Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Felix Fietkau | 4018 | 72.28% | 13 | 34.21% |
Lorenzo Bianconi | 749 | 13.47% | 5 | 13.16% |
Daniel Golle | 554 | 9.97% | 4 | 10.53% |
Sean Wang | 85 | 1.53% | 7 | 18.42% |
Yan Cangang | 52 | 0.94% | 1 | 2.63% |
John Crispin | 37 | 0.67% | 1 | 2.63% |
Ilya Lipnitskiy | 26 | 0.47% | 1 | 2.63% |
René van Dorst | 19 | 0.34% | 1 | 2.63% |
Dan Carpenter | 8 | 0.14% | 1 | 2.63% |
Nelson Chang | 6 | 0.11% | 1 | 2.63% |
Kees Cook | 3 | 0.05% | 1 | 2.63% |
Thomas Gleixner | 1 | 0.02% | 1 | 2.63% |
DENG Qingfang | 1 | 0.02% | 1 | 2.63% |
Total | 5559 | 38 |
// SPDX-License-Identifier: GPL-2.0-only /* Copyright (C) 2020 Felix Fietkau <nbd@nbd.name> */ #include <linux/kernel.h> #include <linux/io.h> #include <linux/iopoll.h> #include <linux/etherdevice.h> #include <linux/platform_device.h> #include <linux/if_ether.h> #include <linux/if_vlan.h> #include <net/dst_metadata.h> #include <net/dsa.h> #include "mtk_eth_soc.h" #include "mtk_ppe.h" #include "mtk_ppe_regs.h" static DEFINE_SPINLOCK(ppe_lock); static const struct rhashtable_params mtk_flow_l2_ht_params = { .head_offset = offsetof(struct mtk_flow_entry, l2_node), .key_offset = offsetof(struct mtk_flow_entry, data.bridge), .key_len = offsetof(struct mtk_foe_bridge, key_end), .automatic_shrinking = true, }; static void ppe_w32(struct mtk_ppe *ppe, u32 reg, u32 val) { writel(val, ppe->base + reg); } static u32 ppe_r32(struct mtk_ppe *ppe, u32 reg) { return readl(ppe->base + reg); } static u32 ppe_m32(struct mtk_ppe *ppe, u32 reg, u32 mask, u32 set) { u32 val; val = ppe_r32(ppe, reg); val &= ~mask; val |= set; ppe_w32(ppe, reg, val); return val; } static u32 ppe_set(struct mtk_ppe *ppe, u32 reg, u32 val) { return ppe_m32(ppe, reg, 0, val); } static u32 ppe_clear(struct mtk_ppe *ppe, u32 reg, u32 val) { return ppe_m32(ppe, reg, val, 0); } static u32 mtk_eth_timestamp(struct mtk_eth *eth) { return mtk_r32(eth, 0x0010) & mtk_get_ib1_ts_mask(eth); } static int mtk_ppe_wait_busy(struct mtk_ppe *ppe) { int ret; u32 val; ret = readl_poll_timeout(ppe->base + MTK_PPE_GLO_CFG, val, !(val & MTK_PPE_GLO_CFG_BUSY), 20, MTK_PPE_WAIT_TIMEOUT_US); if (ret) dev_err(ppe->dev, "PPE table busy"); return ret; } static int mtk_ppe_mib_wait_busy(struct mtk_ppe *ppe) { int ret; u32 val; ret = readl_poll_timeout(ppe->base + MTK_PPE_MIB_SER_CR, val, !(val & MTK_PPE_MIB_SER_CR_ST), 20, MTK_PPE_WAIT_TIMEOUT_US); if (ret) dev_err(ppe->dev, "MIB table busy"); return ret; } static int mtk_mib_entry_read(struct mtk_ppe *ppe, u16 index, u64 *bytes, u64 *packets) { u32 byte_cnt_low, byte_cnt_high, pkt_cnt_low, pkt_cnt_high; u32 val, cnt_r0, cnt_r1, cnt_r2; int ret; val = FIELD_PREP(MTK_PPE_MIB_SER_CR_ADDR, index) | MTK_PPE_MIB_SER_CR_ST; ppe_w32(ppe, MTK_PPE_MIB_SER_CR, val); ret = mtk_ppe_mib_wait_busy(ppe); if (ret) return ret; cnt_r0 = readl(ppe->base + MTK_PPE_MIB_SER_R0); cnt_r1 = readl(ppe->base + MTK_PPE_MIB_SER_R1); cnt_r2 = readl(ppe->base + MTK_PPE_MIB_SER_R2); byte_cnt_low = FIELD_GET(MTK_PPE_MIB_SER_R0_BYTE_CNT_LOW, cnt_r0); byte_cnt_high = FIELD_GET(MTK_PPE_MIB_SER_R1_BYTE_CNT_HIGH, cnt_r1); pkt_cnt_low = FIELD_GET(MTK_PPE_MIB_SER_R1_PKT_CNT_LOW, cnt_r1); pkt_cnt_high = FIELD_GET(MTK_PPE_MIB_SER_R2_PKT_CNT_HIGH, cnt_r2); *bytes = ((u64)byte_cnt_high << 32) | byte_cnt_low; *packets = (pkt_cnt_high << 16) | pkt_cnt_low; return 0; } static void mtk_ppe_cache_clear(struct mtk_ppe *ppe) { ppe_set(ppe, MTK_PPE_CACHE_CTL, MTK_PPE_CACHE_CTL_CLEAR); ppe_clear(ppe, MTK_PPE_CACHE_CTL, MTK_PPE_CACHE_CTL_CLEAR); } static void mtk_ppe_cache_enable(struct mtk_ppe *ppe, bool enable) { mtk_ppe_cache_clear(ppe); ppe_m32(ppe, MTK_PPE_CACHE_CTL, MTK_PPE_CACHE_CTL_EN, enable * MTK_PPE_CACHE_CTL_EN); } static u32 mtk_ppe_hash_entry(struct mtk_eth *eth, struct mtk_foe_entry *e) { u32 hv1, hv2, hv3; u32 hash; switch (mtk_get_ib1_pkt_type(eth, e->ib1)) { case MTK_PPE_PKT_TYPE_IPV4_ROUTE: case MTK_PPE_PKT_TYPE_IPV4_HNAPT: hv1 = e->ipv4.orig.ports; hv2 = e->ipv4.orig.dest_ip; hv3 = e->ipv4.orig.src_ip; break; case MTK_PPE_PKT_TYPE_IPV6_ROUTE_3T: case MTK_PPE_PKT_TYPE_IPV6_ROUTE_5T: hv1 = e->ipv6.src_ip[3] ^ e->ipv6.dest_ip[3]; hv1 ^= e->ipv6.ports; hv2 = e->ipv6.src_ip[2] ^ e->ipv6.dest_ip[2]; hv2 ^= e->ipv6.dest_ip[0]; hv3 = e->ipv6.src_ip[1] ^ e->ipv6.dest_ip[1]; hv3 ^= e->ipv6.src_ip[0]; break; case MTK_PPE_PKT_TYPE_IPV4_DSLITE: case MTK_PPE_PKT_TYPE_IPV6_6RD: default: WARN_ON_ONCE(1); return MTK_PPE_HASH_MASK; } hash = (hv1 & hv2) | ((~hv1) & hv3); hash = (hash >> 24) | ((hash & 0xffffff) << 8); hash ^= hv1 ^ hv2 ^ hv3; hash ^= hash >> 16; hash <<= (ffs(eth->soc->hash_offset) - 1); hash &= MTK_PPE_ENTRIES - 1; return hash; } static inline struct mtk_foe_mac_info * mtk_foe_entry_l2(struct mtk_eth *eth, struct mtk_foe_entry *entry) { int type = mtk_get_ib1_pkt_type(eth, entry->ib1); if (type == MTK_PPE_PKT_TYPE_BRIDGE) return &entry->bridge.l2; if (type >= MTK_PPE_PKT_TYPE_IPV4_DSLITE) return &entry->ipv6.l2; return &entry->ipv4.l2; } static inline u32 * mtk_foe_entry_ib2(struct mtk_eth *eth, struct mtk_foe_entry *entry) { int type = mtk_get_ib1_pkt_type(eth, entry->ib1); if (type == MTK_PPE_PKT_TYPE_BRIDGE) return &entry->bridge.ib2; if (type >= MTK_PPE_PKT_TYPE_IPV4_DSLITE) return &entry->ipv6.ib2; return &entry->ipv4.ib2; } int mtk_foe_entry_prepare(struct mtk_eth *eth, struct mtk_foe_entry *entry, int type, int l4proto, u8 pse_port, u8 *src_mac, u8 *dest_mac) { struct mtk_foe_mac_info *l2; u32 ports_pad, val; memset(entry, 0, sizeof(*entry)); if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) { val = FIELD_PREP(MTK_FOE_IB1_STATE, MTK_FOE_STATE_BIND) | FIELD_PREP(MTK_FOE_IB1_PACKET_TYPE_V2, type) | FIELD_PREP(MTK_FOE_IB1_UDP, l4proto == IPPROTO_UDP) | MTK_FOE_IB1_BIND_CACHE_V2 | MTK_FOE_IB1_BIND_TTL_V2; entry->ib1 = val; val = FIELD_PREP(MTK_FOE_IB2_DEST_PORT_V2, pse_port) | FIELD_PREP(MTK_FOE_IB2_PORT_AG_V2, 0xf); } else { int port_mg = eth->soc->offload_version > 1 ? 0 : 0x3f; val = FIELD_PREP(MTK_FOE_IB1_STATE, MTK_FOE_STATE_BIND) | FIELD_PREP(MTK_FOE_IB1_PACKET_TYPE, type) | FIELD_PREP(MTK_FOE_IB1_UDP, l4proto == IPPROTO_UDP) | MTK_FOE_IB1_BIND_CACHE | MTK_FOE_IB1_BIND_TTL; entry->ib1 = val; val = FIELD_PREP(MTK_FOE_IB2_DEST_PORT, pse_port) | FIELD_PREP(MTK_FOE_IB2_PORT_MG, port_mg) | FIELD_PREP(MTK_FOE_IB2_PORT_AG, 0x1f); } if (is_multicast_ether_addr(dest_mac)) val |= mtk_get_ib2_multicast_mask(eth); ports_pad = 0xa5a5a500 | (l4proto & 0xff); if (type == MTK_PPE_PKT_TYPE_IPV4_ROUTE) entry->ipv4.orig.ports = ports_pad; if (type == MTK_PPE_PKT_TYPE_IPV6_ROUTE_3T) entry->ipv6.ports = ports_pad; if (type == MTK_PPE_PKT_TYPE_BRIDGE) { ether_addr_copy(entry->bridge.src_mac, src_mac); ether_addr_copy(entry->bridge.dest_mac, dest_mac); entry->bridge.ib2 = val; l2 = &entry->bridge.l2; } else if (type >= MTK_PPE_PKT_TYPE_IPV4_DSLITE) { entry->ipv6.ib2 = val; l2 = &entry->ipv6.l2; } else { entry->ipv4.ib2 = val; l2 = &entry->ipv4.l2; } l2->dest_mac_hi = get_unaligned_be32(dest_mac); l2->dest_mac_lo = get_unaligned_be16(dest_mac + 4); l2->src_mac_hi = get_unaligned_be32(src_mac); l2->src_mac_lo = get_unaligned_be16(src_mac + 4); if (type >= MTK_PPE_PKT_TYPE_IPV6_ROUTE_3T) l2->etype = ETH_P_IPV6; else l2->etype = ETH_P_IP; return 0; } int mtk_foe_entry_set_pse_port(struct mtk_eth *eth, struct mtk_foe_entry *entry, u8 port) { u32 *ib2 = mtk_foe_entry_ib2(eth, entry); u32 val = *ib2; if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) { val &= ~MTK_FOE_IB2_DEST_PORT_V2; val |= FIELD_PREP(MTK_FOE_IB2_DEST_PORT_V2, port); } else { val &= ~MTK_FOE_IB2_DEST_PORT; val |= FIELD_PREP(MTK_FOE_IB2_DEST_PORT, port); } *ib2 = val; return 0; } int mtk_foe_entry_set_ipv4_tuple(struct mtk_eth *eth, struct mtk_foe_entry *entry, bool egress, __be32 src_addr, __be16 src_port, __be32 dest_addr, __be16 dest_port) { int type = mtk_get_ib1_pkt_type(eth, entry->ib1); struct mtk_ipv4_tuple *t; switch (type) { case MTK_PPE_PKT_TYPE_IPV4_HNAPT: if (egress) { t = &entry->ipv4.new; break; } fallthrough; case MTK_PPE_PKT_TYPE_IPV4_DSLITE: case MTK_PPE_PKT_TYPE_IPV4_ROUTE: t = &entry->ipv4.orig; break; case MTK_PPE_PKT_TYPE_IPV6_6RD: entry->ipv6_6rd.tunnel_src_ip = be32_to_cpu(src_addr); entry->ipv6_6rd.tunnel_dest_ip = be32_to_cpu(dest_addr); return 0; default: WARN_ON_ONCE(1); return -EINVAL; } t->src_ip = be32_to_cpu(src_addr); t->dest_ip = be32_to_cpu(dest_addr); if (type == MTK_PPE_PKT_TYPE_IPV4_ROUTE) return 0; t->src_port = be16_to_cpu(src_port); t->dest_port = be16_to_cpu(dest_port); return 0; } int mtk_foe_entry_set_ipv6_tuple(struct mtk_eth *eth, struct mtk_foe_entry *entry, __be32 *src_addr, __be16 src_port, __be32 *dest_addr, __be16 dest_port) { int type = mtk_get_ib1_pkt_type(eth, entry->ib1); u32 *src, *dest; int i; switch (type) { case MTK_PPE_PKT_TYPE_IPV4_DSLITE: src = entry->dslite.tunnel_src_ip; dest = entry->dslite.tunnel_dest_ip; break; case MTK_PPE_PKT_TYPE_IPV6_ROUTE_5T: case MTK_PPE_PKT_TYPE_IPV6_6RD: entry->ipv6.src_port = be16_to_cpu(src_port); entry->ipv6.dest_port = be16_to_cpu(dest_port); fallthrough; case MTK_PPE_PKT_TYPE_IPV6_ROUTE_3T: src = entry->ipv6.src_ip; dest = entry->ipv6.dest_ip; break; default: WARN_ON_ONCE(1); return -EINVAL; } for (i = 0; i < 4; i++) src[i] = be32_to_cpu(src_addr[i]); for (i = 0; i < 4; i++) dest[i] = be32_to_cpu(dest_addr[i]); return 0; } int mtk_foe_entry_set_dsa(struct mtk_eth *eth, struct mtk_foe_entry *entry, int port) { struct mtk_foe_mac_info *l2 = mtk_foe_entry_l2(eth, entry); l2->etype = BIT(port); if (!(entry->ib1 & mtk_get_ib1_vlan_layer_mask(eth))) entry->ib1 |= mtk_prep_ib1_vlan_layer(eth, 1); else l2->etype |= BIT(8); entry->ib1 &= ~mtk_get_ib1_vlan_tag_mask(eth); return 0; } int mtk_foe_entry_set_vlan(struct mtk_eth *eth, struct mtk_foe_entry *entry, int vid) { struct mtk_foe_mac_info *l2 = mtk_foe_entry_l2(eth, entry); switch (mtk_get_ib1_vlan_layer(eth, entry->ib1)) { case 0: entry->ib1 |= mtk_get_ib1_vlan_tag_mask(eth) | mtk_prep_ib1_vlan_layer(eth, 1); l2->vlan1 = vid; return 0; case 1: if (!