Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Linu Cherian | 2062 | 25.45% | 8 | 21.62% |
Christina Jacob | 1557 | 19.22% | 4 | 10.81% |
Sunil Kumar Kori | 1200 | 14.81% | 1 | 2.70% |
Hariprasad Kelam | 990 | 12.22% | 6 | 16.22% |
Geetha Sowjanya | 733 | 9.05% | 3 | 8.11% |
Sunil Goutham | 642 | 7.92% | 4 | 10.81% |
Vidhya Raman | 337 | 4.16% | 1 | 2.70% |
Zyta Szpak | 148 | 1.83% | 1 | 2.70% |
Arnd Bergmann | 145 | 1.79% | 1 | 2.70% |
Subbaraya Sundeep | 116 | 1.43% | 2 | 5.41% |
Felix Manlunas | 59 | 0.73% | 1 | 2.70% |
Rakesh Babu | 47 | 0.58% | 1 | 2.70% |
Colin Ian King | 28 | 0.35% | 1 | 2.70% |
Christophe Jaillet | 23 | 0.28% | 2 | 5.41% |
Dan Carpenter | 16 | 0.20% | 1 | 2.70% |
Total | 8103 | 37 |
// SPDX-License-Identifier: GPL-2.0 /* Marvell OcteonTx2 CGX driver * * Copyright (C) 2018 Marvell. * */ #include <linux/acpi.h> #include <linux/module.h> #include <linux/interrupt.h> #include <linux/pci.h> #include <linux/netdevice.h> #include <linux/etherdevice.h> #include <linux/ethtool.h> #include <linux/phy.h> #include <linux/of.h> #include <linux/of_mdio.h> #include <linux/of_net.h> #include "cgx.h" #include "rvu.h" #include "lmac_common.h" #define DRV_NAME "Marvell-CGX/RPM" #define DRV_STRING "Marvell CGX/RPM Driver" static LIST_HEAD(cgx_list); /* Convert firmware speed encoding to user format(Mbps) */ static const u32 cgx_speed_mbps[CGX_LINK_SPEED_MAX] = { [CGX_LINK_NONE] = 0, [CGX_LINK_10M] = 10, [CGX_LINK_100M] = 100, [CGX_LINK_1G] = 1000, [CGX_LINK_2HG] = 2500, [CGX_LINK_5G] = 5000, [CGX_LINK_10G] = 10000, [CGX_LINK_20G] = 20000, [CGX_LINK_25G] = 25000, [CGX_LINK_40G] = 40000, [CGX_LINK_50G] = 50000, [CGX_LINK_80G] = 80000, [CGX_LINK_100G] = 100000, }; /* Convert firmware lmac type encoding to string */ static const char *cgx_lmactype_string[LMAC_MODE_MAX] = { [LMAC_MODE_SGMII] = "SGMII", [LMAC_MODE_XAUI] = "XAUI", [LMAC_MODE_RXAUI] = "RXAUI", [LMAC_MODE_10G_R] = "10G_R", [LMAC_MODE_40G_R] = "40G_R", [LMAC_MODE_QSGMII] = "QSGMII", [LMAC_MODE_25G_R] = "25G_R", [LMAC_MODE_50G_R] = "50G_R", [LMAC_MODE_100G_R] = "100G_R", [LMAC_MODE_USXGMII] = "USXGMII", }; /* CGX PHY management internal APIs */ static int cgx_fwi_link_change(struct cgx *cgx, int lmac_id, bool en); /* Supported devices */ static const struct pci_device_id cgx_id_table[] = { { PCI_DEVICE(PCI_VENDOR_ID_CAVIUM, PCI_DEVID_OCTEONTX2_CGX) }, { PCI_DEVICE(PCI_VENDOR_ID_CAVIUM, PCI_DEVID_CN10K_RPM) }, { 0, } /* end of table */ }; MODULE_DEVICE_TABLE(pci, cgx_id_table); static bool is_dev_rpm(void *cgxd) { struct cgx *cgx = cgxd; return (cgx->pdev->device == PCI_DEVID_CN10K_RPM); } bool is_lmac_valid(struct cgx *cgx, int lmac_id) { if (!cgx || lmac_id < 0 || lmac_id >= MAX_LMAC_PER_CGX) return false; return test_bit(lmac_id, &cgx->lmac_bmap); } /* Helper function to get sequential index * given the enabled LMAC of a CGX */ static int get_sequence_id_of_lmac(struct cgx *cgx, int lmac_id) { int tmp, id = 0; for_each_set_bit(tmp, &cgx->lmac_bmap, MAX_LMAC_PER_CGX) { if (tmp == lmac_id) break; id++; } return id; } struct mac_ops *get_mac_ops(void *cgxd) { if (!cgxd) return cgxd; return ((struct cgx *)cgxd)->mac_ops; } void cgx_write(struct cgx *cgx, u64 lmac, u64 offset, u64 val) { writeq(val, cgx->reg_base + (lmac << cgx->mac_ops->lmac_offset) + offset); } u64 cgx_read(struct cgx *cgx, u64 lmac, u64 offset) { return readq(cgx->reg_base + (lmac << cgx->mac_ops->lmac_offset) + offset); } struct lmac *lmac_pdata(u8 lmac_id, struct cgx *cgx) { if (!cgx || lmac_id >= MAX_LMAC_PER_CGX) return NULL; return