diff options
Diffstat (limited to 'target/linux/realtek/files-5.10/drivers/net/dsa/rtl83xx/rtl930x.c')
-rw-r--r-- | target/linux/realtek/files-5.10/drivers/net/dsa/rtl83xx/rtl930x.c | 1039 |
1 files changed, 1039 insertions, 0 deletions
diff --git a/target/linux/realtek/files-5.10/drivers/net/dsa/rtl83xx/rtl930x.c b/target/linux/realtek/files-5.10/drivers/net/dsa/rtl83xx/rtl930x.c new file mode 100644 index 0000000000..f1de39f0bc --- /dev/null +++ b/target/linux/realtek/files-5.10/drivers/net/dsa/rtl83xx/rtl930x.c @@ -0,0 +1,1039 @@ +// SPDX-License-Identifier: GPL-2.0-only + +#include <asm/mach-rtl838x/mach-rtl83xx.h> +#include "rtl83xx.h" + +extern struct mutex smi_lock; +extern struct rtl83xx_soc_info soc_info; + +void rtl930x_print_matrix(void) +{ + int i; + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 6); + + for (i = 0; i < 29; i++) { + rtl_table_read(r, i); + pr_debug("> %08x\n", sw_r32(rtl_table_data(r, 0))); + } + rtl_table_release(r); +} + +inline void rtl930x_exec_tbl0_cmd(u32 cmd) +{ + sw_w32(cmd, RTL930X_TBL_ACCESS_CTRL_0); + do { } while (sw_r32(RTL930X_TBL_ACCESS_CTRL_0) & (1 << 17)); +} + +inline void rtl930x_exec_tbl1_cmd(u32 cmd) +{ + sw_w32(cmd, RTL930X_TBL_ACCESS_CTRL_1); + do { } while (sw_r32(RTL930X_TBL_ACCESS_CTRL_1) & (1 << 17)); +} + +inline int rtl930x_tbl_access_data_0(int i) +{ + return RTL930X_TBL_ACCESS_DATA_0(i); +} + +static inline int rtl930x_l2_port_new_salrn(int p) +{ + return RTL930X_L2_PORT_SALRN(p); +} + +static inline int rtl930x_l2_port_new_sa_fwd(int p) +{ + // TODO: The definition of the fields changed, because of the master-cpu in a stack + return RTL930X_L2_PORT_NEW_SA_FWD(p); +} + +inline static int rtl930x_trk_mbr_ctr(int group) +{ + return RTL930X_TRK_MBR_CTRL + (group << 2); +} + +static void rtl930x_vlan_tables_read(u32 vlan, struct rtl838x_vlan_info *info) +{ + u32 v, w; + // Read VLAN table (1) via register 0 + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 1); + + rtl_table_read(r, vlan); + v = sw_r32(rtl_table_data(r, 0)); + w = sw_r32(rtl_table_data(r, 1)); + pr_debug("VLAN_READ %d: %08x %08x\n", vlan, v, w); + rtl_table_release(r); + + info->tagged_ports = v >> 3; + info->profile_id = (w >> 24) & 7; + info->hash_mc_fid = !!(w & BIT(27)); + info->hash_uc_fid = !!(w & BIT(28)); + info->fid = ((v & 0x7) << 3) | ((w >> 29) & 0x7); + + // Read UNTAG table via table register 2 + r = rtl_table_get(RTL9300_TBL_2, 0); + rtl_table_read(r, vlan); + v = sw_r32(rtl_table_data(r, 0)); + rtl_table_release(r); + + info->untagged_ports = v >> 3; +} + +static void rtl930x_vlan_set_tagged(u32 vlan, struct rtl838x_vlan_info *info) +{ + u32 v, w; + // Access VLAN table (1) via register 0 + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 1); + + v = info->tagged_ports << 3; + v |= ((u32)info->fid) >> 3; + + w = ((u32)info->fid) << 29; + w |= info->hash_mc_fid ? BIT(27) : 0; + w |= info->hash_uc_fid ? BIT(28) : 0; + w |= info->profile_id << 24; + + sw_w32(v, rtl_table_data(r, 0)); + sw_w32(w, rtl_table_data(r, 1)); + + rtl_table_write(r, vlan); + rtl_table_release(r); +} + +void rtl930x_vlan_profile_dump(int profile) +{ + u32 p[5]; + + if (profile < 0 || profile > 7) + return; + + p[0] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile)); + p[1] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile) + 4); + p[2] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile) + 8) & 0x1FFFFFFF; + p[3] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile) + 12) & 0x1FFFFFFF; + p[4] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile) + 16) & 0x1FFFFFFF; + + pr_info("VLAN %d: L2 learn: %d; Unknown MC PMasks: L2 %0x, IPv4 %0x, IPv6: %0x", + profile, p[0] & (3 << 21), p[2], p[3], p[4]); + pr_info(" Routing enabled: IPv4 UC %c, IPv6 UC %c, IPv4 MC %c, IPv6 MC %c\n", + p[0] & BIT(17) ? 