vid %d with key %d, seed: %016llx\n",
- __func__, nh->mac, nh->vid, key, seed);
-
- e.type = L2_UNICAST;
- e.rvid = nh->fid; // Verify its the forwarding ID!!! l2_entry.un.unicast.fid
- u64_to_ether_addr(nh->mac, &e.mac[0]);
- e.port = RTL930X_PORT_IGNORE;
-
- // Loop over all entries in the hash-bucket and over the second block on 93xx SoCs
- for (i = 0; i < priv->l2_bucket_size; i++) {
- entry = rtl930x_read_l2_entry_using_hash(key, i, &e);
- pr_info("%s i: %d, entry %016llx, seed %016llx\n", __func__, i, entry, seed);
- if (e.valid && e.next_hop)
- continue;
- if (!e.valid || ((entry & 0x0fffffffffffffffULL) == seed)) {
- idx = i > 3 ? ((key >> 14) & 0xffff) | i >> 1
- : ((key << 2) | i) & 0xffff;
- break;
- }
- }
-
- pr_info("%s: found idx %d and i %d\n", __func__, idx, i);
-
- if (idx < 0) {
- pr_err("%s: No more L2 forwarding entries available\n", __func__);
- return -1;
- }
-
- // Found an existing or empty entry, make it a nexthop entry
- pr_info("%s BEFORE -> key %d, pos: %d, index: %d\n", __func__, key, i, idx);
- dump_l2_entry(&e);
- nh->l2_id = idx;
-
- // Found an existing (e->valid is true) or empty entry, make it a nexthop entry
- if (e.valid) {
- nh->port = e.port;
- nh->fid = e.rvid;
- nh->vid = e.vid;
- nh->dev_id = e.stack_dev;
- } else {
- e.valid = true;
- e.is_static = false;
- e.vid = nh->vid;
- e.rvid = nh->fid;
- e.port = RTL930X_PORT_IGNORE;
- u64_to_ether_addr(nh->mac, &e.mac[0]);
- }
- e.next_hop = true;
- // For nexthop entries, the vid field in the table is used to denote the dest mac_id
- e.nh_route_id = nh->mac_id;
- pr_info("%s AFTER\n", __func__);
- dump_l2_entry(&e);
-
- rtl930x_write_l2_entry_using_hash(idx >> 2, idx & 0x3, &e);
-
- // _dal_longan_l2_nexthop_add
- return 0;
-}
-
static u64 rtl930x_read_mcast_pmask(int idx)
{
u32 portmask;
/* Clear status */
sw_w32(ports, RTL930X_ISR_PORT_LINK_STS_CHG);
- pr_info("RTL9300 Link change: status: %x, ports %x\n", status, ports);
-
- rtl9300_dump_debug();
for (i = 0; i < 28; i++) {
if (ports & BIT(i)) {
return IRQ_HANDLED;
}
-int rtl9300_sds_power(int mac, int val)
-{
- int sds_num;
- u32 mode;
-
- // TODO: these numbers are hard-coded for the Zyxel XGS1210 12 Switch
- pr_info("SerDes: %s %d\n", __func__, mac);
- switch (mac) {
- case 24:
- sds_num = 6;
- mode = 0x12; // HISGMII
- break;
- case 25:
- sds_num = 7;
- mode = 0x12; // HISGMII
- break;
- case 26:
- sds_num = 8;
- mode = 0x1b; // 10GR/1000BX auto
- break;
- case 27:
- sds_num = 9;
- mode = 0x1b; // 10GR/1000BX auto
- break;
- default:
- return -1;
- }
- if (!val)
- mode = 0x1f; // OFF
-
- rtl9300_sds_rst(sds_num, mode);
-
- return 0;
-}
-
int rtl930x_write_phy(u32 port, u32 page, u32 reg, u32 val)
{
u32 v;
priv->eee_enabled = enable;
}
+#define HASH_PICK(val, lsb, len) ((val & (((1 << len) - 1) << lsb)) >> lsb)
+
+static u32 rtl930x_l3_hash4(u32 ip, int algorithm, bool move_dip)
+{
+ u32 rows[4];
+ u32 hash;
+ u32 s0, s1, pH;
+
+ memset(rows, 0, sizeof(rows));
+
+ rows[0] = HASH_PICK(ip, 27, 5);
+ rows[1] = HASH_PICK(ip, 18, 9);
+ rows[2] = HASH_PICK(ip, 9, 9);
+
+ if (!move_dip)
+ rows[3] = HASH_PICK(ip, 0, 9);
+
+ if (!algorithm) {
+ hash = rows[0] ^ rows[1] ^ rows[2] ^ rows[3];
+ } else {
+ s0 = rows[0] + rows[1] + rows[2];
+ s1 = (s0 & 0x1ff) + ((s0 & (0x1ff << 9)) >> 9);
+ pH = (s1 & 0x1ff) + ((s1 & (0x1ff << 9)) >> 9);
+ hash = pH ^ rows[3];
+ }
+ return hash;
+}
+
+static u32 rtl930x_l3_hash6(struct in6_addr *ip6, int algorithm, bool move_dip)
+{
+ u32 rows[16];
+ u32 hash;
+ u32 s0, s1, pH;
+
+ rows[0] = (HASH_PICK(ip6->s6_addr[0], 6, 2) << 0);
+ rows[1] = (HASH_PICK(ip6->s6_addr[0], 0, 6) << 3) | HASH_PICK(ip6->s6_addr[1], 5, 3);
+ rows[2] = (HASH_PICK(ip6->s6_addr[1], 0, 5) << 4) | HASH_PICK(ip6->s6_addr[2], 4, 4);
+ rows[3] = (HASH_PICK(ip6->s6_addr[2], 0, 4) << 5) | HASH_PICK(ip6->s6_addr[3], 3, 5);
+ rows[4] = (HASH_PICK(ip6->s6_addr[3], 0, 3) << 6) | HASH_PICK(ip6->s6_addr[4], 2, 6);
+ rows[5] = (HASH_PICK(ip6->s6_addr[4], 0, 2) << 7) | HASH_PICK(ip6->s6_addr[5], 1, 7);
+ rows[6] = (HASH_PICK(ip6->s6_addr[5], 0, 1) << 8) | HASH_PICK(ip6->s6_addr[6], 0, 8);