cgx->lmac_idmap[lmac_id]; } int cgx_get_cgxcnt_max(void) { struct cgx *cgx_dev; int idmax = -ENODEV; list_for_each_entry(cgx_dev, &cgx_list, cgx_list) if (cgx_dev->cgx_id > idmax) idmax = cgx_dev->cgx_id; if (idmax < 0) return 0; return idmax + 1; } int cgx_get_lmac_cnt(void *cgxd) { struct cgx *cgx = cgxd; if (!cgx) return -ENODEV; return cgx->lmac_count; } void *cgx_get_pdata(int cgx_id) { struct cgx *cgx_dev; list_for_each_entry(cgx_dev, &cgx_list, cgx_list) { if (cgx_dev->cgx_id == cgx_id) return cgx_dev; } return NULL; } void cgx_lmac_write(int cgx_id, int lmac_id, u64 offset, u64 val) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); cgx_write(cgx_dev, lmac_id, offset, val); } u64 cgx_lmac_read(int cgx_id, int lmac_id, u64 offset) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); return cgx_read(cgx_dev, lmac_id, offset); } int cgx_get_cgxid(void *cgxd) { struct cgx *cgx = cgxd; if (!cgx) return -EINVAL; return cgx->cgx_id; } u8 cgx_lmac_get_p2x(int cgx_id, int lmac_id) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); u64 cfg; cfg = cgx_read(cgx_dev, lmac_id, CGXX_CMRX_CFG); return (cfg & CMR_P2X_SEL_MASK) >> CMR_P2X_SEL_SHIFT; } /* Ensure the required lock for event queue(where asynchronous events are * posted) is acquired before calling this API. Else an asynchronous event(with * latest link status) can reach the destination before this function returns * and could make the link status appear wrong. */ int cgx_get_link_info(void *cgxd, int lmac_id, struct cgx_link_user_info *linfo) { struct lmac *lmac = lmac_pdata(lmac_id, cgxd); if (!lmac) return -ENODEV; *linfo = lmac->link_info; return 0; } static u64 mac2u64 (u8 *mac_addr) { u64 mac = 0; int index; for (index = ETH_ALEN - 1; index >= 0; index--) mac |= ((u64)*mac_addr++) << (8 * index); return mac; } static void cfg2mac(u64 cfg, u8 *mac_addr) { int i, index = 0; for (i = ETH_ALEN - 1; i >= 0; i--, index++) mac_addr[i] = (cfg >> (8 * index)) & 0xFF; } int cgx_lmac_addr_set(u8 cgx_id, u8 lmac_id, u8 *mac_addr) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); struct mac_ops *mac_ops; int index, id; u64 cfg; /* access mac_ops to know csr_offset */ mac_ops = cgx_dev->mac_ops; /* copy 6bytes from macaddr */ /* memcpy(&cfg, mac_addr, 6); */ cfg = mac2u64 (mac_addr); id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max; cgx_write(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8)), cfg | CGX_DMAC_CAM_ADDR_ENABLE | ((u64)lmac_id << 49)); cfg = cgx_read(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg |= (CGX_DMAC_CTL0_CAM_ENABLE | CGX_DMAC_BCAST_MODE | CGX_DMAC_MCAST_MODE); cgx_write(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); return 0; } u64 cgx_read_dmac_ctrl(void *cgxd, int lmac_id) { struct mac_ops *mac_ops; struct cgx *cgx = cgxd; if (!cgxd || !is_lmac_valid(cgxd, lmac_id)) return 0; cgx = cgxd; /* Get mac_ops to know csr offset */ mac_ops = cgx->mac_ops; return cgx_read(cgxd, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); } u64 cgx_read_dmac_entry(void *cgxd, int index) { struct mac_ops *mac_ops; struct cgx *cgx; if (!cgxd) return 0; cgx = cgxd; mac_ops = cgx->mac_ops; return cgx_read(cgx, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 8))); } int cgx_lmac_addr_add(u8 cgx_id, u8 lmac_id, u8 *mac_addr) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); struct mac_ops *mac_ops; int index, idx; u64 cfg = 0; int id; if (!lmac) return -ENODEV; mac_ops = cgx_dev->mac_ops; /* Get available index where entry is to be installed */ idx = rvu_alloc_rsrc(&lmac->mac_to_index_bmap); if (idx < 0) return idx; id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max + idx; cfg = mac2u64 (mac_addr); cfg |= CGX_DMAC_CAM_ADDR_ENABLE; cfg |= ((u64)lmac_id << 49); cgx_write(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8)), cfg); cfg = cgx_read(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg |= (CGX_DMAC_BCAST_MODE | CGX_DMAC_CAM_ACCEPT); if (is_multicast_ether_addr(mac_addr)) { cfg &= ~GENMASK_ULL(2, 1); cfg |= CGX_DMAC_MCAST_MODE_CAM; lmac->mcast_filters_count++; } else if (!lmac->mcast_filters_count) { cfg |= CGX_DMAC_MCAST_MODE; } cgx_write(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); return idx; } int cgx_lmac_addr_reset(u8 cgx_id, u8 lmac_id) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); struct mac_ops *mac_ops; u8 index = 0, id; u64 cfg; if (!lmac) return -ENODEV; mac_ops = cgx_dev->mac_ops; /* Restore index 0 to its default init value as done during * cgx_lmac_init */ set_bit(0, lmac->mac_to_index_bmap.bmap); id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max + index; cgx_write(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8)), 0); /* Reset CGXX_CMRX_RX_DMAC_CTL0 register to default state */ cfg = cgx_read(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg &= ~CGX_DMAC_CAM_ACCEPT; cfg |= (CGX_DMAC_BCAST_MODE | CGX_DMAC_MCAST_MODE); cgx_write(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); return 0; } /* Allows caller to change macaddress associated with index * in dmac filter table including index 0 reserved for * interface mac address */ int cgx_lmac_addr_update(u8 cgx_id, u8 lmac_id, u8 *mac_addr, u8 index) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct mac_ops *mac_ops; struct lmac *lmac; u64 cfg; int id; lmac = lmac_pdata(lmac_id, cgx_dev); if (!lmac) return -ENODEV; mac_ops = cgx_dev->mac_ops; /* Validate the index */ if (index >= lmac->mac_to_index_bmap.max) return -EINVAL; /* ensure index is already set */ if (!test_bit(index, lmac->mac_to_index_bmap.bmap)) return -EINVAL; id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max + index; cfg = cgx_read(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8))); cfg &= ~CGX_RX_DMAC_ADR_MASK; cfg |= mac2u64 (mac_addr); cgx_write(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8)), cfg); return 0; } int cgx_lmac_addr_del(u8 cgx_id, u8 lmac_id, u8 index) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); struct mac_ops *mac_ops; u8 mac[ETH_ALEN]; u64 cfg; int id; if (!lmac) return -ENODEV; mac_ops = cgx_dev->mac_ops; /* Validate the index */ if (index >= lmac->mac_to_index_bmap.max) return -EINVAL; /* Skip deletion for reserved index i.e. index 0 */ if (index == 0) return 0; rvu_free_rsrc(&lmac->mac_to_index_bmap, index); id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max + index; /* Read MAC address to check whether it is ucast or mcast */ cfg = cgx_read(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8))); cfg2mac(cfg, mac); if (is_multicast_ether_addr(mac)) lmac->mcast_filters_count--; if (!lmac->mcast_filters_count) { cfg = cgx_read(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg &= ~GENMASK_ULL(2, 1); cfg |= CGX_DMAC_MCAST_MODE; cgx_write(cgx_dev, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); } cgx_write(cgx_dev, 0, (CGXX_CMRX_RX_DMAC_CAM0 + (index * 0x8)), 0); return 0; } int cgx_lmac_addr_max_entries_get(u8 cgx_id, u8 lmac_id) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); if (lmac) return lmac->mac_to_index_bmap.max; return 0; } u64 cgx_lmac_addr_get(u8 cgx_id, u8 lmac_id) { struct cgx *cgx_dev = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx_dev); struct mac_ops *mac_ops; int index; u64 cfg; int id; mac_ops = cgx_dev->mac_ops; id = get_sequence_id_of_lmac(cgx_dev, lmac_id); index = id * lmac->mac_to_index_bmap.max; cfg = cgx_read(cgx_dev, 0, CGXX_CMRX_RX_DMAC_CAM0 + index * 0x8); return cfg & CGX_RX_DMAC_ADR_MASK; } int cgx_set_pkind(void *cgxd, u8 lmac_id, int pkind) { struct cgx *cgx = cgxd; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; cgx_write(cgx, lmac_id, CGXX_CMRX_RX_ID_MAP, (pkind & 0x3F)); return 0; } static u8 cgx_get_lmac_type(void *cgxd, int lmac_id) { struct cgx *cgx = cgxd; u64 cfg; cfg = cgx_read(cgx, lmac_id, CGXX_CMRX_CFG); return (cfg >> CGX_LMAC_TYPE_SHIFT) & CGX_LMAC_TYPE_MASK; } /* Configure CGX LMAC in internal loopback mode */ int cgx_lmac_internal_loopback(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u8 lmac_type; u64 cfg; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; lmac_type = cgx->mac_ops->get_lmac_type(cgx, lmac_id); if (lmac_type == LMAC_MODE_SGMII || lmac_type == LMAC_MODE_QSGMII) { cfg = cgx_read(cgx, lmac_id, CGXX_GMP_PCS_MRX_CTL); if (enable) cfg |= CGXX_GMP_PCS_MRX_CTL_LBK; else cfg &= ~CGXX_GMP_PCS_MRX_CTL_LBK; cgx_write(cgx, lmac_id, CGXX_GMP_PCS_MRX_CTL, cfg); } else { cfg = cgx_read(cgx, lmac_id, CGXX_SPUX_CONTROL1); if (enable) cfg |= CGXX_SPUX_CONTROL1_LBK; else cfg &= ~CGXX_SPUX_CONTROL1_LBK; cgx_write(cgx, lmac_id, CGXX_SPUX_CONTROL1, cfg); } return 0; } void cgx_lmac_promisc_config(int cgx_id, int lmac_id, bool enable) { struct cgx *cgx = cgx_get_pdata(cgx_id); struct lmac *lmac = lmac_pdata(lmac_id, cgx); u16 max_dmac = lmac->mac_to_index_bmap.max; struct mac_ops *mac_ops; int index, i; u64 cfg = 0; int id; if (!cgx) return; id = get_sequence_id_of_lmac(cgx, lmac_id); mac_ops = cgx->mac_ops; if (enable) { /* Enable promiscuous mode on LMAC */ cfg = cgx_read(cgx, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg &= ~CGX_DMAC_CAM_ACCEPT; cfg |= (CGX_DMAC_BCAST_MODE | CGX_DMAC_MCAST_MODE); cgx_write(cgx, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); for (i = 0; i < max_dmac; i++) { index = id * max_dmac + i; cfg = cgx_read(cgx, 0, (CGXX_CMRX_RX_DMAC_CAM0 + index * 0x8)); cfg &= ~CGX_DMAC_CAM_ADDR_ENABLE; cgx_write(cgx, 0, (CGXX_CMRX_RX_DMAC_CAM0 + index * 0x8), cfg); } } else { /* Disable promiscuous mode */ cfg = cgx_read(cgx, lmac_id, CGXX_CMRX_RX_DMAC_CTL0); cfg |= CGX_DMAC_CAM_ACCEPT | CGX_DMAC_MCAST_MODE; cgx_write(cgx, lmac_id, CGXX_CMRX_RX_DMAC_CTL0, cfg); for (i = 0; i < max_dmac; i++) { index = id * max_dmac + i; cfg = cgx_read(cgx, 0, (CGXX_CMRX_RX_DMAC_CAM0 + index * 0x8)); if ((cfg & CGX_RX_DMAC_ADR_MASK) != 0) { cfg |= CGX_DMAC_CAM_ADDR_ENABLE; cgx_write(cgx, 0, (CGXX_CMRX_RX_DMAC_CAM0 + index * 0x8), cfg); } } } } /* Enable or disable forwarding received pause frames to Tx block */ void cgx_lmac_enadis_rx_pause_fwding(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u64 cfg; if (!cgx) return; if (enable) { cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg |= CGX_GMP_GMI_RXX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg |= CGX_SMUX_RX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); } else { cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg &= ~CGX_GMP_GMI_RXX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg &= ~CGX_SMUX_RX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); } } int cgx_get_rx_stats(void *cgxd, int lmac_id, int idx, u64 *rx_stat) { struct cgx *cgx = cgxd; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; *rx_stat = cgx_read(cgx, lmac_id, CGXX_CMRX_RX_STAT0 + (idx * 8)); return 0; } int cgx_get_tx_stats(void *cgxd, int lmac_id, int idx, u64 *tx_stat) { struct cgx *cgx = cgxd; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; *tx_stat = cgx_read(cgx, lmac_id, CGXX_CMRX_TX_STAT0 + (idx * 8)); return 0; } u64 cgx_features_get(void *cgxd) { return ((struct cgx *)cgxd)->hw_features; } static int cgx_set_fec_stats_count(struct cgx_link_user_info *linfo) { if (!linfo->fec) return 0; switch (linfo->lmac_type_id) { case LMAC_MODE_SGMII: case LMAC_MODE_XAUI: case LMAC_MODE_RXAUI: case LMAC_MODE_QSGMII: return 0; case LMAC_MODE_10G_R: case LMAC_MODE_25G_R: case LMAC_MODE_100G_R: case LMAC_MODE_USXGMII: return 1; case LMAC_MODE_40G_R: return 4; case LMAC_MODE_50G_R: if (linfo->fec == OTX2_FEC_BASER) return 2; else return 1; default: return 0; } } int cgx_get_fec_stats(void *cgxd, int lmac_id, struct cgx_fec_stats_rsp *rsp) { int stats, fec_stats_count = 0; int corr_reg, uncorr_reg; struct cgx *cgx = cgxd; if (!cgx || lmac_id >= cgx->lmac_count) return -ENODEV; fec_stats_count = cgx_set_fec_stats_count(&cgx->lmac_idmap[lmac_id]->link_info); if (cgx->lmac_idmap[lmac_id]->link_info.fec == OTX2_FEC_BASER) { corr_reg = CGXX_SPUX_LNX_FEC_CORR_BLOCKS; uncorr_reg = CGXX_SPUX_LNX_FEC_UNCORR_BLOCKS; } else { corr_reg = CGXX_SPUX_RSFEC_CORR; uncorr_reg = CGXX_SPUX_RSFEC_UNCORR; } for (stats = 0; stats < fec_stats_count; stats++) { rsp->fec_corr_blks += cgx_read(cgx, lmac_id, corr_reg + (stats * 8)); rsp->fec_uncorr_blks += cgx_read(cgx, lmac_id, uncorr_reg + (stats * 8)); } return 0; } int cgx_lmac_rx_tx_enable(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u64 cfg; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; cfg = cgx_read(cgx, lmac_id, CGXX_CMRX_CFG); if (enable) cfg |= CMR_EN | DATA_PKT_RX_EN | DATA_PKT_TX_EN; else cfg &= ~(CMR_EN | DATA_PKT_RX_EN | DATA_PKT_TX_EN); cgx_write(cgx, lmac_id, CGXX_CMRX_CFG, cfg); return 0; } int cgx_lmac_tx_enable(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u64 cfg, last; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; cfg = cgx_read(cgx, lmac_id, CGXX_CMRX_CFG); last = cfg; if (enable) cfg |= DATA_PKT_TX_EN; else cfg &= ~DATA_PKT_TX_EN; if (cfg != last) cgx_write(cgx, lmac_id, CGXX_CMRX_CFG, cfg); return !!(last & DATA_PKT_TX_EN); } static int cgx_lmac_get_pause_frm_status(void *cgxd, int lmac_id, u8 *tx_pause, u8 *rx_pause) { struct cgx *cgx = cgxd; u64 cfg; if (is_dev_rpm(cgx)) return 0; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); *rx_pause = !!(cfg & CGX_SMUX_RX_FRM_CTL_CTL_BCK); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_TX_CTL); *tx_pause = !!(cfg & CGX_SMUX_TX_CTL_L2P_BP_CONV); return 0; } static int cgx_lmac_enadis_pause_frm(void *cgxd, int lmac_id, u8 tx_pause, u8 rx_pause) { struct cgx *cgx = cgxd; u64 cfg; if (is_dev_rpm(cgx)) return 0; if (!is_lmac_valid(cgx, lmac_id)) return -ENODEV; cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg &= ~CGX_SMUX_RX_FRM_CTL_CTL_BCK; cfg |= rx_pause ? CGX_SMUX_RX_FRM_CTL_CTL_BCK : 0x0; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_TX_CTL); cfg &= ~CGX_SMUX_TX_CTL_L2P_BP_CONV; cfg |= tx_pause ? CGX_SMUX_TX_CTL_L2P_BP_CONV : 0x0; cgx_write(cgx, lmac_id, CGXX_SMUX_TX_CTL, cfg); cfg = cgx_read(cgx, 0, CGXX_CMR_RX_OVR_BP); if (tx_pause) { cfg &= ~CGX_CMR_RX_OVR_BP_EN(lmac_id); } else { cfg |= CGX_CMR_RX_OVR_BP_EN(lmac_id); cfg &= ~CGX_CMR_RX_OVR_BP_BP(lmac_id); } cgx_write(cgx, 0, CGXX_CMR_RX_OVR_BP, cfg); return 0; } static void cgx_lmac_pause_frm_config(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u64 