(entry->ib1 & mtk_get_ib1_vlan_tag_mask(eth))) { l2->vlan1 = vid; l2->etype |= BIT(8); } else { l2->vlan2 = vid; entry->ib1 += mtk_prep_ib1_vlan_layer(eth, 1); } return 0; default: return -ENOSPC; } } int mtk_foe_entry_set_pppoe(struct mtk_eth *eth, struct mtk_foe_entry *entry, int sid) { struct mtk_foe_mac_info *l2 = mtk_foe_entry_l2(eth, entry); if (!(entry->ib1 & mtk_get_ib1_vlan_layer_mask(eth)) || (entry->ib1 & mtk_get_ib1_vlan_tag_mask(eth))) l2->etype = ETH_P_PPP_SES; entry->ib1 |= mtk_get_ib1_ppoe_mask(eth); l2->pppoe_id = sid; return 0; } int mtk_foe_entry_set_wdma(struct mtk_eth *eth, struct mtk_foe_entry *entry, int wdma_idx, int txq, int bss, int wcid) { struct mtk_foe_mac_info *l2 = mtk_foe_entry_l2(eth, entry); u32 *ib2 = mtk_foe_entry_ib2(eth, entry); if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) { *ib2 &= ~MTK_FOE_IB2_PORT_MG_V2; *ib2 |= FIELD_PREP(MTK_FOE_IB2_RX_IDX, txq) | MTK_FOE_IB2_WDMA_WINFO_V2; l2->winfo = FIELD_PREP(MTK_FOE_WINFO_WCID, wcid) | FIELD_PREP(MTK_FOE_WINFO_BSS, bss); } else { *ib2 &= ~MTK_FOE_IB2_PORT_MG; *ib2 |= MTK_FOE_IB2_WDMA_WINFO; if (wdma_idx) *ib2 |= MTK_FOE_IB2_WDMA_DEVIDX; l2->vlan2 = FIELD_PREP(MTK_FOE_VLAN2_WINFO_BSS, bss) | FIELD_PREP(MTK_FOE_VLAN2_WINFO_WCID, wcid) | FIELD_PREP(MTK_FOE_VLAN2_WINFO_RING, txq); } return 0; } int mtk_foe_entry_set_queue(struct mtk_eth *eth, struct mtk_foe_entry *entry, unsigned int queue) { u32 *ib2 = mtk_foe_entry_ib2(eth, entry); if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) { *ib2 &= ~MTK_FOE_IB2_QID_V2; *ib2 |= FIELD_PREP(MTK_FOE_IB2_QID_V2, queue); *ib2 |= MTK_FOE_IB2_PSE_QOS_V2; } else { *ib2 &= ~MTK_FOE_IB2_QID; *ib2 |= FIELD_PREP(MTK_FOE_IB2_QID, queue); *ib2 |= MTK_FOE_IB2_PSE_QOS; } return 0; } static bool mtk_flow_entry_match(struct mtk_eth *eth, struct mtk_flow_entry *entry, struct mtk_foe_entry *data) { int type, len; if ((data->ib1 ^ entry->data.ib1) & MTK_FOE_IB1_UDP) return false; type = mtk_get_ib1_pkt_type(eth, entry->data.ib1); if (type > MTK_PPE_PKT_TYPE_IPV4_DSLITE) len = offsetof(struct mtk_foe_entry, ipv6._rsv); else len = offsetof(struct mtk_foe_entry, ipv4.ib2); return !memcmp(&entry->data.data, &data->data, len - 4); } static void __mtk_foe_entry_clear(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { struct hlist_head *head; struct hlist_node *tmp; if (entry->type == MTK_FLOW_TYPE_L2) { rhashtable_remove_fast(&ppe->l2_flows, &entry->l2_node, mtk_flow_l2_ht_params); head = &entry->l2_flows; hlist_for_each_entry_safe(entry, tmp, head, l2_data.list) __mtk_foe_entry_clear(ppe, entry); return; } hlist_del_init(&entry->list); if (entry->hash != 0xffff) { struct mtk_foe_entry *hwe = mtk_foe_get_entry(ppe, entry->hash); hwe->ib1 &= ~MTK_FOE_IB1_STATE; hwe->ib1 |= FIELD_PREP(MTK_FOE_IB1_STATE, MTK_FOE_STATE_INVALID); dma_wmb(); mtk_ppe_cache_clear(ppe); if (ppe->accounting) { struct mtk_foe_accounting *acct; acct = ppe->acct_table + entry->hash * sizeof(*acct); acct->packets = 0; acct->bytes = 0; } } entry->hash = 0xffff; if (entry->type != MTK_FLOW_TYPE_L2_SUBFLOW) return; hlist_del_init(&entry->l2_data.list); kfree(entry); } static int __mtk_foe_entry_idle_time(struct mtk_ppe *ppe, u32 ib1) { u32 ib1_ts_mask = mtk_get_ib1_ts_mask(ppe->eth); u16 now = mtk_eth_timestamp(ppe->eth); u16 timestamp = ib1 & ib1_ts_mask; if (timestamp > now) return ib1_ts_mask + 1 - timestamp + now; else return now - timestamp; } static void mtk_flow_entry_update_l2(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { u32 ib1_ts_mask = mtk_get_ib1_ts_mask(ppe->eth); struct mtk_flow_entry *cur; struct mtk_foe_entry *hwe; struct hlist_node *tmp; int idle; idle = __mtk_foe_entry_idle_time(ppe, entry->data.ib1); hlist_for_each_entry_safe(cur, tmp, &entry->l2_flows, l2_data.list) { int cur_idle; u32 ib1; hwe = mtk_foe_get_entry(ppe, cur->hash); ib1 = READ_ONCE(hwe->ib1); if (FIELD_GET(MTK_FOE_IB1_STATE, ib1) != MTK_FOE_STATE_BIND) { cur->hash = 0xffff; __mtk_foe_entry_clear(ppe, cur); continue; } cur_idle = __mtk_foe_entry_idle_time(ppe, ib1); if (cur_idle >= idle) continue; idle = cur_idle; entry->data.ib1 &= ~ib1_ts_mask; entry->data.ib1 |= hwe->ib1 & ib1_ts_mask; } } static void mtk_flow_entry_update(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { struct mtk_foe_entry foe = {}; struct mtk_foe_entry *hwe; spin_lock_bh(&ppe_lock); if (entry->type == MTK_FLOW_TYPE_L2) { mtk_flow_entry_update_l2(ppe, entry); goto out; } if (entry->hash == 0xffff) goto out; hwe = mtk_foe_get_entry(ppe, entry->hash); memcpy(&foe, hwe, ppe->eth->soc->foe_entry_size); if (!mtk_flow_entry_match(ppe->eth, entry, &foe)) { entry->hash = 0xffff; goto out; } entry->data.ib1 = foe.ib1; out: spin_unlock_bh(&ppe_lock); } static void __mtk_foe_entry_commit(struct mtk_ppe *ppe, struct mtk_foe_entry *entry, u16 hash) { struct mtk_eth *eth = ppe->eth; u16 timestamp = mtk_eth_timestamp(eth); struct mtk_foe_entry *hwe; u32 val; if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) { entry->ib1 &= ~MTK_FOE_IB1_BIND_TIMESTAMP_V2; entry->ib1 |= FIELD_PREP(MTK_FOE_IB1_BIND_TIMESTAMP_V2, timestamp); } else { entry->ib1 &= ~MTK_FOE_IB1_BIND_TIMESTAMP; entry->ib1 |= FIELD_PREP(MTK_FOE_IB1_BIND_TIMESTAMP, timestamp); } hwe = mtk_foe_get_entry(ppe, hash); memcpy(&hwe->data, &entry->data, eth->soc->foe_entry_size - sizeof(hwe->ib1)); wmb(); hwe->ib1 = entry->ib1; if (ppe->accounting) { if (MTK_HAS_CAPS(eth->soc->caps, MTK_NETSYS_V2)) val = MTK_FOE_IB2_MIB_CNT_V2; else val = MTK_FOE_IB2_MIB_CNT; *mtk_foe_entry_ib2(eth, hwe) |= val; } dma_wmb(); mtk_ppe_cache_clear(ppe); } void mtk_foe_entry_clear(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { spin_lock_bh(&ppe_lock); __mtk_foe_entry_clear(ppe, entry); spin_unlock_bh(&ppe_lock); } static int mtk_foe_entry_commit_l2(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { struct mtk_flow_entry *prev; entry->type = MTK_FLOW_TYPE_L2; prev = rhashtable_lookup_get_insert_fast(&ppe->l2_flows, &entry->l2_node, mtk_flow_l2_ht_params); if (likely(!prev)) return 0; if (IS_ERR(prev)) return PTR_ERR(prev); return rhashtable_replace_fast(&ppe->l2_flows, &prev->l2_node, &entry->l2_node, mtk_flow_l2_ht_params); } int mtk_foe_entry_commit(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { const struct mtk_soc_data *soc = ppe->eth->soc; int type = mtk_get_ib1_pkt_type(ppe->eth, entry->data.ib1); u32 hash; if (type == MTK_PPE_PKT_TYPE_BRIDGE) return mtk_foe_entry_commit_l2(ppe, entry); hash = mtk_ppe_hash_entry(ppe->eth, &entry->data); entry->hash = 0xffff; spin_lock_bh(&ppe_lock); hlist_add_head(&entry->list, &ppe->foe_flow[hash / soc->hash_offset]); spin_unlock_bh(&ppe_lock); return 0; } static void mtk_foe_entry_commit_subflow(struct mtk_ppe *ppe, struct mtk_flow_entry *entry, u16 hash) { const struct mtk_soc_data *soc = ppe->eth->soc; struct mtk_flow_entry *flow_info; struct mtk_foe_entry foe = {}, *hwe; struct mtk_foe_mac_info *l2; u32 ib1_mask = mtk_get_ib1_pkt_type_mask(ppe->eth) | MTK_FOE_IB1_UDP; int type; flow_info = kzalloc(sizeof(*flow_info), GFP_ATOMIC); if (!flow_info) return; flow_info->l2_data.base_flow = entry; flow_info->type = MTK_FLOW_TYPE_L2_SUBFLOW; flow_info->hash = hash; hlist_add_head(&flow_info->list, &ppe->foe_flow[hash / soc->hash_offset]); hlist_add_head(&flow_info->l2_data.list, &entry->l2_flows); hwe = mtk_foe_get_entry(ppe, hash); memcpy(&foe, hwe, soc->foe_entry_size); foe.ib1 &= ib1_mask; foe.ib1 |= entry->data.ib1 & ~ib1_mask; l2 = mtk_foe_entry_l2(ppe->eth, &foe); memcpy(l2, &entry->data.bridge.l2, sizeof(*l2)); type = mtk_get_ib1_pkt_type(ppe->eth, foe.ib1); if (type == MTK_PPE_PKT_TYPE_IPV4_HNAPT) memcpy(&foe.ipv4.new, &foe.ipv4.orig, sizeof(foe.ipv4.new)); else if (type >= MTK_PPE_PKT_TYPE_IPV6_ROUTE_3T && l2->etype == ETH_P_IP) l2->etype = ETH_P_IPV6; *mtk_foe_entry_ib2(ppe->eth, &foe) = entry->data.bridge.ib2; __mtk_foe_entry_commit(ppe, &foe, hash); } void __mtk_ppe_check_skb(struct mtk_ppe *ppe, struct sk_buff *skb, u16 hash) { const struct mtk_soc_data *soc = ppe->eth->soc; struct hlist_head *head = &ppe->foe_flow[hash / soc->hash_offset]; struct mtk_foe_entry *hwe = mtk_foe_get_entry(ppe, hash); struct mtk_flow_entry *entry; struct mtk_foe_bridge key = {}; struct hlist_node *n; struct ethhdr *eh; bool found = false; u8 *tag; spin_lock_bh(&ppe_lock); if (FIELD_GET(MTK_FOE_IB1_STATE, hwe->ib1) == MTK_FOE_STATE_BIND) goto out; hlist_for_each_entry_safe(entry, n, head, list) { if (entry->type == MTK_FLOW_TYPE_L2_SUBFLOW) { if (unlikely(FIELD_GET(MTK_FOE_IB1_STATE, hwe->ib1) == MTK_FOE_STATE_BIND)) continue; entry->hash = 0xffff; __mtk_foe_entry_clear(ppe, entry); continue; } if (found || !mtk_flow_entry_match(ppe->eth, entry, hwe)) { if (entry->hash != 0xffff) entry->hash = 0xffff; continue; } entry->hash = hash; __mtk_foe_entry_commit(ppe, &entry->data, hash); found = true; } if (found) goto out; eh = eth_hdr(skb); ether_addr_copy(key.dest_mac, eh->h_dest); ether_addr_copy(key.src_mac, eh->h_source); tag = skb->data - 2; key.vlan = 0; switch (skb->protocol) { #if IS_ENABLED(CONFIG_NET_DSA) case htons(ETH_P_XDSA): if (!netdev_uses_dsa(skb->dev) || skb->dev->dsa_ptr->tag_ops->proto != DSA_TAG_PROTO_MTK) goto out; if (!skb_metadata_dst(skb)) tag += 4; if (get_unaligned_be16(tag) != ETH_P_8021Q) break; fallthrough; #endif case htons(ETH_P_8021Q): key.vlan = get_unaligned_be16(tag + 2) & VLAN_VID_MASK; break; default: break; } entry = rhashtable_lookup_fast(&ppe->l2_flows, &key, mtk_flow_l2_ht_params); if (!entry) goto out; mtk_foe_entry_commit_subflow(ppe, entry, hash); out: spin_unlock_bh(&ppe_lock); } int mtk_foe_entry_idle_time(struct mtk_ppe *ppe, struct mtk_flow_entry *entry) { mtk_flow_entry_update(ppe, entry); return __mtk_foe_entry_idle_time(ppe, entry->data.ib1); } int mtk_ppe_prepare_reset(struct mtk_ppe *ppe) { if (!ppe) return -EINVAL; /* disable KA */ ppe_clear(ppe, MTK_PPE_TB_CFG, MTK_PPE_TB_CFG_KEEPALIVE); ppe_clear(ppe, MTK_PPE_BIND_LMT1, MTK_PPE_NTU_KEEPALIVE); ppe_w32(ppe, MTK_PPE_KEEPALIVE, 0); usleep_range(10000, 11000); /* set KA timer to maximum */ ppe_set(ppe, MTK_PPE_BIND_LMT1, MTK_PPE_NTU_KEEPALIVE); ppe_w32(ppe, MTK_PPE_KEEPALIVE, 0xffffffff); /* set KA tick select */ ppe_set(ppe, MTK_PPE_TB_CFG, MTK_PPE_TB_TICK_SEL); ppe_set(ppe, MTK_PPE_TB_CFG, MTK_PPE_TB_CFG_KEEPALIVE); usleep_range(10000, 11000); /* disable scan mode */ ppe_clear(ppe, MTK_PPE_TB_CFG, MTK_PPE_TB_CFG_SCAN_MODE); usleep_range(10000, 11000); return mtk_ppe_wait_busy(ppe); } struct mtk_foe_accounting *mtk_foe_entry_get_mib(struct mtk_ppe *ppe, u32 index, struct mtk_foe_accounting *diff) { struct mtk_foe_accounting *acct; int size = sizeof(struct mtk_foe_accounting); u64 bytes, packets; if (!ppe->accounting) return NULL; if (mtk_mib_entry_read(ppe, index, &bytes, &packets)) return NULL; acct = ppe->acct_table + index * size; acct->bytes += bytes; acct->packets += packets; if (diff) { diff->bytes = bytes; diff->packets = packets; } return acct; } struct mtk_ppe *mtk_ppe_init(struct mtk_eth *eth, void __iomem *base, int index) { bool accounting = eth->soc->has_accounting; const struct mtk_soc_data *soc = eth->soc; struct mtk_foe_accounting *acct; struct device *dev = eth->dev; struct mtk_mib_entry *mib; struct mtk_ppe *ppe; u32 foe_flow_size; void *foe; ppe = devm_kzalloc(dev, sizeof(*ppe), GFP_KERNEL); if (!ppe) return NULL; rhashtable_init(&ppe->l2_flows, &mtk_flow_l2_ht_params); /* need to allocate a separate device, since it PPE DMA access is * not coherent. */ ppe->base = base; ppe->eth = eth; ppe->dev = dev; ppe->version = eth->soc->offload_version; ppe->accounting = accounting; foe = dmam_alloc_coherent(ppe->dev, MTK_PPE_ENTRIES * soc->foe_entry_size, &ppe->foe_phys, GFP_KERNEL); if (!foe) goto err_free_l2_flows; ppe->foe_table = foe; foe_flow_size = (MTK_PPE_ENTRIES / soc->hash_offset) * sizeof(*ppe->foe_flow); ppe->foe_flow = devm_kzalloc(dev, foe_flow_size, GFP_KERNEL); if (!ppe->foe_flow) goto err_free_l2_flows; if (accounting) { mib = dmam_alloc_coherent(ppe->dev, MTK_PPE_ENTRIES * sizeof(*mib), &ppe->mib_phys, GFP_KERNEL); if (!mib) return NULL; ppe->mib_table = mib; acct = devm_kzalloc(dev, MTK_PPE_ENTRIES * sizeof(*acct), GFP_KERNEL); if (!acct) return NULL; ppe->acct_table = acct; } mtk_ppe_debugfs_init(ppe, index); return ppe; err_free_l2_flows: rhashtable_destroy(&ppe->l2_flows); return NULL; } void mtk_ppe_deinit(struct mtk_eth *eth) { int i; for (i = 0; i < ARRAY_SIZE(eth->ppe); i++) { if (!eth->ppe[i]) return; rhashtable_destroy(ð->ppe[i]->l2_flows); } } static void mtk_ppe_init_foe_table(struct mtk_ppe *ppe) { static const u8 skip[] = { 12, 25, 38, 51, 76, 89, 102 }; int i, k; memset(ppe->foe_table, 0, MTK_PPE_ENTRIES * ppe->eth->soc->foe_entry_size); if (!IS_ENABLED(CONFIG_SOC_MT7621)) return; /* skip all entries that cross the 1024 byte boundary */ for (i = 0; i < MTK_PPE_ENTRIES; i += 128) { for (k = 0; k < ARRAY_SIZE(skip); k++) { struct mtk_foe_entry *hwe; hwe = mtk_foe_get_entry(ppe, i + skip[k]); hwe->ib1 |= MTK_FOE_IB1_STATIC; } } } void mtk_ppe_start(struct mtk_ppe *ppe) { u32 val; if (!ppe) return; mtk_ppe_init_foe_table(ppe); ppe_w32(ppe, MTK_PPE_TB_BASE, ppe->foe_phys); val = MTK_PPE_TB_CFG_ENTRY_80B | MTK_PPE_TB_CFG_AGE_NON_L4 | MTK_PPE_TB_CFG_AGE_UNBIND | MTK_PPE_TB_CFG_AGE_TCP | MTK_PPE_TB_CFG_AGE_UDP | MTK_PPE_TB_CFG_AGE_TCP_FIN | FIELD_PREP(MTK_PPE_TB_CFG_SEARCH_MISS, MTK_PPE_SEARCH_MISS_ACTION_FORWARD_BUILD) | FIELD_PREP(MTK_PPE_TB_CFG_KEEPALIVE, MTK_PPE_KEEPALIVE_DISABLE) | FIELD_PREP(MTK_PPE_TB_CFG_HASH_MODE, 1) | FIELD_PREP(MTK_PPE_TB_CFG_SCAN_MODE, MTK_PPE_SCAN_MODE_KEEPALIVE_AGE) | FIELD_PREP(MTK_PPE_TB_CFG_ENTRY_NUM, MTK_PPE_ENTRIES_SHIFT); if (MTK_HAS_CAPS(ppe->eth->soc->caps, MTK_NETSYS_V2)) val |= MTK_PPE_TB_CFG_INFO_SEL; ppe_w32(ppe, MTK_PPE_TB_CFG, val); ppe_w32(ppe, MTK_PPE_IP_PROTO_CHK, MTK_PPE_IP_PROTO_CHK_IPV4 | MTK_PPE_IP_PROTO_CHK_IPV6); mtk_ppe_cache_enable(ppe, true); val = MTK_PPE_FLOW_CFG_IP6_3T_ROUTE | MTK_PPE_FLOW_CFG_IP6_5T_ROUTE | MTK_PPE_FLOW_CFG_IP6_6RD | MTK_PPE_FLOW_CFG_IP4_NAT | MTK_PPE_FLOW_CFG_IP4_NAPT | MTK_PPE_FLOW_CFG_IP4_DSLITE | MTK_PPE_FLOW_CFG_IP4_NAT_FRAG; if (MTK_HAS_CAPS(ppe->eth->soc->caps, MTK_NETSYS_V2)) val |= MTK_PPE_MD_TOAP_BYP_CRSN0 | MTK_PPE_MD_TOAP_BYP_CRSN1 | MTK_PPE_MD_TOAP_BYP_CRSN2 | MTK_PPE_FLOW_CFG_IP4_HASH_GRE_KEY; else val |= MTK_PPE_FLOW_CFG_IP4_TCP_FRAG | MTK_PPE_FLOW_CFG_IP4_UDP_FRAG; ppe_w32(ppe, MTK_PPE_FLOW_CFG, val); val = FIELD_PREP(MTK_PPE_UNBIND_AGE_MIN_PACKETS, 1000) | FIELD_PREP(MTK_PPE_UNBIND_AGE_DELTA, 3); ppe_w32(ppe, MTK_PPE_UNBIND_AGE, val); val = FIELD_PREP(MTK_PPE_BIND_AGE0_DELTA_UDP, 12) | FIELD_PREP(MTK_PPE_BIND_AGE0_DELTA_NON_L4, 1); ppe_w32(ppe, MTK_PPE_BIND_AGE0, val); val = FIELD_PREP(MTK_PPE_BIND_AGE1_DELTA_TCP_FIN, 1) | FIELD_PREP(MTK_PPE_BIND_AGE1_DELTA_TCP, 7); ppe_w32(ppe, MTK_PPE_BIND_AGE1, val); val = MTK_PPE_BIND_LIMIT0_QUARTER | MTK_PPE_BIND_LIMIT0_HALF; ppe_w32(ppe, MTK_PPE_BIND_LIMIT0, val); val = MTK_PPE_BIND_LIMIT1_FULL | FIELD_PREP(MTK_PPE_BIND_LIMIT1_NON_L4, 1); ppe_w32(ppe, MTK_PPE_BIND_LIMIT1, val); val = FIELD_PREP(MTK_PPE_BIND_RATE_BIND, 30) | FIELD_PREP(MTK_PPE_BIND_RATE_PREBIND, 1); ppe_w32(ppe, MTK_PPE_BIND_RATE, val); /* enable PPE */ val = MTK_PPE_GLO_CFG_EN | MTK_PPE_GLO_CFG_IP4_L4_CS_DROP | MTK_PPE_GLO_CFG_IP4_CS_DROP | MTK_PPE_GLO_CFG_FLOW_DROP_UPDATE; ppe_w32(ppe, MTK_PPE_GLO_CFG, val); ppe_w32(ppe, MTK_PPE_DEFAULT_CPU_PORT, 0); if (MTK_HAS_CAPS(ppe->eth->soc->caps, MTK_NETSYS_V2)) { ppe_w32(ppe, MTK_PPE_DEFAULT_CPU_PORT1, 0xcb777); ppe_w32(ppe, MTK_PPE_SBW_CTRL, 0x7f); } if (ppe->accounting && ppe->mib_phys) { ppe_w32(ppe, MTK_PPE_MIB_TB_BASE, ppe->mib_phys); ppe_m32(ppe, MTK_PPE_MIB_CFG, MTK_PPE_MIB_CFG_EN, MTK_PPE_MIB_CFG_EN); ppe_m32(ppe, MTK_PPE_MIB_CFG, MTK_PPE_MIB_CFG_RD_CLR, MTK_PPE_MIB_CFG_RD_CLR); ppe_m32(ppe, MTK_PPE_MIB_CACHE_CTL, MTK_PPE_MIB_CACHE_CTL_EN, MTK_PPE_MIB_CFG_RD_CLR); } } int mtk_ppe_stop(struct mtk_ppe *ppe) { u32 val; int i; if (!ppe) return 0; for (i = 0; i < MTK_PPE_ENTRIES; i++) { struct mtk_foe_entry *hwe = mtk_foe_get_entry(ppe, i); hwe->ib1 = FIELD_PREP(MTK_FOE_IB1_STATE, MTK_FOE_STATE_INVALID); } mtk_ppe_cache_enable(ppe, false); /* disable offload engine */ ppe_clear(ppe, MTK_PPE_GLO_CFG, MTK_PPE_GLO_CFG_EN); ppe_w32(ppe, MTK_PPE_FLOW_CFG, 0); /* disable aging */ val = MTK_PPE_TB_CFG_AGE_NON_L4 | MTK_PPE_TB_CFG_AGE_UNBIND | MTK_PPE_TB_CFG_AGE_TCP | MTK_PPE_TB_CFG_AGE_UDP | MTK_PPE_TB_CFG_AGE_TCP_FIN; ppe_clear(ppe, MTK_PPE_TB_CFG, val); return mtk_ppe_wait_busy(ppe); }
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