+ rows[7] = (HASH_PICK(ip6->s6_addr[7], 0, 8) << 1) | HASH_PICK(ip6->s6_addr[8], 7, 1);
+ rows[8] = (HASH_PICK(ip6->s6_addr[8], 0, 7) << 2) | HASH_PICK(ip6->s6_addr[9], 6, 2);
+ rows[9] = (HASH_PICK(ip6->s6_addr[9], 0, 6) << 3) | HASH_PICK(ip6->s6_addr[10], 5, 3);
+ rows[10] = (HASH_PICK(ip6->s6_addr[10], 0, 5) << 4) | HASH_PICK(ip6->s6_addr[11], 4, 4);
+ if (!algorithm) {
+ rows[11] = (HASH_PICK(ip6->s6_addr[11], 0, 4) << 5)
+ | (HASH_PICK(ip6->s6_addr[12], 3, 5) << 0);
+ rows[12] = (HASH_PICK(ip6->s6_addr[12], 0, 3) << 6)
+ | (HASH_PICK(ip6->s6_addr[13], 2, 6) << 0);
+ rows[13] = (HASH_PICK(ip6->s6_addr[13], 0, 2) << 7)
+ | (HASH_PICK(ip6->s6_addr[14], 1, 7) << 0);
+ if (!move_dip) {
+ rows[14] = (HASH_PICK(ip6->s6_addr[14], 0, 1) << 8)
+ | (HASH_PICK(ip6->s6_addr[15], 0, 8) << 0);
+ }
+ hash = rows[0] ^ rows[1] ^ rows[2] ^ rows[3] ^ rows[4] ^ rows[5] ^ rows[6]
+ ^ rows[7] ^ rows[8] ^ rows[9] ^ rows[10] ^ rows[11] ^ rows[12]
+ ^ rows[13] ^ rows[14];
+ } else {
+ rows[11] = (HASH_PICK(ip6->s6_addr[11], 0, 4) << 5);
+ rows[12] = (HASH_PICK(ip6->s6_addr[12], 3, 5) << 0);
+ rows[13] = (HASH_PICK(ip6->s6_addr[12], 0, 3) << 6)
+ | HASH_PICK(ip6->s6_addr[13], 2, 6);
+ rows[14] = (HASH_PICK(ip6->s6_addr[13], 0, 2) << 7)
+ | HASH_PICK(ip6->s6_addr[14], 1, 7);
+ if (!move_dip) {
+ rows[15] = (HASH_PICK(ip6->s6_addr[14], 0, 1) << 8)
+ | (HASH_PICK(ip6->s6_addr[15], 0, 8) << 0);
+ }
+ s0 = rows[12] + rows[13] + rows[14];
+ s1 = (s0 & 0x1ff) + ((s0 & (0x1ff << 9)) >> 9);
+ pH = (s1 & 0x1ff) + ((s1 & (0x1ff << 9)) >> 9);
+ hash = rows[0] ^ rows[1] ^ rows[2] ^ rows[3] ^ rows[4] ^ rows[5] ^ rows[6]
+ ^ rows[7] ^ rows[8] ^ rows[9] ^ rows[10] ^ rows[11] ^ pH ^ rows[15];
+ }
+ return hash;
+}
+
+/*
+ * Read a prefix route entry from the L3_PREFIX_ROUTE_IPUC table
+ * We currently only support IPv4 and IPv6 unicast route
+ */
+static void rtl930x_route_read(int idx, struct rtl83xx_route *rt)
+{
+ u32 v, ip4_m;
+ bool host_route, default_route;
+ struct in6_addr ip6_m;
+
+ // Read L3_PREFIX_ROUTE_IPUC table (2) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 2);
+
+ rtl_table_read(r, idx);
+ // The table has a size of 11 registers
+ rt->attr.valid = !!(sw_r32(rtl_table_data(r, 0)) & BIT(31));
+ if (!rt->attr.valid)
+ goto out;
+
+ rt->attr.type = (sw_r32(rtl_table_data(r, 0)) >> 29) & 0x3;
+
+ v = sw_r32(rtl_table_data(r, 10));
+ host_route = !!(v & BIT(21));
+ default_route = !!(v & BIT(20));
+ rt->prefix_len = -1;
+ pr_info("%s: host route %d, default_route %d\n", __func__, host_route, default_route);
+
+ switch (rt->attr.type) {
+ case 0: // IPv4 Unicast route
+ rt->dst_ip = sw_r32(rtl_table_data(r, 4));
+ ip4_m = sw_r32(rtl_table_data(r, 9));
+ pr_info("%s: Read ip4 mask: %08x\n", __func__, ip4_m);
+ rt->prefix_len = host_route ? 32 : -1;
+ rt->prefix_len = (rt->prefix_len < 0 && default_route) ? 0 : -1;
+ if (rt->prefix_len < 0)
+ rt->prefix_len = inet_mask_len(ip4_m);
+ break;
+ case 2: // IPv6 Unicast route
+ ipv6_addr_set(&rt->dst_ip6,
+ sw_r32(rtl_table_data(r, 1)), sw_r32(rtl_table_data(r, 2)),
+ sw_r32(rtl_table_data(r, 3)), sw_r32(rtl_table_data(r, 4)));
+ ipv6_addr_set(&ip6_m,
+ sw_r32(rtl_table_data(r, 6)), sw_r32(rtl_table_data(r, 7)),
+ sw_r32(rtl_table_data(r, 8)), sw_r32(rtl_table_data(r, 9)));
+ rt->prefix_len = host_route ? 128 : 0;
+ rt->prefix_len = (rt->prefix_len < 0 && default_route) ? 0 : -1;
+ if (rt->prefix_len < 0)
+ rt->prefix_len = find_last_bit((unsigned long int *)&ip6_m.s6_addr32,
+ 128);
+ break;
+ case 1: // IPv4 Multicast route
+ case 3: // IPv6 Multicast route
+ pr_warn("%s: route type not supported\n", __func__);
+ goto out;
+ }
+
+ rt->attr.hit = !!(v & BIT(22));
+ rt->attr.action = (v >> 18) & 3;
+ rt->nh.id = (v >> 7) & 0x7ff;
+ rt->attr.ttl_dec = !!(v & BIT(6));
+ rt->attr.ttl_check = !!(v & BIT(5));
+ rt->attr.dst_null = !!(v & BIT(4));
+ rt->attr.qos_as = !!(v & BIT(3));
+ rt->attr.qos_prio = v & 0x7;
+ pr_info("%s: index %d is valid: %d\n", __func__, idx, rt->attr.valid);
+ pr_info("%s: next_hop: %d, hit: %d, action :%d, ttl_dec %d, ttl_check %d, dst_null %d\n",
+ __func__, rt->nh.id, rt->attr.hit, rt->attr.action,
+ rt->attr.ttl_dec, rt->attr.ttl_check, rt->attr.dst_null);