cfg; if (!is_lmac_valid(cgx, lmac_id)) return; if (enable) { /* Enable receive pause frames */ cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg |= CGX_SMUX_RX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg |= CGX_GMP_GMI_RXX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); /* Enable pause frames transmission */ cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_TX_CTL); cfg |= CGX_SMUX_TX_CTL_L2P_BP_CONV; cgx_write(cgx, lmac_id, CGXX_SMUX_TX_CTL, cfg); /* Set pause time and interval */ cgx_write(cgx, lmac_id, CGXX_SMUX_TX_PAUSE_PKT_TIME, DEFAULT_PAUSE_TIME); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_TX_PAUSE_PKT_INTERVAL); cfg &= ~0xFFFFULL; cgx_write(cgx, lmac_id, CGXX_SMUX_TX_PAUSE_PKT_INTERVAL, cfg | (DEFAULT_PAUSE_TIME / 2)); cgx_write(cgx, lmac_id, CGXX_GMP_GMI_TX_PAUSE_PKT_TIME, DEFAULT_PAUSE_TIME); cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_TX_PAUSE_PKT_INTERVAL); cfg &= ~0xFFFFULL; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_TX_PAUSE_PKT_INTERVAL, cfg | (DEFAULT_PAUSE_TIME / 2)); } else { /* ALL pause frames received are completely ignored */ cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg &= ~CGX_SMUX_RX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg &= ~CGX_GMP_GMI_RXX_FRM_CTL_CTL_BCK; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); /* Disable pause frames transmission */ cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_TX_CTL); cfg &= ~CGX_SMUX_TX_CTL_L2P_BP_CONV; cgx_write(cgx, lmac_id, CGXX_SMUX_TX_CTL, cfg); } } void cgx_lmac_ptp_config(void *cgxd, int lmac_id, bool enable) { struct cgx *cgx = cgxd; u64 cfg; if (!cgx) return; if (is_dev_rpm(cgx)) return; if (enable) { /* Enable inbound PTP timestamping */ cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg |= CGX_GMP_GMI_RXX_FRM_CTL_PTP_MODE; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg |= CGX_SMUX_RX_FRM_CTL_PTP_MODE; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); } else { /* Disable inbound PTP stamping */ cfg = cgx_read(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL); cfg &= ~CGX_GMP_GMI_RXX_FRM_CTL_PTP_MODE; cgx_write(cgx, lmac_id, CGXX_GMP_GMI_RXX_FRM_CTL, cfg); cfg = cgx_read(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL); cfg &= ~CGX_SMUX_RX_FRM_CTL_PTP_MODE; cgx_write(cgx, lmac_id, CGXX_SMUX_RX_FRM_CTL, cfg); } } /* CGX Firmware interface low level support */ int cgx_fwi_cmd_send(u64 req, u64 *resp, struct lmac *lmac) { struct cgx *cgx = lmac->cgx; struct device *dev; int err = 0; u64 cmd; /* Ensure no other command is in progress */ err = mutex_lock_interruptible(&lmac->cmd_lock); if (err) return err; /* Ensure command register is free */ cmd = cgx_read(cgx, lmac->lmac_id, CGX_COMMAND_REG); if (FIELD_GET(CMDREG_OWN, cmd) != CGX_CMD_OWN_NS) { err = -EBUSY; goto unlock; } /* Update ownership in command request */ req = FIELD_SET(CMDREG_OWN, CGX_CMD_OWN_FIRMWARE, req); /* Mark this lmac as pending, before we start */ lmac->cmd_pend = true; /* Start command in hardware */ cgx_write(cgx, lmac->lmac_id, CGX_COMMAND_REG, req); /* Ensure command is completed without errors */ if (!wait_event_timeout(lmac->wq_cmd_cmplt, !lmac->cmd_pend, msecs_to_jiffies(CGX_CMD_TIMEOUT))) { dev = &cgx->pdev->dev; dev_err(dev, "cgx port %d:%d cmd timeout\n", cgx->cgx_id, lmac->lmac_id); err = -EIO; goto unlock; } /* we have a valid command response */ smp_rmb(); /* Ensure the latest updates are visible */ *resp = lmac->resp; unlock: mutex_unlock(&lmac->cmd_lock); return err; } int