'y' : 'n', p[0] & BIT(16) ? 'y' : 'n', + p[0] & BIT(13) ? 'y' : 'n', p[0] & BIT(12) ? 'y' : 'n'); + pr_info(" Bridge enabled: IPv4 MC %c, IPv6 MC %c,\n", + p[0] & BIT(15) ? 'y' : 'n', p[0] & BIT(14) ? 'y' : 'n'); + pr_info("VLAN profile %d: raw %08x %08x %08x %08x %08x\n", + profile, p[0], p[1], p[2], p[3], p[4]); +} + +static void rtl930x_vlan_set_untagged(u32 vlan, u64 portmask) +{ + struct table_reg *r = rtl_table_get(RTL9300_TBL_2, 0); + + sw_w32(portmask << 3, rtl_table_data(r, 0)); + rtl_table_write(r, vlan); + rtl_table_release(r); +} + +/* Sets the L2 forwarding to be based on either the inner VLAN tag or the outer + */ +static void rtl930x_vlan_fwd_on_inner(int port, bool is_set) +{ + // Always set all tag modes to fwd based on either inner or outer tag + if (is_set) + sw_w32_mask(0, 0xf, RTL930X_VLAN_PORT_FWD + (port << 2)); + else + sw_w32_mask(0xf, 0, RTL930X_VLAN_PORT_FWD + (port << 2)); +} + +static void rtl930x_vlan_profile_setup(int profile) +{ + u32 p[5]; + + pr_info("In %s\n", __func__); + p[0] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile)); + p[1] = sw_r32(RTL930X_VLAN_PROFILE_SET(profile) + 4); + + // Enable routing of Ipv4/6 Unicast and IPv4/6 Multicast traffic + p[0] |= BIT(17) | BIT(16) | BIT(13) | BIT(12); + p[2] = 0x1fffffff; // L2 unknown MC flooding portmask all ports, including the CPU-port + p[3] = 0x1fffffff; // IPv4 unknown MC flooding portmask + p[4] = 0x1fffffff; // IPv6 unknown MC flooding portmask + + sw_w32(p[0], RTL930X_VLAN_PROFILE_SET(profile)); + sw_w32(p[1], RTL930X_VLAN_PROFILE_SET(profile) + 4); + sw_w32(p[2], RTL930X_VLAN_PROFILE_SET(profile) + 8); + sw_w32(p[3], RTL930X_VLAN_PROFILE_SET(profile) + 12); + sw_w32(p[4], RTL930X_VLAN_PROFILE_SET(profile) + 16); + pr_info("Leaving %s\n", __func__); +} + +static void rtl930x_stp_get(struct rtl838x_switch_priv *priv, u16 msti, u32 port_state[]) +{ + int i; + u32 cmd = 1 << 17 /* Execute cmd */ + | 0 << 16 /* Read */ + | 4 << 12 /* Table type 0b10 */ + | (msti & 0xfff); + priv->r->exec_tbl0_cmd(cmd); + + for (i = 0; i < 2; i++) + port_state[i] = sw_r32(RTL930X_TBL_ACCESS_DATA_0(i)); + pr_debug("MSTI: %d STATE: %08x, %08x\n", msti, port_state[0], port_state[1]); +} + +static void rtl930x_stp_set(struct rtl838x_switch_priv *priv, u16 msti, u32 port_state[]) +{ + int i; + u32 cmd = 1 << 17 /* Execute cmd */ + | 1 << 16 /* Write */ + | 4 << 12 /* Table type 4 */ + | (msti & 0xfff); + + for (i = 0; i < 2; i++) + sw_w32(port_state[i], RTL930X_TBL_ACCESS_DATA_0(i)); + priv->r->exec_tbl0_cmd(cmd); +} + +static inline int rtl930x_mac_force_mode_ctrl(int p) +{ + return RTL930X_MAC_FORCE_MODE_CTRL + (p << 2); +} + +static inline int rtl930x_mac_port_ctrl(int p) +{ + return RTL930X_MAC_L2_PORT_CTRL(p); +} + +static inline int rtl930x_mac_link_spd_sts(int p) +{ + return RTL930X_MAC_LINK_SPD_STS(p); +} + +static u64 rtl930x_l2_hash_seed(u64 