+ pr_info("%s: GW: %pI4, prefix_len: %d\n", __func__, &rt->dst_ip, rt->prefix_len);
+out:
+ rtl_table_release(r);
+}
+
+static void rtl930x_net6_mask(int prefix_len, struct in6_addr *ip6_m)
+{
+ int o, b;
+ // Define network mask
+ o = prefix_len >> 3;
+ b = prefix_len & 0x7;
+ memset(ip6_m->s6_addr, 0xff, o);
+ ip6_m->s6_addr[o] |= b ? 0xff00 >> b : 0x00;
+}
+
+/*
+ * Read a host route entry from the table using its index
+ * We currently only support IPv4 and IPv6 unicast route
+ */
+static void rtl930x_host_route_read(int idx, struct rtl83xx_route *rt)
+{
+ u32 v;
+ // Read L3_HOST_ROUTE_IPUC table (1) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 1);
+
+ idx = ((idx / 6) * 8) + (idx % 6);
+
+ pr_debug("In %s, physical index %d\n", __func__, idx);
+ rtl_table_read(r, idx);
+ // The table has a size of 5 (for UC, 11 for MC) registers
+ v = sw_r32(rtl_table_data(r, 0));
+ rt->attr.valid = !!(v & BIT(31));
+ if (!rt->attr.valid)
+ goto out;
+ rt->attr.type = (v >> 29) & 0x3;
+ switch (rt->attr.type) {
+ case 0: // IPv4 Unicast route
+ rt->dst_ip = sw_r32(rtl_table_data(r, 4));
+ break;
+ case 2: // IPv6 Unicast route
+ ipv6_addr_set(&rt->dst_ip6,
+ sw_r32(rtl_table_data(r, 3)), sw_r32(rtl_table_data(r, 2)),
+ sw_r32(rtl_table_data(r, 1)), sw_r32(rtl_table_data(r, 0)));
+ break;
+ case 1: // IPv4 Multicast route
+ case 3: // IPv6 Multicast route
+ pr_warn("%s: route type not supported\n", __func__);
+ goto out;
+ }
+
+ rt->attr.hit = !!(v & BIT(20));
+ rt->attr.dst_null = !!(v & BIT(19));
+ rt->attr.action = (v >> 17) & 3;
+ rt->nh.id = (v >> 6) & 0x7ff;
+ rt->attr.ttl_dec = !!(v & BIT(5));
+ rt->attr.ttl_check = !!(v & BIT(4));
+ rt->attr.qos_as = !!(v & BIT(3));
+ rt->attr.qos_prio = v & 0x7;
+ pr_debug("%s: index %d is valid: %d\n", __func__, idx, rt->attr.valid);
+ pr_debug("%s: next_hop: %d, hit: %d, action :%d, ttl_dec %d, ttl_check %d, dst_null %d\n",
+ __func__, rt->nh.id, rt->attr.hit, rt->attr.action, rt->attr.ttl_dec, rt->attr.ttl_check,
+ rt->attr.dst_null);
+ pr_debug("%s: Destination: %pI4\n", __func__, &rt->dst_ip);
+
+out:
+ rtl_table_release(r);
+}
+
+/*
+ * Write a host route entry from the table using its index
+ * We currently only support IPv4 and IPv6 unicast route
+ */
+static void rtl930x_host_route_write(int idx, struct rtl83xx_route *rt)
+{
+ u32 v;
+ // Access L3_HOST_ROUTE_IPUC table (1) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 1);
+ // The table has a size of 5 (for UC, 11 for MC) registers
+
+ idx = ((idx / 6) * 8) + (idx % 6);
+
+ pr_debug("%s: index %d is valid: %d\n", __func__, idx, rt->attr.valid);
+ pr_debug("%s: next_hop: %d, hit: %d, action :%d, ttl_dec %d, ttl_check %d, dst_null %d\n",
+ __func__, rt->nh.id, rt->attr.hit, rt->attr.action, rt->attr.ttl_dec, rt->attr.ttl_check,
+ rt->attr.dst_null);
+ pr_debug("%s: GW: %pI4, prefix_len: %d\n", __func__, &rt->dst_ip, rt->prefix_len);
+
+ v = BIT(31); // Entry is valid
+ v |= (rt->attr.type & 0x3) << 29;
+ v |= rt->attr.hit ? BIT(20) : 0;
+ v |= rt->attr.dst_null ? BIT(19) : 0;
+ v |= (rt->attr.action & 0x3) << 17;
+ v |= (rt->nh.id & 0x7ff) << 6;
+ v |= rt->attr.ttl_dec ? BIT(5) : 0;
+ v |= rt->attr.ttl_check ? BIT(4) : 0;
+ v |= rt->attr.qos_as ? BIT(3) : 0;
+ v |= rt->attr.qos_prio & 0x7;
+
+ sw_w32(v, rtl_table_data(r, 0));
+ switch (rt->attr.type) {
+ case 0: // IPv4 Unicast route
+ sw_w32(0, rtl_table_data(r, 1));
+ sw_w32(0, rtl_table_data(r, 2));
+ sw_w32(0, rtl_table_data(r, 3));
+ sw_w32(rt->dst_ip, rtl_table_data(r, 4));
+ break;
+ case 2: // IPv6 Unicast route
+ sw_w32(rt->dst_ip6.s6_addr32[0], rtl_table_data(r, 1));
+ sw_w32(rt->dst_ip6.s6_addr32[1], rtl_table_data(r, 2));
+ sw_w32(rt->dst_ip6.s6_addr32[2], rtl_table_data(r, 3));
+ sw_w32(rt->dst_ip6.s6_addr32[3], rtl_table_data(r, 4));
+ break;
+ case 1: // IPv4 Multicast route
+ case 3: // IPv6 Multicast route
+ pr_warn("%s: route type not supported\n", __func__);
+ goto out;
+ }
+
+ rtl_table_write(r, idx);
+
+out:
+ rtl_table_release(r);
+}
+
+/*
+ * Look up the index of a prefix route in the routing table CAM for unicast IPv4/6 routes
+ * using hardware offload.