cgx_fwi_cmd_generic(u64 req, u64 *resp, struct cgx *cgx, int lmac_id) { struct lmac *lmac; int err; lmac = lmac_pdata(lmac_id, cgx); if (!lmac) return -ENODEV; err = cgx_fwi_cmd_send(req, resp, lmac); /* Check for valid response */ if (!err) { if (FIELD_GET(EVTREG_STAT, *resp) == CGX_STAT_FAIL) return -EIO; else return 0; } return err; } static int cgx_link_usertable_index_map(int speed) { switch (speed) { case SPEED_10: return CGX_LINK_10M; case SPEED_100: return CGX_LINK_100M; case SPEED_1000: return CGX_LINK_1G; case SPEED_2500: return CGX_LINK_2HG; case SPEED_5000: return CGX_LINK_5G; case SPEED_10000: return CGX_LINK_10G; case SPEED_20000: return CGX_LINK_20G; case SPEED_25000: return CGX_LINK_25G; case SPEED_40000: return CGX_LINK_40G; case SPEED_50000: return CGX_LINK_50G; case 80000: return CGX_LINK_80G; case SPEED_100000: return CGX_LINK_100G; case SPEED_UNKNOWN: return CGX_LINK_NONE; } return CGX_LINK_NONE; } static void set_mod_args(struct cgx_set_link_mode_args *args, u32 speed, u8 duplex, u8 autoneg, u64 mode) { /* Fill default values incase of user did not pass * valid parameters */ if (args->duplex == DUPLEX_UNKNOWN) args->duplex = duplex; if (args->speed == SPEED_UNKNOWN) args->speed = speed; if (args->an == AUTONEG_UNKNOWN) args->an = autoneg; args->mode = mode; args->ports = 0; } static void otx2_map_ethtool_link_modes(u64 bitmask, struct cgx_set_link_mode_args *args) { switch (bitmask) { case ETHTOOL_LINK_MODE_10baseT_Half_BIT: set_mod_args(args, 10, 1, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_10baseT_Full_BIT: set_mod_args(args, 10, 0, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_100baseT_Half_BIT: set_mod_args(args, 100, 1, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_100baseT_Full_BIT: set_mod_args(args, 100, 0, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_1000baseT_Half_BIT: set_mod_args(args, 1000, 1, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_1000baseT_Full_BIT: set_mod_args(args, 1000, 0, 1, BIT_ULL(CGX_MODE_SGMII)); break; case ETHTOOL_LINK_MODE_1000baseX_Full_BIT: set_mod_args(args, 1000, 0, 0, BIT_ULL(CGX_MODE_1000_BASEX)); break; case ETHTOOL_LINK_MODE_10000baseT_Full_BIT: set_mod_args(args, 1000, 0, 1, BIT_ULL(CGX_MODE_QSGMII)); break; case ETHTOOL_LINK_MODE_10000baseSR_Full_BIT: set_mod_args(args, 10000, 0, 0, BIT_ULL(CGX_MODE_10G_C2C)); break; case ETHTOOL_LINK_MODE_10000baseLR_Full_BIT: set_mod_args(args, 10000, 0, 0, BIT_ULL(CGX_MODE_10G_C2M)); break; case ETHTOOL_LINK_MODE_10000baseKR_Full_BIT: set_mod_args(args, 10000, 0, 1, BIT_ULL(CGX_MODE_10G_KR)); break; case ETHTOOL_LINK_MODE_25000baseSR_Full_BIT: set_mod_args(args, 25000, 0, 0, BIT_ULL(CGX_MODE_25G_C2C)); break; case ETHTOOL_LINK_MODE_25000baseCR_Full_BIT: set_mod_args(args, 25000, 0, 1, BIT_ULL(CGX_MODE_25G_CR)); break; case ETHTOOL_LINK_MODE_25000baseKR_Full_BIT: set_mod_args(args, 25000, 0, 1, BIT_ULL(CGX_MODE_25G_KR)); break; case ETHTOOL_LINK_MODE_40000baseSR4_Full_BIT: set_mod_args(args, 40000, 0, 0, BIT_ULL(CGX_MODE_40G_C2C)); break; case ETHTOOL_LINK_MODE_40000baseLR4_Full_BIT: set_mod_args(args, 40000, 0, 0, BIT_ULL(CGX_MODE_40G_C2M)); break; case ETHTOOL_LINK_MODE_40000baseCR4_Full_BIT: set_mod_args(args, 40000, 0, 1, BIT_ULL(CGX_MODE_40G_CR4)); break; case ETHTOOL_LINK_MODE_40000baseKR4_Full_BIT: set_mod_args(args, 40000, 0, 1, BIT_ULL(CGX_MODE_40G_KR4)); break; case ETHTOOL_LINK_MODE_50000baseSR_Full_BIT: set_mod_args(args, 50000, 0, 0, BIT_ULL(CGX_MODE_50G_C2C)); break; case ETHTOOL_LINK_MODE_50000baseLR_ER_FR_Full_BIT: set_mod_args(args, 