mac, u32 vid) +{ + u64 v = vid; + + v <<= 48; + v |= mac; + + return v; +} + +/* + * Calculate both the block 0 and the block 1 hash by applyingthe same hash + * algorithm as the one used currently by the ASIC to the seed, and return + * both hashes in the lower and higher word of the return value since only 12 bit of + * the hash are significant + */ +static u32 rtl930x_l2_hash_key(struct rtl838x_switch_priv *priv, u64 seed) +{ + u32 k0, k1, h1, h2, h; + + k0 = (u32) (((seed >> 55) & 0x1f) ^ ((seed >> 44) & 0x7ff) + ^ ((seed >> 33) & 0x7ff) ^ ((seed >> 22) & 0x7ff) + ^ ((seed >> 11) & 0x7ff) ^ (seed & 0x7ff)); + + h1 = (seed >> 11) & 0x7ff; + h1 = ((h1 & 0x1f) << 6) | ((h1 >> 5) & 0x3f); + + h2 = (seed >> 33) & 0x7ff; + h2 = ((h2 & 0x3f) << 5)| ((h2 >> 6) & 0x3f); + + k1 = (u32) (((seed << 55) & 0x1f) ^ ((seed >> 44) & 0x7ff) ^ h2 + ^ ((seed >> 22) & 0x7ff) ^ h1 + ^ (seed & 0x7ff)); + + // Algorithm choice for block 0 + if (sw_r32(RTL930X_L2_CTRL) & BIT(0)) + h = k1; + else + h = k0; + + /* Algorithm choice for block 1 + * Since k0 and k1 are < 2048, adding 2048 will offset the hash into the second + * half of hash-space + * 2048 is in fact the hash-table size 16384 divided by 4 hashes per bucket + * divided by 2 to divide the hash space in 2 + */ + if (sw_r32(RTL930X_L2_CTRL) & BIT(1)) + h |= (k1 + 2048) << 16; + else + h |= (k0 + 2048) << 16; + + return h; +} + +/* + * Fills an L2 entry structure from the SoC registers + */ +static void rtl930x_fill_l2_entry(u32 r[], struct rtl838x_l2_entry *e) +{ + pr_debug("In %s valid?\n", __func__); + e->valid = !!(r[2] & BIT(31)); + if (!e->valid) + return; + + pr_debug("In %s is valid\n", __func__); + e->is_ip_mc = false; + e->is_ipv6_mc = false; + + // TODO: Is there not a function to copy directly MAC memory? + e->mac[0] = (r[0] >> 24); + e->mac[1] = (r[0] >> 16); + e->mac[2] = (r[0] >> 8); + e->mac[3] = r[0]; + e->mac[4] = (r[1] >> 24); + e->mac[5] = (r[1] >> 16); + + e->next_hop = !!(r[2] & BIT(12)); + e->rvid = r[1] & 0xfff; + + /* Is it a unicast entry? check multicast bit */ + if (!(e->mac[0] & 1)) { + e->type = L2_UNICAST; + e->is_static = !!(r[2] & BIT(14)); + e->port = (r[2] >> 20) & 0x3ff; + // Check for trunk port + if (r[2] & BIT(30)) { + e->is_trunk = true; + e->stack_dev = (e->port >> 9) & 1; + e->trunk = e->port & 0x3f; + } else { + e->is_trunk = false; + e->stack_dev = (e->port >> 6) & 0xf; + e->port = e->port & 0x3f; + } + + e->block_da = !!(r[2] & BIT(15)); + e->block_sa = !!(r[2] & BIT(16)); + e->suspended = !!(r[2] & BIT(13)); + e->age = (r[2] >> 17) & 3; + 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->vid = 0; + } else { + e->vid = r[2] & 0xfff; + e->nh_route_id = 0; + } + } else { + e->valid = true; + e->type = L2_MULTICAST; + e->mc_portmask_index = (r[2] >> 16) & 0x3ff; + } +} + +/* + * Fills the 3 SoC table registers r[] with the information of in the rtl838x_l2_entry + */ +static void rtl930x_fill_l2_row(u32 r[], struct rtl838x_l2_entry *e) +{ + u32 port; + + if (!e->valid) { + r[0] = r[1] = r[2] = 0; + return; + } + + r[2] = BIT(31); // Set valid bit + + r[0] = ((u32)e->mac[0]) << 24 | ((u32)e->mac[1]) << 16 + | ((u32)e->mac[2]) << 8 | ((u32)e->mac[3]); + r[1] = ((u32)e->mac[4]) << 24 | ((u32)e->mac[5]) << 16; + + r[2] |= e->next_hop ? BIT(12) : 0; + + if (e->type == L2_UNICAST) { + r[2] |= e->is_static ? BIT(14) : 0; + r[1] |= e->rvid & 0xfff; + r[2] |= (e->port & 0x3ff) << 20; + if (e->is_trunk) { + r[2] |= BIT(30); + port = e->stack_dev << 9 | (e->port & 0x3f); + } else { + port = (e->stack_dev & 0xf) << 6; + port |= e->port & 0x3f; + } + r[2] |= port << 20; + r[2] |= e->block_da ? BIT(15) : 0; + r[2] |= e->block_sa ? BIT(17) : 0; + r[2] |= e->suspended ? BIT(13) : 0; + 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; + else + r[2] |= e->vid & 0xfff; + } else { // L2_MULTICAST + r[2] |= (e->mc_portmask_index & 0x3ff) << 16; + r[2] |= e->mc_mac_index & 0x7ff; + } +} + +/* + * Read an L2 UC or MC entry out of a hash bucket of the L2 forwarding table + * hash is the id of the bucket and pos is the position of the entry in that bucket + * The data read from the SoC is filled into rtl838x_l2_entry + */ +static u64 rtl930x_read_l2_entry_using_hash(u32 hash, u32 pos, struct rtl838x_l2_entry *e) +{ + u32 r[3]; + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 0); + u32 idx; + int i; + u64 mac; + u64 seed; + + pr_debug("%s: hash %08x, pos: %d\n", __func__, hash, pos); + + /* On the RTL93xx, 2 different hash algorithms are used making it a total of + * 8 buckets that need to be searched, 4 for each hash-half + * Use second hash space when bucket is between 4 and 8 */ + if (pos >= 4) { + pos -= 4; + hash >>= 16; + } else { + hash &= 0xffff; + } + + idx = (0 << 14) | (hash << 2) | pos; // Search SRAM, with hash and at pos in bucket + pr_debug("%s: NOW hash %08x, pos: %d\n", __func__, hash, pos); + + rtl_table_read(q, idx); + for (i = 0; i < 3; i++) + r[i] = sw_r32(rtl_table_data(q, i)); + + rtl_table_release(q); + + rtl930x_fill_l2_entry(r, e); + + pr_debug("%s: valid: %d, nh: %d\n", __func__, e->valid, e->next_hop); + if (!e->valid) + return 0; + + mac = ((u64)e->mac[0]) << 40 | ((u64)e->mac[1]) << 32 | ((u64)e->mac[2]) << 24 + | ((u64)e->mac[3]) << 16 | ((u64)e->mac[4]) << 8 | ((u64)e->mac[5]); + + seed = rtl930x_l2_hash_seed(mac, e->rvid); + pr_debug("%s: mac %016llx, seed %016llx\n", __func__, mac, seed); + // return vid with concatenated mac as unique id + return seed; +} + +static void rtl930x_write_l2_entry_using_hash(u32 hash, u32 pos, struct rtl838x_l2_entry *e) +{ + u32 r[3]; + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 0); + 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, + e->mac[0], e->mac[1], e->mac[2], e->mac[3],e->mac[4],e->mac[5]); + + rtl930x_fill_l2_row(r, e); + + for (i= 0; i < 3; i++) + sw_w32(r[i], rtl_table_data(q, i)); + + rtl_table_write(q, idx); + rtl_table_release(q); +} + +static u64 rtl930x_read_cam(int idx, struct rtl838x_l2_entry *e) +{ + u32 r[3]; + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 1); + int i; + + rtl_table_read(q, idx); + for (i= 0; i < 3; i++) + r[i] = sw_r32(rtl_table_data(q, i)); + + rtl_table_release(q); + + rtl930x_fill_l2_entry(r, e); + if (!e->valid) + return 0; + + // return mac with concatenated vid as unique id + return ((u64)r[0] << 28) | ((r[1] & 0xffff0000) >> 4) | e->vid; +} + +static void rtl930x_write_cam(int idx, struct rtl838x_l2_entry *e) +{ + u32 r[3]; + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 1); // Access L2 Table 1 + int i; + + rtl930x_fill_l2_row(r, e); + + for (i= 0; i < 3; i++) + sw_w32(r[i], rtl_table_data(q, i)); + + rtl_table_write(q, idx); + rtl_table_release(q); +} + +static