+ */
+static int rtl930x_route_lookup_hw(struct rtl83xx_route *rt)
+{
+ u32 ip4_m, v;
+ struct in6_addr ip6_m;
+ int i;
+
+ if (rt->attr.type == 1 || rt->attr.type == 3) // Hardware only supports UC routes
+ return -1;
+
+ sw_w32_mask(0x3 << 19, rt->attr.type, RTL930X_L3_HW_LU_KEY_CTRL);
+ if (rt->attr.type) { // IPv6
+ rtl930x_net6_mask(rt->prefix_len, &ip6_m);
+ for (i = 0; i < 4; i++)
+ sw_w32(rt->dst_ip6.s6_addr32[0] & ip6_m.s6_addr32[0],
+ RTL930X_L3_HW_LU_KEY_IP_CTRL + (i << 2));
+ } else { // IPv4
+ ip4_m = inet_make_mask(rt->prefix_len);
+ sw_w32(0, RTL930X_L3_HW_LU_KEY_IP_CTRL);
+ sw_w32(0, RTL930X_L3_HW_LU_KEY_IP_CTRL + 4);
+ sw_w32(0, RTL930X_L3_HW_LU_KEY_IP_CTRL + 8);
+ v = rt->dst_ip & ip4_m;
+ pr_info("%s: searching for %pI4\n", __func__, &v);
+ sw_w32(v, RTL930X_L3_HW_LU_KEY_IP_CTRL + 12);
+ }
+
+ // Execute CAM lookup in SoC
+ sw_w32(BIT(15), RTL930X_L3_HW_LU_CTRL);
+
+ // Wait until execute bit clears and result is ready
+ do {
+ v = sw_r32(RTL930X_L3_HW_LU_CTRL);
+ } while (v & BIT(15));
+
+ pr_info("%s: found: %d, index: %d\n", __func__, !!(v & BIT(14)), v & 0x1ff);
+
+ // Test if search successful (BIT 14 set)
+ if (v & BIT(14))
+ return v & 0x1ff;
+
+ return -1;
+}
+
+static int rtl930x_find_l3_slot(struct rtl83xx_route *rt, bool must_exist)
+{
+ int t, s, slot_width, algorithm, addr, idx;
+ u32 hash;
+ struct rtl83xx_route route_entry;
+
+ // IPv6 entries take up 3 slots
+ slot_width = (rt->attr.type == 0) || (rt->attr.type == 2) ? 1 : 3;
+
+ for (t = 0; t < 2; t++) {
+ algorithm = (sw_r32(RTL930X_L3_HOST_TBL_CTRL) >> (2 + t)) & 0x1;
+ hash = rtl930x_l3_hash4(rt->dst_ip, algorithm, false);
+
+ pr_debug("%s: table %d, algorithm %d, hash %04x\n", __func__, t, algorithm, hash);
+
+ for (s = 0; s < 6; s += slot_width) {
+ addr = (t << 12) | ((hash & 0x1ff) << 3) | s;
+ pr_debug("%s physical address %d\n", __func__, addr);
+ idx = ((addr / 8) * 6) + (addr % 8);
+ pr_debug("%s logical address %d\n", __func__, idx);
+
+ rtl930x_host_route_read(idx, &route_entry);
+ pr_debug("%s route valid %d, route dest: %pI4, hit %d\n", __func__,
+ rt->attr.valid, &rt->dst_ip, rt->attr.hit);
+ if (!must_exist && rt->attr.valid)
+ return idx;
+ if (must_exist && route_entry.dst_ip == rt->dst_ip)
+ return idx;
+ }
+ }
+
+ return -1;
+}
+
+/*
+ * Write a prefix route into the routing table CAM at position idx
+ * Currently only IPv4 and IPv6 unicast routes are supported
+ */
+static void rtl930x_route_write(int idx, struct rtl83xx_route *rt)
+{
+ u32 v, ip4_m;
+ struct in6_addr ip6_m;
+ // Access L3_PREFIX_ROUTE_IPUC table (2) via register RTL9300_TBL_1
+ // The table has a size of 11 registers (20 for MC)
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 2);
+
+ pr_debug("%s: index %d is valid: %d\n", __func__, idx, rt->attr.valid);
+ pr_debug("%s: nexthop: %d, hit: %d, action :%d, ttl_dec %d, ttl_check %d, dst_null %d\n",
+ __func__, rt->nh.id, rt->attr.hit, rt->attr.action,
+ rt->attr.ttl_dec, rt->attr.ttl_check, rt->attr.dst_null);
+ pr_debug("%s: GW: %pI4, prefix_len: %d\n", __func__, &rt->dst_ip, rt->prefix_len);
+
+ v = rt->attr.valid ? BIT(31) : 0;
+ v |= (rt->attr.type & 0x3) << 29;
+ sw_w32(v, rtl_table_data(r, 0));
+
+ v = rt->attr.hit ? BIT(22) : 0;
+ v |= (rt->attr.action & 0x3) << 18;
+ v |= (rt->nh.id & 0x7ff) << 7;
+ v |= rt->attr.ttl_dec ? BIT(6) : 0;
+ v |= rt->attr.ttl_check ? BIT(5) : 0;
+ v |= rt->attr.dst_null ? BIT(6) : 0;
+ v |= rt->attr.qos_as ? BIT(6) : 0;
+ v |= rt->attr.qos_prio & 0x7;
+ v |= rt->prefix_len == 0 ? BIT(20) : 0; // set default route bit
+
+ // set bit mask for entry type always to 0x3
