Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jakub Kiciński | 2110 | 100.00% | 19 | 100.00% |
Total | 2110 | 19 |
// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) /* Copyright (C) 2018 Netronome Systems, Inc. */ #include <linux/bitops.h> #include <linux/kernel.h> #include <linux/log2.h> #include "../nfpcore/nfp_cpp.h" #include "../nfpcore/nfp_nffw.h" #include "../nfp_app.h" #include "../nfp_abi.h" #include "../nfp_main.h" #include "../nfp_net.h" #include "main.h" #define NFP_NUM_PRIOS_SYM_NAME "_abi_pci_dscp_num_prio_%u" #define NFP_NUM_BANDS_SYM_NAME "_abi_pci_dscp_num_band_%u" #define NFP_ACT_MASK_SYM_NAME "_abi_nfd_out_q_actions_%u" #define NFP_RED_SUPPORT_SYM_NAME "_abi_nfd_out_red_offload_%u" #define NFP_QLVL_SYM_NAME "_abi_nfd_out_q_lvls_%u%s" #define NFP_QLVL_STRIDE 16 #define NFP_QLVL_BLOG_BYTES 0 #define NFP_QLVL_BLOG_PKTS 4 #define NFP_QLVL_THRS 8 #define NFP_QLVL_ACT 12 #define NFP_QMSTAT_SYM_NAME "_abi_nfdqm%u_stats%s" #define NFP_QMSTAT_STRIDE 32 #define NFP_QMSTAT_NON_STO 0 #define NFP_QMSTAT_STO 8 #define NFP_QMSTAT_DROP 16 #define NFP_QMSTAT_ECN 24 #define NFP_Q_STAT_SYM_NAME "_abi_nfd_rxq_stats%u%s" #define NFP_Q_STAT_STRIDE 16 #define NFP_Q_STAT_PKTS 0 #define NFP_Q_STAT_BYTES 8 #define NFP_NET_ABM_MBOX_CMD NFP_NET_CFG_MBOX_SIMPLE_CMD #define NFP_NET_ABM_MBOX_RET NFP_NET_CFG_MBOX_SIMPLE_RET #define NFP_NET_ABM_MBOX_DATALEN NFP_NET_CFG_MBOX_SIMPLE_VAL #define NFP_NET_ABM_MBOX_RESERVED (NFP_NET_CFG_MBOX_SIMPLE_VAL + 4) #define NFP_NET_ABM_MBOX_DATA (NFP_NET_CFG_MBOX_SIMPLE_VAL + 8) static int nfp_abm_ctrl_stat(struct nfp_abm_link *alink, const struct nfp_rtsym *sym, unsigned int stride, unsigned int offset, unsigned int band, unsigned int queue, bool is_u64, u64 *res) { struct nfp_cpp *cpp = alink->abm->app->cpp; u64 val, sym_offset; unsigned int qid; u32 val32; int err; qid = band * NFP_NET_MAX_RX_RINGS + alink->queue_base + queue; sym_offset = qid * stride + offset; if (is_u64) err = __nfp_rtsym_readq(cpp, sym, 3, 0, sym_offset, &val); else err = __nfp_rtsym_readl(cpp, sym, 3, 0, sym_offset, &val32); if (err) { nfp_err(cpp, "RED offload reading stat failed on vNIC %d band %d queue %d (+ %d)\n", alink->id, band, queue, alink->queue_base); return err; } *res = is_u64 ? val : val32; return 0; } int __nfp_abm_ctrl_set_q_lvl(struct nfp_abm *abm, unsigned int id, u32 val) { struct nfp_cpp *cpp = abm->app->cpp; u64 sym_offset; int err; __clear_bit(id, abm->threshold_undef); if (abm->thresholds[id] == val) return 0; sym_offset = id * NFP_QLVL_STRIDE + NFP_QLVL_THRS; err = __nfp_rtsym_writel(cpp, abm->q_lvls, 4, 0, sym_offset, val); if (err) { nfp_err(cpp, "RED offload setting level failed on subqueue %d\n", id); return err; } abm->thresholds[id] = val; return 0; } int nfp_abm_ctrl_set_q_lvl(struct nfp_abm_link *alink, unsigned int band, unsigned int queue, u32 val) { unsigned int threshold; threshold = band * NFP_NET_MAX_RX_RINGS + alink->queue_base + queue; return __nfp_abm_ctrl_set_q_lvl(alink->abm, threshold, val); } int __nfp_abm_ctrl_set_q_act(struct nfp_abm *abm, unsigned int id, enum nfp_abm_q_action act) { struct nfp_cpp *cpp = abm->app->cpp; u64 sym_offset; int err; if (abm->actions[id] == act) return 0; sym_offset = id * NFP_QLVL_STRIDE + NFP_QLVL_ACT; err = __nfp_rtsym_writel(cpp, abm->q_lvls, 4, 0, sym_offset, act); if (err) { nfp_err(cpp, "RED offload setting action failed on subqueue %d\n", id); return err; } abm->actions[id] = act; return 0; } int nfp_abm_ctrl_set_q_act(struct nfp_abm_link *alink, unsigned int band, unsigned int queue, enum nfp_abm_q_action act) { unsigned int qid; qid = band * NFP_NET_MAX_RX_RINGS + alink->queue_base + queue; return __nfp_abm_ctrl_set_q_act(alink->abm, qid, act); } u64 nfp_abm_ctrl_stat_non_sto(struct nfp_abm_link *alink, unsigned int queue) { unsigned int band; u64 val, sum = 0; for (band = 0; band < alink->abm->num_bands; band++) { if (nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_NON_STO, band, queue, true, &val)) return 0; sum += val; } return sum; } u64 nfp_abm_ctrl_stat_sto(struct nfp_abm_link *alink, unsigned int queue) { unsigned int band; u64 val, sum = 0; for (band = 0; band < alink->abm->num_bands; band++) { if (nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_STO, band, queue, true, &val)) return 0; sum += val; } return sum; } static int nfp_abm_ctrl_stat_basic(struct nfp_abm_link *alink, unsigned int band, unsigned int queue, unsigned int off, u64 *val) { if (!nfp_abm_has_prio(alink->abm)) { if (!band) { unsigned int id = alink->queue_base + queue; *val = nn_readq(alink->vnic, NFP_NET_CFG_RXR_STATS(id) + off); } else { *val = 0; } return 0; } else { return nfp_abm_ctrl_stat(alink, alink->abm->q_stats, NFP_Q_STAT_STRIDE, off, band, queue, true, val); } } int nfp_abm_ctrl_read_q_stats(struct nfp_abm_link *alink, unsigned int band, unsigned int queue, struct nfp_alink_stats *stats) { int err; err = nfp_abm_ctrl_stat_basic(alink, band, queue, NFP_Q_STAT_PKTS, &stats->tx_pkts); if (err) return err; err = nfp_abm_ctrl_stat_basic(alink, band, queue, NFP_Q_STAT_BYTES, &stats->tx_bytes); if (err) return err; err = nfp_abm_ctrl_stat(alink, alink->abm->q_lvls, NFP_QLVL_STRIDE, NFP_QLVL_BLOG_BYTES, band, queue, false, &stats->backlog_bytes); if (err) return err; err = nfp_abm_ctrl_stat(alink, alink->abm->q_lvls, NFP_QLVL_STRIDE, NFP_QLVL_BLOG_PKTS, band, queue, false, &stats->backlog_pkts); if (err) return err; err = nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_DROP, band, queue, true, &stats->drops); if (err) return err; return nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_ECN, band, queue, true, &stats->overlimits); } int nfp_abm_ctrl_read_q_xstats(struct nfp_abm_link *alink, unsigned int band, unsigned int queue, struct nfp_alink_xstats *xstats) { int err; err = nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_DROP, band, queue, true, &xstats->pdrop); if (err) return err; return nfp_abm_ctrl_stat(alink, alink->abm->qm_stats, NFP_QMSTAT_STRIDE, NFP_QMSTAT_ECN, band, queue, true, &xstats->ecn_marked); } int nfp_abm_ctrl_qm_enable(struct nfp_abm *abm) { return nfp_mbox_cmd(abm->app->pf, NFP_MBOX_PCIE_ABM_ENABLE, NULL, 0, NULL, 0); } int nfp_abm_ctrl_qm_disable(struct nfp_abm *abm) { return nfp_mbox_cmd(abm->app->pf, NFP_MBOX_PCIE_ABM_DISABLE, NULL, 0, NULL, 0); } int nfp_abm_ctrl_prio_map_update(struct nfp_abm_link *alink, u32 *packed) { struct nfp_net *nn = alink->vnic; unsigned int i; int err; /* Write data_len and wipe reserved */ nn_writeq(nn, nn->tlv_caps.mbox_off + NFP_NET_ABM_MBOX_DATALEN, alink->abm->prio_map_len); for (i = 0; i < alink->abm->prio_map_len; i += sizeof(u32)) nn_writel(nn, nn->tlv_caps.mbox_off + NFP_NET_ABM_MBOX_DATA + i, packed[i / sizeof(u32)]); err = nfp_net_reconfig_mbox(nn, NFP_NET_CFG_MBOX_CMD_PCI_DSCP_PRIOMAP_SET); if (err) nfp_err(alink->abm->app->cpp, "setting DSCP -> VQ map failed with error %d\n", err); return err; } static int nfp_abm_ctrl_prio_check_params(struct nfp_abm_link *alink) { struct nfp_abm *abm = alink->abm; struct nfp_net *nn = alink->vnic; unsigned int min_mbox_sz; if (!nfp_abm_has_prio(alink->abm)) return 0; min_mbox_sz = NFP_NET_ABM_MBOX_DATA + alink->abm->prio_map_len; if (nn->tlv_caps.mbox_len < min_mbox_sz) { nfp_err(abm->app->pf->cpp, "vNIC mailbox too small for prio offload: %u, need: %u\n", nn->tlv_caps.mbox_len, min_mbox_sz); return -EINVAL; } return 0; } int nfp_abm_ctrl_read_params(struct nfp_abm_link *alink) { alink->queue_base = nn_readl(alink->vnic, NFP_NET_CFG_START_RXQ); alink->queue_base /= alink->vnic->stride_rx; return nfp_abm_ctrl_prio_check_params(alink); } static unsigned int nfp_abm_ctrl_prio_map_size(struct nfp_abm *abm) { unsigned int size; size = roundup_pow_of_two(order_base_2(abm->num_bands)); size = DIV_ROUND_UP(size * abm->num_prios, BITS_PER_BYTE); size = round_up(size, sizeof(u32)); return size; } static const struct nfp_rtsym * nfp_abm_ctrl_find_rtsym(struct nfp_pf *pf, const char *name, unsigned int size) { const struct nfp_rtsym *sym; sym = nfp_rtsym_lookup(pf->rtbl, name); if (!sym) { nfp_err(pf->cpp, "Symbol '%s' not found\n", name); return ERR_PTR(-ENOENT); } if (nfp_rtsym_size(sym) != size) { nfp_err(pf->cpp, "Symbol '%s' wrong size: expected %u got %llu\n", name, size, nfp_rtsym_size(sym)); return ERR_PTR(-EINVAL); } return sym; } static const struct nfp_rtsym * nfp_abm_ctrl_find_q_rtsym(struct nfp_abm *abm, const char *name_fmt, size_t size) { char pf_symbol[64]; size = array3_size(size, abm->num_bands, NFP_NET_MAX_RX_RINGS); snprintf(pf_symbol, sizeof(pf_symbol), name_fmt, abm->pf_id, nfp_abm_has_prio(abm) ? "_per_band" : ""); return nfp_abm_ctrl_find_rtsym(abm->app->pf, pf_symbol, size); } int nfp_abm_ctrl_find_addrs(struct nfp_abm *abm) { struct nfp_pf *pf = abm->app->pf; const struct nfp_rtsym *sym; int res; abm->pf_id = nfp_cppcore_pcie_unit(pf->cpp); /* Check if Qdisc offloads are supported */ res = nfp_pf_rtsym_read_optional(pf, NFP_RED_SUPPORT_SYM_NAME, 1); if (res < 0) return res; abm->red_support = res; /* Read count of prios and prio bands */ res = nfp_pf_rtsym_read_optional(pf, NFP_NUM_BANDS_SYM_NAME, 1); if (res < 0) return res; abm->num_bands = res; res = nfp_pf_rtsym_read_optional(pf, NFP_NUM_PRIOS_SYM_NAME, 1); if (res < 0) return res; abm->num_prios = res; /* Read available actions */ res = nfp_pf_rtsym_read_optional(pf, NFP_ACT_MASK_SYM_NAME, BIT(NFP_ABM_ACT_MARK_DROP)); if (res < 0) return res; abm->action_mask = res; abm->prio_map_len = nfp_abm_ctrl_prio_map_size(abm); abm->dscp_mask = GENMASK(7, 8 - order_base_2(abm->num_prios)); /* Check values are sane, U16_MAX is arbitrarily chosen as max */ if (!is_power_of_2(abm->num_bands) || !is_power_of_2(abm->num_prios) || abm->num_bands > U16_MAX || abm->num_prios > U16_MAX || (abm->num_bands == 1) != (abm->num_prios == 1)) { nfp_err(pf->cpp, "invalid priomap description num bands: %u and num prios: %u\n", abm->num_bands, abm->num_prios); return -EINVAL; } /* Find level and stat symbols */ if (!abm->red_support) return 0; sym = nfp_abm_ctrl_find_q_rtsym(abm, NFP_QLVL_SYM_NAME, NFP_QLVL_STRIDE); if (IS_ERR(sym)) return PTR_ERR(sym); abm->q_lvls = sym; sym = nfp_abm_ctrl_find_q_rtsym(abm, NFP_QMSTAT_SYM_NAME, NFP_QMSTAT_STRIDE); if (IS_ERR(sym)) return PTR_ERR(sym); abm->qm_stats = sym; if (nfp_abm_has_prio(abm)) { sym = nfp_abm_ctrl_find_q_rtsym(abm, NFP_Q_STAT_SYM_NAME, NFP_Q_STAT_STRIDE); if (IS_ERR(sym)) return PTR_ERR(sym); abm->q_stats = sym; } return 0; }
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