void dump_l2_entry(struct rtl838x_l2_entry *e) +{ + pr_info("MAC: %02x:%02x:%02x:%02x:%02x:%02x vid: %d, rvid: %d, port: %d, valid: %d\n", + e->mac[0], e->mac[1], e->mac[2], e->mac[3], e->mac[4], e->mac[5], + e->vid, e->rvid, e->port, e->valid); + pr_info("Type: %d, is_static: %d, is_ip_mc: %d, is_ipv6_mc: %d, block_da: %d\n", + e->type, e->is_static, e->is_ip_mc, e->is_ipv6_mc, e->block_da); + pr_info(" block_sa: %d, suspended: %d, next_hop: %d, age: %d, is_trunk: %d, trunk: %d\n", + e->block_sa, e->suspended, e->next_hop, e->age, e->is_trunk, e->trunk); + if (e->is_ip_mc || e->is_ipv6_mc) + pr_info(" mc_portmask_index: %d, mc_gip: %d, mc_sip: %d\n", + e->mc_portmask_index, e->mc_gip, e->mc_sip); + pr_info(" stac_dev: %d, nh_route_id: %d, port: %d, dev_id\n", + 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; + // Read MC_PORTMASK (2) via register RTL9300_TBL_L2 + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 2); + + rtl_table_read(q, idx); + portmask = sw_r32(rtl_table_data(q, 0)); + portmask >>= 3; + rtl_table_release(q); + + pr_debug("%s: Index idx %d has portmask %08x\n", __func__, idx, portmask); + return portmask; +} + +static void rtl930x_write_mcast_pmask(int idx, u64 portmask) +{ + u32 pm = portmask; + + // Access MC_PORTMASK (2) via register RTL9300_TBL_L2 + struct table_reg *q = rtl_table_get(RTL9300_TBL_L2, 2); + + pr_debug("%s: Index idx %d has portmask %08x\n", __func__, idx, pm); + pm <<= 3; + sw_w32(pm, rtl_table_data(q, 0)); + rtl_table_write(q, idx); + rtl_table_release(q); +} + +u64 rtl930x_traffic_get(int source) +{ + u32 v; + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 6); + + rtl_table_read(r, source); + v = sw_r32(rtl_table_data(r, 0)); + rtl_table_release(r); + return v >> 3; +} + +/* + * Enable traffic between a source port and a destination port matrix + */ +void rtl930x_traffic_set(int source, u64 dest_matrix) +{ + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 6); + + sw_w32((dest_matrix << 3), rtl_table_data(r, 0)); + rtl_table_write(r, source); + rtl_table_release(r); +} + +void rtl930x_traffic_enable(int source, int dest) +{ + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 6); + rtl_table_read(r, source); + sw_w32_mask(0, BIT(dest + 3), rtl_table_data(r, 0)); + rtl_table_write(r, source); + rtl_table_release(r); +} + +void rtl930x_traffic_disable(int source, int dest) +{ + struct table_reg *r = rtl_table_get(RTL9300_TBL_0, 6); + rtl_table_read(r, source); + sw_w32_mask(BIT(dest + 3), 0, rtl_table_data(r, 0)); + rtl_table_write(r, source); + rtl_table_release(r); +} + +void rtl9300_dump_debug(void) +{ + int i; + u16 r = RTL930X_STAT_PRVTE_DROP_COUNTER0; + + for (i = 0; i < 10; i ++) { + pr_info("# %d %08x %08x %08x %08x %08x %08x %08x %08x\n", i * 8, + sw_r32(r), sw_r32(r + 4), sw_r32(r + 8), sw_r32(r + 12), + sw_r32(r + 16), sw_r32(r + 20), sw_r32(r + 24), sw_r32(r + 28)); + r += 32; + } + pr_info("# %08x %08x %08x %08x %08x\n", + sw_r32(r), sw_r32(r + 4), sw_r32(r + 8), sw_r32(r + 12), sw_r32(r + 16)); + rtl930x_print_matrix(); + pr_info("RTL930X_L2_PORT_SABLK_CTRL: %08x, RTL930X_L2_PORT_DABLK_CTRL %08x\n", + sw_r32(RTL930X_L2_PORT_SABLK_CTRL), sw_r32(RTL930X_L2_PORT_DABLK_CTRL) + + ); +} + +irqreturn_t rtl930x_switch_irq(int irq, void *dev_id) +{ + struct dsa_switch *ds = dev_id; + u32 status = sw_r32(RTL930X_ISR_GLB); + u32 ports = sw_r32(RTL930X_ISR_PORT_LINK_STS_CHG); + u32 link; + int i; + + /* 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)) { + /* Read the register twice because of issues with latency at least + * with the external RTL8226 PHY on the XGS1210 */ + link = sw_r32(RTL930X_MAC_LINK_STS); + link = sw_r32(RTL930X_MAC_LINK_STS); + if (link & BIT(i)) + dsa_port_phylink_mac_change(ds, i, true); + else + dsa_port_phylink_mac_change(ds, i, false); + } + } + + 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; + int err = 0; + + pr_debug("%s: port %d, page: %d, reg: %x, val: %x\n", __func__, port, page, reg, val); + + if (port > 63 || page > 4095 || reg > 31) + return -ENOTSUPP; + + val &= 0xffff; + mutex_lock(&smi_lock); + + sw_w32(BIT(port), RTL930X_SMI_ACCESS_PHY_CTRL_0); + sw_w32_mask(0xffff << 16, val << 16, RTL930X_SMI_ACCESS_PHY_CTRL_2); + v = reg << 20 | page << 3 | 0x1f << 15 | BIT(2) | BIT(0); + sw_w32(v, RTL930X_SMI_ACCESS_PHY_CTRL_1); + + do { + v = sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_1); + } while (v & 0x1); + + if (v & 0x2) + err = -EIO; + + mutex_unlock(&smi_lock); + + return err; +} + +int rtl930x_read_phy(u32 port, u32 page, u32 reg, u32 *val) +{ + u32 v; + int err = 0; + + if (port > 63 || page > 4095 || reg > 31) + return -ENOTSUPP; + + mutex_lock(&smi_lock); + + sw_w32_mask(0xffff << 16, port << 16, RTL930X_SMI_ACCESS_PHY_CTRL_2); + v = reg << 20 | page << 3 | 0x1f << 15 | 1; + sw_w32(v, RTL930X_SMI_ACCESS_PHY_CTRL_1); + + do { + v = sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_1); + } while ( v & 0x1); + + if (v & BIT(25)) { + pr_debug("Error reading phy %d, register %d\n", port, reg); + err = -EIO; + } + *val = (sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_2) & 0xffff); + + pr_debug("%s: port %d, page: %d, reg: %x, val: %x\n", __func__, port, page, reg, *val); + + mutex_unlock(&smi_lock); + + return err; +} + +/* + * Write to an mmd register of the PHY + */ +int rtl930x_write_mmd_phy(u32 port, u32 devnum, u32 regnum, u32 val) +{ + int err = 0; + u32 v; + + mutex_lock(&smi_lock); + + // Set PHY to access + sw_w32(BIT(port), RTL930X_SMI_ACCESS_PHY_CTRL_0); + + // Set data to write + sw_w32_mask(0xffff << 16, val << 16, RTL930X_SMI_ACCESS_PHY_CTRL_2); + + // Set MMD device number and register to write to + sw_w32(devnum << 16 | (regnum & 0xffff), RTL930X_SMI_ACCESS_PHY_CTRL_3); + + v = BIT(2) | BIT(1) | BIT(0); // WRITE | MMD-access | EXEC + sw_w32(v, RTL930X_SMI_ACCESS_PHY_CTRL_1); + + do { + v = sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_1); + } while (v & BIT(0)); + + pr_debug("%s: port %d, regnum: %x, val: %x (err %d)\n", __func__, port, regnum, val, err); + mutex_unlock(&smi_lock); + return err; +} + +/* + * Read an mmd register of the PHY + */ +int rtl930x_read_mmd_phy(u32 port, u32 devnum, u32 regnum, u32 *val) +{ + int err = 0; + u32 v; + + mutex_lock(&smi_lock); + + // Set PHY to access + sw_w32_mask(0xffff << 16, port << 16, RTL930X_SMI_ACCESS_PHY_CTRL_2); + + // Set MMD device number and register to write to + sw_w32(devnum << 16 | (regnum & 0xffff), RTL930X_SMI_ACCESS_PHY_CTRL_3); + + v = BIT(1) | BIT(0); // MMD-access | EXEC + sw_w32(v, RTL930X_SMI_ACCESS_PHY_CTRL_1); + + do { + v = sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_1); + } while (v & BIT(0)); + // There is