+ sw_w32(0x3 << 29, rtl_table_data(r, 5));
+
+ switch (rt->attr.type) {
+ case 0: // IPv4 Unicast route
+ sw_w32(0, rtl_table_data(r, 1));
+ sw_w32(0, rtl_table_data(r, 2));
+ sw_w32(0, rtl_table_data(r, 3));
+ sw_w32(rt->dst_ip, rtl_table_data(r, 4));
+
+ v |= rt->prefix_len == 32 ? BIT(21) : 0; // set host-route bit
+ ip4_m = inet_make_mask(rt->prefix_len);
+ sw_w32(0, rtl_table_data(r, 6));
+ sw_w32(0, rtl_table_data(r, 7));
+ sw_w32(0, rtl_table_data(r, 8));
+ sw_w32(ip4_m, rtl_table_data(r, 9));
+ break;
+ case 2: // IPv6 Unicast route
+ sw_w32(rt->dst_ip6.s6_addr32[0], rtl_table_data(r, 1));
+ sw_w32(rt->dst_ip6.s6_addr32[1], rtl_table_data(r, 2));
+ sw_w32(rt->dst_ip6.s6_addr32[2], rtl_table_data(r, 3));
+ sw_w32(rt->dst_ip6.s6_addr32[3], rtl_table_data(r, 4));
+
+ v |= rt->prefix_len == 128 ? BIT(21) : 0; // set host-route bit
+
+ rtl930x_net6_mask(rt->prefix_len, &ip6_m);
+
+ sw_w32(ip6_m.s6_addr32[0], rtl_table_data(r, 6));
+ sw_w32(ip6_m.s6_addr32[1], rtl_table_data(r, 7));
+ sw_w32(ip6_m.s6_addr32[2], rtl_table_data(r, 8));
+ sw_w32(ip6_m.s6_addr32[3], rtl_table_data(r, 9));
+ break;
+ case 1: // IPv4 Multicast route
+ case 3: // IPv6 Multicast route
+ pr_warn("%s: route type not supported\n", __func__);
+ rtl_table_release(r);
+ return;
+ }
+ sw_w32(v, rtl_table_data(r, 10));
+
+ pr_debug("%s: %08x %08x %08x %08x %08x %08x %08x %08x %08x %08x %08x\n", __func__,
+ sw_r32(rtl_table_data(r, 0)), sw_r32(rtl_table_data(r, 1)), sw_r32(rtl_table_data(r, 2)),
+ sw_r32(rtl_table_data(r, 3)), sw_r32(rtl_table_data(r, 4)), sw_r32(rtl_table_data(r, 5)),
+ sw_r32(rtl_table_data(r, 6)), sw_r32(rtl_table_data(r, 7)), sw_r32(rtl_table_data(r, 8)),
+ sw_r32(rtl_table_data(r, 9)), sw_r32(rtl_table_data(r, 10)));
+
+ rtl_table_write(r, idx);
+ rtl_table_release(r);
+}
+
+
+/*
+ * Get the destination MAC and L3 egress interface ID of a nexthop entry from
+ * the SoC's L3_NEXTHOP table
+ */
+static void rtl930x_get_l3_nexthop(int idx, u16 *dmac_id, u16 *interface)
+{
+ u32 v;
+ // Read L3_NEXTHOP table (3) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 3);
+
+ rtl_table_read(r, idx);
+ // The table has a size of 1 register
+ v = sw_r32(rtl_table_data(r, 0));
+ rtl_table_release(r);
+
+ *dmac_id = (v >> 7) & 0x7fff;
+ *interface = v & 0x7f;
+}
+
+static int rtl930x_l3_mtu_del(struct rtl838x_switch_priv *priv, int mtu)
+{
+ int i;
+
+ for (i = 0; i < MAX_INTF_MTUS; i++) {
+ if (mtu == priv->intf_mtus[i])
+ break;
+ }
+ if (i >= MAX_INTF_MTUS || !priv->intf_mtu_count[i]) {
+ pr_err("%s: No MTU slot found for MTU: %d\n", __func__, mtu);
+ return -EINVAL;
+ }
+
+ priv->intf_mtu_count[i]--;
+}
+
+static int rtl930x_l3_mtu_add(struct rtl838x_switch_priv *priv, int mtu)
+{
+ int i, free_mtu;
+ int mtu_id;
+
+ // Try to find an existing mtu-value or a free slot
+ free_mtu = MAX_INTF_MTUS;
+ for (i = 0; i < MAX_INTF_MTUS && priv->intf_mtus[i] != mtu; i++) {
+ if ((!priv->intf_mtu_count[i]) && (free_mtu == MAX_INTF_MTUS))
+ free_mtu = i;
+ }
+ i = (i < MAX_INTF_MTUS) ? i : free_mtu;
+ if (i < MAX_INTF_MTUS) {
+ mtu_id = i;
+ } else {
+ pr_err("%s: No free MTU slot available!\n", __func__);
+ return -EINVAL;
+ }
+
+ priv->intf_mtus[i] = mtu;
+ pr_info("Writing MTU %d to slot %d\n", priv->intf_mtus[i], i);
+ // Set MTU-value of the slot TODO: distinguish between IPv4/IPv6 routes / slots
+ sw_w32_mask(0xffff << ((i % 2) * 16), priv->intf_mtus[i] << ((i % 2) * 16),
+ RTL930X_L3_IP_MTU_CTRL(i));
+ sw_w32_mask(0xffff << ((i % 2) * 16), priv->intf_mtus[i] << ((i % 2) * 16),
+ RTL930X_L3_IP6_MTU_CTRL(i));
+
+ priv->intf_mtu_count[i]++;
+
+ return mtu_id;
+}
+
+/*
+ * Creates an interface for a route by setting up the HW tables in the SoC
+ */
+static int rtl930x_l3_intf_add(struct rtl838x_switch_priv *priv, struct rtl838x_l3_intf *intf)
+{
+ int i, intf_id, mtu_id;
+ // number of MTU-values < 16384
+
+ // Use the same IPv6 mtu as the ip4 mtu for this route if unset
+ intf->ip6_mtu = intf->ip6_mtu ? intf->ip6_mtu : intf->ip4_mtu;
+
+ mtu_id = rtl930x_l3_mtu_add(priv, intf->ip4_mtu);
+ pr_info("%s: added mtu %d with mtu-id %d\n", __func__, intf->ip4_mtu, mtu_id);
+ if (mtu_id < 0)
+ return -ENOSPC;
+ intf->ip4_mtu_id = mtu_id;
+ intf->ip6_mtu_id = mtu_id;
+
+ for (i = 0; i < MAX_INTERFACES; i++) {
+ if (!priv->interfaces[i])
+ break;
+ }
+ if (i >= MAX_INTERFACES) {
+ pr_err("%s: cannot find free interface entry\n", __func__);
+ return -EINVAL;
+ }
+ intf_id = i;
+ priv->interfaces[i] = kzalloc(sizeof(struct rtl838x_l3_intf), GFP_KERNEL);
+ if (!priv->interfaces[i]) {
+ pr_err("%s: no memory to allocate new interface\n", __func__);
+ return -ENOMEM;
+ }
+}
+
+/*
+ * Set the destination MAC and L3 egress interface ID for a nexthop entry in the SoC's
+ * L3_NEXTHOP table. The nexthop entry is identified by idx.
+ * dmac_id is the reference to the L2 entry in the L2 forwarding table, special values are
+ * 0x7ffe: TRAP2CPU
+ * 0x7ffd: TRAP2MASTERCPU
+ * 0x7fff: DMAC_ID_DROP
+ */
+static void rtl930x_set_l3_nexthop(int idx, u16 dmac_id, u16 interface)
+{
+ // Access L3_NEXTHOP table (3) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 3);
+
+ pr_info("%s: Writing to L3_NEXTHOP table, index %d, dmac_id %d, interface %d\n",
+ __func__, idx, dmac_id, interface);
+ sw_w32(((dmac_id & 0x7fff) << 7) | (interface & 0x7f), rtl_table_data(r, 0));
+
+ pr_info("%s: %08x\n", __func__, sw_r32(rtl_table_data(r,0)));
+ rtl_table_write(r, idx);
+ rtl_table_release(r);
+}
static void rtl930x_pie_lookup_enable(struct rtl838x_switch_priv *priv, int index)
{
}
+/*
+ * Sets up an egress interface for L3 actions
+ * Actions for ip4/6_icmp_redirect, ip4/6_pbr_icmp_redirect are:
+ * 0: FORWARD, 1: DROP, 2: TRAP2CPU, 3: COPY2CPU, 4: TRAP2MASTERCPU 5: COPY2MASTERCPU
+ * 6: HARDDROP
+ * idx is the index in the HW interface table: idx < 0x80
+ */
+static void rtl930x_set_l3_egress_intf(int idx, struct rtl838x_l3_intf *intf)
+{
+ u32 u, v;
+ // Read L3_EGR_INTF table (4) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 4);
+
+ // The table has 2 registers
+ u = (intf->vid & 0xfff) << 9;
+ u |= (intf->smac_idx & 0x3f) << 3;
+ u |= (intf->ip4_mtu_id & 0x7);
+
+ v = (intf->ip6_mtu_id & 0x7) << 28;
+ v |= (intf->ttl_scope & 0xff) << 20;
+ v |= (intf->hl_scope & 0xff) << 12;
+ v |= (intf->ip4_icmp_redirect & 0x7) << 9;
+ v |= (intf->ip6_icmp_redirect & 0x7)<< 6;
+ v |= (intf->ip4_pbr_icmp_redirect & 0x7) << 3;
+ v |= (intf->ip6_pbr_icmp_redirect & 0x7);
+
+ sw_w32(u, rtl_table_data(r, 0));
+ sw_w32(v, rtl_table_data(r, 1));
+
+ pr_info("%s writing to index %d: %08x %08x\n", __func__, idx, u, v);
+ rtl_table_write(r, idx & 0x7f);
+ rtl_table_release(r);
+}
+
+/*
+ * Reads a MAC entry for L3 termination as entry point for routing
+ * from the hardware table
+ * idx is the index into the L3_ROUTER_MAC table
+ */
+static void rtl930x_get_l3_router_mac(u32 idx, struct rtl93xx_rt_mac *m)
+{
+ u32 v, w;
+ // Read L3_ROUTER_MAC table (0) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 0);
+
+ rtl_table_read(r, idx);
+ // The table has a size of 7 registers, 64 entries
+ v = sw_r32(rtl_table_data(r, 0));
+ w = sw_r32(rtl_table_data(r, 3));
+ m->valid = !!(v & BIT(20));
+ if (!m->valid)
+ goto out;
+
+ m->p_type = !!(v & BIT(19));
+ m->p_id = (v >> 13) & 0x3f; // trunk id of port