no error-checking via BIT 25 of v, as it does not seem to be set correctly + *val = (sw_r32(RTL930X_SMI_ACCESS_PHY_CTRL_2) & 0xffff); + pr_debug("%s: port %d, regnum: %x, val: %x (err %d)\n", __func__, port, regnum, *val, err); + + mutex_unlock(&smi_lock); + + return err; +} + +/* + * Calculate both the block 0 and the block 1 hash, and return in + * lower and higher word of the return value since only 12 bit of + * the hash are significant + */ +u32 rtl930x_hash(struct rtl838x_switch_priv *priv, u64 seed) +{ + u32 k0, k1, h1, h2, h; + + k0 = (u32) (((seed >> 55) & 0x1f) ^ ((seed >> 44) & 0x7ff) + ^ ((seed >> 33) & 0x7ff) ^ ((seed >> 22) & 0x7ff) + ^ ((seed >> 11) & 0x7ff) ^ (seed & 0x7ff)); + + h1 = (seed >> 11) & 0x7ff; + h1 = ((h1 & 0x1f) << 6) | ((h1 >> 5) & 0x3f); + + h2 = (seed >> 33) & 0x7ff; + h2 = ((h2 & 0x3f) << 5)| ((h2 >> 6) & 0x3f); + + k1 = (u32) (((seed << 55) & 0x1f) ^ ((seed >> 44) & 0x7ff) ^ h2 + ^ ((seed >> 22) & 0x7ff) ^ h1 + ^ (seed & 0x7ff)); + + // Algorithm choice for block 0 + if (sw_r32(RTL930X_L2_CTRL) & BIT(0)) + h = k1; + else + h = k0; + + /* Algorithm choice for block 1 + * Since k0 and k1 are < 2048, adding 2048 will offset the hash into the second + * half of hash-space + * 2048 is in fact the hash-table size 16384 divided by 4 hashes per bucket + * divided by 2 to divide the hash space in 2 + */ + if (sw_r32(RTL930X_L2_CTRL) & BIT(1)) + h |= (k1 + 2048) << 16; + else + h |= (k0 + 2048) << 16; + + return h; +} + +/* + * Enables or disables the EEE/EEEP capability of a port + */ +void rtl930x_port_eee_set(struct rtl838x_switch_priv *priv, int port, bool enable) +{ + u32 v; + + // This works only for Ethernet ports, and on the RTL930X, ports from 26 are SFP + if (port >= 26) + return; + + pr_debug("In %s: setting port %d to %d\n", __func__, port, enable); + v = enable ? 0x3f : 0x0; + + // Set EEE/EEEP state for 100, 500, 1000MBit and 2.5, 5 and 10GBit + sw_w32_mask(0, v << 10, rtl930x_mac_force_mode_ctrl(port)); + + // Set TX/RX EEE state + v = enable ? 0x3 : 0x0; + sw_w32(v, RTL930X_EEE_CTRL(port)); + + priv->ports[port].eee_enabled = enable; +} + +/* + * Get EEE own capabilities and negotiation result + */ +int rtl930x_eee_port_ability(struct rtl838x_switch_priv *priv, struct ethtool_eee *e, int port) +{ + u32 link, a; + + if (port >= 26) + return -ENOTSUPP; + + pr_info("In %s, port %d\n", __func__, port); + link = sw_r32(RTL930X_MAC_LINK_STS); + link = sw_r32(RTL930X_MAC_LINK_STS); + if (!(link & BIT(port))) + return 0; + + pr_info("Setting advertised\n"); + if (sw_r32(rtl930x_mac_force_mode_ctrl(port)) & BIT(10)) + e->advertised |= ADVERTISED_100baseT_Full; + + if (sw_r32(rtl930x_mac_force_mode_ctrl(port)) & BIT(12)) + e->advertised |= ADVERTISED_1000baseT_Full; + + if (priv->ports[port].is2G5 && sw_r32(rtl930x_mac_force_mode_ctrl(port)) & BIT(13)) { + pr_info("ADVERTISING 2.5G EEE\n"); + e->advertised |= ADVERTISED_2500baseX_Full; + } + + if (priv->ports[port].is10G && sw_r32(rtl930x_mac_force_mode_ctrl(port)) & BIT(15)) + e->advertised |= ADVERTISED_10000baseT_Full; + + a = sw_r32(RTL930X_MAC_EEE_ABLTY); + a = sw_r32(RTL930X_MAC_EEE_ABLTY); + pr_info("Link partner: %08x\n", a); + if (a & BIT(port)) { + e->lp_advertised = ADVERTISED_100baseT_Full; + e->lp_advertised |= ADVERTISED_1000baseT_Full; + if (priv->ports[port].is2G5) + e->lp_advertised |= ADVERTISED_2500baseX_Full; + if (priv->ports[port].is10G) + e->lp_advertised |= ADVERTISED_10000baseT_Full; + } + + // Read 2x to clear latched state + a = sw_r32(RTL930X_EEEP_PORT_CTRL(port)); + a = sw_r32(RTL930X_EEEP_PORT_CTRL(port)); + pr_info("%s RTL930X_EEEP_PORT_CTRL: %08x\n", __func__, a); + + return 0; +} + +static void rtl930x_init_eee(struct rtl838x_switch_priv *priv, bool enable) +{ + int i; + + pr_info("Setting up EEE, state: %d\n", enable); + + // Setup EEE on all ports + for (i = 0; i < priv->cpu_port; i++) { + if (priv->ports[i].phy) + rtl930x_port_eee_set(priv, i, enable); + } + + priv->eee_enabled = enable; +} + +const struct rtl838x_reg rtl930x_reg = { + .mask_port_reg_be = rtl838x_mask_port_reg, + .set_port_reg_be = rtl838x_set_port_reg, + .get_port_reg_be = rtl838x_get_port_reg, + .mask_port_reg_le = rtl838x_mask_port_reg, + .set_port_reg_le = rtl838x_set_port_reg, + .get_port_reg_le = rtl838x_get_port_reg, + .stat_port_rst = RTL930X_STAT_PORT_RST, + .stat_rst = RTL930X_STAT_RST, + .stat_port_std_mib = RTL930X_STAT_PORT_MIB_CNTR, + .traffic_enable = rtl930x_traffic_enable, + .traffic_disable = rtl930x_traffic_disable, + .traffic_get = rtl930x_traffic_get, + .traffic_set = rtl930x_traffic_set, + .l2_ctrl_0 = RTL930X_L2_CTRL, + .l2_ctrl_1 = RTL930X_L2_AGE_CTRL, + .l2_port_aging_out = RTL930X_L2_PORT_AGE_CTRL, + .smi_poll_ctrl = RTL930X_SMI_POLL_CTRL, // TODO: Difference to RTL9300_SMI_PRVTE_POLLING_CTRL + .l2_tbl_flush_ctrl = RTL930X_L2_TBL_FLUSH_CTRL, + .exec_tbl0_cmd = rtl930x_exec_tbl0_cmd, + .exec_tbl1_cmd = rtl930x_exec_tbl1_cmd, + .tbl_access_data_0 = rtl930x_tbl_access_data_0, + .isr_glb_src = RTL930X_ISR_GLB, + .isr_port_link_sts_chg = RTL930X_ISR_PORT_LINK_STS_CHG, + .imr_port_link_sts_chg = RTL930X_IMR_PORT_LINK_STS_CHG, + .imr_glb = RTL930X_IMR_GLB, + .vlan_tables_read = rtl930x_vlan_tables_read, + .vlan_set_tagged = rtl930x_vlan_set_tagged, + .vlan_set_untagged = rtl930x_vlan_set_untagged, + .vlan_profile_dump = rtl930x_vlan_profile_dump, + .vlan_profile_setup = rtl930x_vlan_profile_setup, + .vlan_fwd_on_inner = rtl930x_vlan_fwd_on_inner, + .stp_get = rtl930x_stp_get, + .stp_set = rtl930x_stp_set, + .mac_force_mode_ctrl = rtl930x_mac_force_mode_ctrl, + .mac_port_ctrl = rtl930x_mac_port_ctrl, + .l2_port_new_salrn = rtl930x_l2_port_new_salrn, + .l2_port_new_sa_fwd = rtl930x_l2_port_new_sa_fwd, + .mir_ctrl = RTL930X_MIR_CTRL, + .mir_dpm = RTL930X_MIR_DPM_CTRL, + .mir_spm = RTL930X_MIR_SPM_CTRL, + .mac_link_sts = RTL930X_MAC_LINK_STS, + .mac_link_dup_sts = RTL930X_MAC_LINK_DUP_STS, + .mac_link_spd_sts = rtl930x_mac_link_spd_sts, + .mac_rx_pause_sts = RTL930X_MAC_RX_PAUSE_STS, + .mac_tx_pause_sts = RTL930X_MAC_TX_PAUSE_STS, + .read_l2_entry_using_hash = rtl930x_read_l2_entry_using_hash, + .write_l2_entry_using_hash = rtl930x_write_l2_entry_using_hash, + .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_pb = RTL930X_VLAN_PORT_PB_VLAN, + .vlan_port_tag_sts_ctrl = RTL930X_VLAN_PORT_TAG_STS_CTRL, + .trk_mbr_ctr = rtl930x_trk_mbr_ctr, + .rma_bpdu_fld_pmask = RTL930X_RMA_BPDU_FLD_PMSK, + .init_eee = rtl930x_init_eee, + .port_eee_set = rtl930x_port_eee_set, + .eee_port_ability = rtl930x_eee_port_ability, + .read_mcast_pmask = rtl930x_read_mcast_pmask, + .write_mcast_pmask = rtl930x_write_mcast_pmask, +}; 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