+ m->vid = v & 0xfff;
+ m->vid_mask = w & 0xfff;
+ m->action = sw_r32(rtl_table_data(r, 6)) & 0x7;
+ m->mac_mask = ((((u64)sw_r32(rtl_table_data(r, 5))) << 32) & 0xffffffffffffULL)
+ | (sw_r32(rtl_table_data(r, 4)));
+ m->mac = ((((u64)sw_r32(rtl_table_data(r, 1))) << 32) & 0xffffffffffffULL)
+ | (sw_r32(rtl_table_data(r, 2)));
+ // Bits L3_INTF and BMSK_L3_INTF are 0
+
+out:
+ rtl_table_release(r);
+}
+
+/*
+ * Writes a MAC entry for L3 termination as entry point for routing
+ * into the hardware table
+ * idx is the index into the L3_ROUTER_MAC table
+ */
+static void rtl930x_set_l3_router_mac(u32 idx, struct rtl93xx_rt_mac *m)
+{
+ u32 v, w;
+ // Read L3_ROUTER_MAC table (0) via register RTL9300_TBL_1
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_1, 0);
+
+ // The table has a size of 7 registers, 64 entries
+ v = BIT(20); // mac entry valid, port type is 0: individual
+ v |= (m->p_id & 0x3f) << 13;
+ v |= (m->vid & 0xfff); // Set the interface_id to the vlan id
+
+ w = m->vid_mask;
+ w |= (m->p_id_mask & 0x3f) << 13;
+
+ sw_w32(v, rtl_table_data(r, 0));
+ sw_w32(w, rtl_table_data(r, 3));
+
+ // Set MAC address, L3_INTF (bit 12 in register 1) needs to be 0
+ sw_w32((u32)(m->mac), rtl_table_data(r, 2));
+ sw_w32(m->mac >> 32, rtl_table_data(r, 1));
+
+ // Set MAC address mask, BMSK_L3_INTF (bit 12 in register 5) needs to be 0
+ sw_w32((u32)(m->mac_mask >> 32), rtl_table_data(r, 4));
+ sw_w32((u32)m->mac_mask, rtl_table_data(r, 5));
+
+ sw_w32(m->action & 0x7, rtl_table_data(r, 6));
+
+ pr_debug("%s writing index %d: %08x %08x %08x %08x %08x %08x %08x\n", __func__, idx,
+ sw_r32(rtl_table_data(r, 0)), sw_r32(rtl_table_data(r, 1)), sw_r32(rtl_table_data(r, 2)),
+ sw_r32(rtl_table_data(r, 3)), sw_r32(rtl_table_data(r, 4)), sw_r32(rtl_table_data(r, 5)),
+ sw_r32(rtl_table_data(r, 6))
+ );
+ rtl_table_write(r, idx);
+ rtl_table_release(r);
+}
+
+/*
+ * Get the Destination-MAC of an L3 egress interface or the Source MAC for routed packets
+ * from the SoC's L3_EGR_INTF_MAC table
+ * Indexes 0-2047 are DMACs, 2048+ are SMACs
+ */
+static u64 rtl930x_get_l3_egress_mac(u32 idx)
+{
+ u64 mac;
+ // Read L3_EGR_INTF_MAC table (2) via register RTL9300_TBL_2
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_2, 2);
+
+ rtl_table_read(r, idx);
+ // The table has a size of 2 registers
+ mac = sw_r32(rtl_table_data(r, 0));
+ mac <<= 32;
+ mac |= sw_r32(rtl_table_data(r, 1));
+ rtl_table_release(r);
+
+ return mac;
+}
+/*
+ * Set the Destination-MAC of a route or the Source MAC of an L3 egress interface
+ * in the SoC's L3_EGR_INTF_MAC table
+ * Indexes 0-2047 are DMACs, 2048+ are SMACs
+ */
+static void rtl930x_set_l3_egress_mac(u32 idx, u64 mac)
+{
+ // Access L3_EGR_INTF_MAC table (2) via register RTL9300_TBL_2
+ struct table_reg *r = rtl_table_get(RTL9300_TBL_2, 2);
+
+ // The table has a size of 2 registers
+ sw_w32(mac >> 32, rtl_table_data(r, 0));
+ sw_w32(mac, rtl_table_data(r, 1));
+
+ pr_debug("%s: setting index %d to %016llx\n", __func__, idx, mac);
+ rtl_table_write(r, idx);
+ rtl_table_release(r);
+}
+
+/*
+ * Configure L3 routing settings of the device:
+ * - MTUs
+ * - Egress interface
+ * - The router's MAC address on which routed packets are expected
+ * - MAC addresses used as source macs of routed packets
+ */
+int rtl930x_l3_setup(struct rtl838x_switch_priv *priv)
+{
+ int i;
+
+ // Setup MTU with id 0 for default interface
+ for (i = 0; i < MAX_INTF_MTUS; i++)
+ priv->intf_mtu_count[i] = priv->intf_mtus[i] = 0;
+
+ priv->intf_mtu_count[0] = 0; // Needs to stay forever
+ priv->intf_mtus[0] = DEFAULT_MTU;
+ sw_w32_mask(0xffff, DEFAULT_MTU, RTL930X_L3_IP_MTU_CTRL(0));
+ sw_w32_mask(0xffff, DEFAULT_MTU, RTL930X_L3_IP6_MTU_CTRL(0));
+ priv->intf_mtus[1] = DEFAULT_MTU;
+ sw_w32_mask(0xffff0000, DEFAULT_MTU << 16, RTL930X_L3_IP_MTU_CTRL(0));
+ sw_w32_mask(0xffff0000, DEFAULT_MTU << 16, RTL930X_L3_IP6_MTU_CTRL(0));
+
+ sw_w32_mask(0xffff, DEFAULT_MTU, RTL930X_L3_IP_MTU_CTRL(1));
+ sw_w32_mask(0xffff, DEFAULT_MTU, RTL930X_L3_IP6_MTU_CTRL(1));
+ sw_w32_mask(0xffff0000, DEFAULT_MTU << 16, RTL930X_L3_IP_MTU_CTRL(1));
+ sw_w32_mask(0xffff0000, DEFAULT_MTU << 16, RTL930X_L3_IP6_MTU_CTRL(1));
+
+ // Clear all source port MACs
+ for (i = 0; i < MAX_SMACS; i++)
+ rtl930x_set_l3_egress_mac(L3_EGRESS_DMACS + i, 0ULL);
+
+ // Configure the default L3 hash algorithm
+ sw_w32_mask(BIT(2), 0, RTL930X_L3_HOST_TBL_CTRL); // Algorithm selection 0 = 0
+ sw_w32_mask(0, BIT(3), RTL930X_L3_HOST_TBL_CTRL); // Algorithm selection 1 = 1
+
+ pr_info("L3_IPUC_ROUTE_CTRL %08x, IPMC_ROUTE %08x, IP6UC_ROUTE %08x, IP6MC_ROUTE %08x\n",
+ sw_r32(RTL930X_L3_IPUC_ROUTE_CTRL), sw_r32(RTL930X_L3_IPMC_ROUTE_CTRL),
+ sw_r32(RTL930X_L3_IP6UC_ROUTE_CTRL), sw_r32(RTL930X_L3_IP6MC_ROUTE_CTRL));
+ sw_w32_mask(0, 1, RTL930X_L3_IPUC_ROUTE_CTRL);
+ sw_w32_mask(0, 1, RTL930X_L3_IP6UC_ROUTE_CTRL);
+ sw_w32_mask(0, 1, RTL930X_L3_IPMC_ROUTE_CTRL);
+ sw_w32_mask(0, 1, RTL930X_L3_IP6MC_ROUTE_CTRL);
+
+ sw_w32(0x00002001, RTL930X_L3_IPUC_ROUTE_CTRL);
+ sw_w32(0x00014581, RTL930X_L3_IP6UC_ROUTE_CTRL);
+ sw_w32(0x00000501, RTL930X_L3_IPMC_ROUTE_CTRL);
+ sw_w32(0x00012881, RTL930X_L3_IP6MC_ROUTE_CTRL);
+
+ pr_info("L3_IPUC_ROUTE_CTRL %08x, IPMC_ROUTE %08x, IP6UC_ROUTE %08x, IP6MC_ROUTE %08x\n",
+ sw_r32(RTL930X_L3_IPUC_ROUTE_CTRL), sw_r32(RTL930X_L3_IPMC_ROUTE_CTRL),
+ sw_r32(RTL930X_L3_IP6UC_ROUTE_CTRL), sw_r32(RTL930X_L3_IP6MC_ROUTE_CTRL));
+
+ // Trap non-ip traffic to the CPU-port (e.g. ARP so we stay reachable)
+ sw_w32_mask(0x3 << 8, 0x1 << 8, RTL930X_L3_IP_ROUTE_CTRL);
+ pr_info("L3_IP_ROUTE_CTRL %08x\n", sw_r32(RTL930X_L3_IP_ROUTE_CTRL));
+
+ // PORT_ISO_RESTRICT_ROUTE_CTRL ?
+
+ // Do not use prefix route 0 because of HW limitations
+ set_bit(0, priv->route_use_bm);
+
+ return 0;
+}
+
static u32 rtl930x_packet_cntr_read(int counter)
{
u32 v;
.read_cam = rtl930x_read_cam,
.write_cam = rtl930x_write_cam,
.vlan_port_egr_filter = RTL930X_VLAN_PORT_EGR_FLTR,
- .vlan_port_igr_filter = RTL930X_VLAN_PORT_IGR_FLTR(0),
+ .vlan_port_igr_filter = RTL930X_VLAN_PORT_IGR_FLTR,
.vlan_port_pb = RTL930X_VLAN_PORT_PB_VLAN,
.vlan_port_tag_sts_ctrl = RTL930X_VLAN_PORT_TAG_STS_CTRL,
.trk_mbr_ctr = rtl930x_trk_mbr_ctr,
.init_eee = rtl930x_init_eee,
.port_eee_set = rtl930x_port_eee_set,
.eee_port_ability = rtl930x_eee_port_ability,
+ .l2_hash_seed = rtl930x_l2_hash_seed,
+ .l2_hash_key = rtl930x_l2_hash_key,
.read_mcast_pmask = rtl930x_read_mcast_pmask,
.write_mcast_pmask = rtl930x_write_mcast_pmask,
.pie_init = rtl930x_pie_init,
.l2_learning_setup = rtl930x_l2_learning_setup,
.packet_cntr_read = rtl930x_packet_cntr_read,
.packet_cntr_clear = rtl930x_packet_cntr_clear,
+ .route_read = rtl930x_route_read,
+ .route_write = rtl930x_route_write,
+ .host_route_write = rtl930x_host_route_write,
+ .l3_setup = rtl930x_l3_setup,
+ .set_l3_nexthop = rtl930x_set_l3_nexthop,
+ .get_l3_nexthop = rtl930x_get_l3_nexthop,
+ .get_l3_egress_mac = rtl930x_get_l3_egress_mac,
+ .set_l3_egress_mac = rtl930x_set_l3_egress_mac,
+ .find_l3_slot = rtl930x_find_l3_slot,
+ .route_lookup_hw = rtl930x_route_lookup_hw,
+ .get_l3_router_mac = rtl930x_get_l3_router_mac,
+ .set_l3_router_mac = rtl930x_set_l3_router_mac,
+ .set_l3_egress_intf = rtl930x_set_l3_egress_intf,
};