50000, 0, 0, BIT_ULL(CGX_MODE_50G_C2M)); break; case ETHTOOL_LINK_MODE_50000baseCR_Full_BIT: set_mod_args(args, 50000, 0, 1, BIT_ULL(CGX_MODE_50G_CR)); break; case ETHTOOL_LINK_MODE_50000baseKR_Full_BIT: set_mod_args(args, 50000, 0, 1, BIT_ULL(CGX_MODE_50G_KR)); break; case ETHTOOL_LINK_MODE_100000baseSR4_Full_BIT: set_mod_args(args, 100000, 0, 0, BIT_ULL(CGX_MODE_100G_C2C)); break; case ETHTOOL_LINK_MODE_100000baseLR4_ER4_Full_BIT: set_mod_args(args, 100000, 0, 0, BIT_ULL(CGX_MODE_100G_C2M)); break; case ETHTOOL_LINK_MODE_100000baseCR4_Full_BIT: set_mod_args(args, 100000, 0, 1, BIT_ULL(CGX_MODE_100G_CR4)); break; case ETHTOOL_LINK_MODE_100000baseKR4_Full_BIT: set_mod_args(args, 100000, 0, 1, BIT_ULL(CGX_MODE_100G_KR4)); break; default: set_mod_args(args, 0, 1, 0, BIT_ULL(CGX_MODE_MAX)); break; } } static inline void link_status_user_format(u64 lstat, struct cgx_link_user_info *linfo, struct cgx *cgx, u8 lmac_id) { const char *lmac_string; linfo->link_up = FIELD_GET(RESP_LINKSTAT_UP, lstat); linfo->full_duplex = FIELD_GET(RESP_LINKSTAT_FDUPLEX, lstat); linfo->speed = cgx_speed_mbps[FIELD_GET(RESP_LINKSTAT_SPEED, lstat)]; linfo->an = FIELD_GET(RESP_LINKSTAT_AN, lstat); linfo->fec = FIELD_GET(RESP_LINKSTAT_FEC, lstat); linfo->lmac_type_id = cgx_get_lmac_type(cgx, lmac_id); lmac_string = cgx_lmactype_string[linfo->lmac_type_id]; strncpy(linfo->lmac_type, lmac_string, LMACTYPE_STR_LEN - 1); } /* Hardware event handlers */ static inline void cgx_link_change_handler(u64 lstat, struct lmac *lmac) { struct cgx_link_user_info *linfo; struct cgx *cgx = lmac->cgx; struct cgx_link_event event; struct device *dev; int err_type; dev = &cgx->pdev->dev; link_status_user_format(lstat, &event.link_uinfo, cgx, lmac->lmac_id); err_type = FIELD_GET(RESP_LINKSTAT_ERRTYPE, lstat); event.cgx_id = cgx->cgx_id; event.lmac_id = lmac->lmac_id; /* update the local copy of link status */ lmac->link_info = event.link_uinfo; linfo = &lmac->link_info; if (err_type == CGX_ERR_SPEED_CHANGE_INVALID) return; /* Ensure callback doesn't get unregistered until we finish it */ spin_lock(&lmac->event_cb_lock); if (!lmac->event_cb.notify_link_chg) { dev_dbg(dev, "cgx port %d:%d Link change handler null", cgx->cgx_id, lmac->lmac_id); if (err_type != CGX_ERR_NONE) { dev_err(dev, "cgx port %d:%d Link error %d\n", cgx->cgx_id, lmac->lmac_id, err_type); } dev_info(dev, "cgx port %d:%d Link is %s %d Mbps\n", cgx->cgx_id, lmac->lmac_id, linfo->link_up ? "UP" : "DOWN", linfo->speed); goto err; } if (lmac->event_cb.notify_link_chg(&event, lmac->event_cb.data)) dev_err(dev, "event notification failure\n"); err: spin_unlock(&lmac->event_cb_lock); } static inline bool cgx_cmdresp_is_linkevent(u64 event) { u8 id; id = FIELD_GET(EVTREG_ID, event); if (id == CGX_CMD_LINK_BRING_UP || id == CGX_CMD_LINK_BRING_DOWN || id == CGX_CMD_MODE_CHANGE) return true; else return false; } static inline bool cgx_event_is_linkevent(u64 event) { if (FIELD_GET(EVTREG_ID, event) == CGX_EVT_LINK_CHANGE) return true; else return false; } static irqreturn_t cgx_fwi_event_handler(int irq, void *data) { u64 event, offset, clear_bit; struct lmac *lmac = data; struct cgx *cgx; cgx = lmac->cgx; /* Clear SW_INT for RPM and CMR_INT for CGX */ offset = cgx->mac_ops->int_register; clear_bit = cgx->mac_ops->int_ena_bit; event = cgx_read(cgx, lmac->lmac_id, CGX_EVENT_REG); if (!FIELD_GET(EVTREG_ACK, event)) return IRQ_NONE; switch (FIELD_GET(EVTREG_EVT_TYPE, event)) { case CGX_EVT_CMD_RESP: /* Copy the response. Since only one command is active at a * time, there is no way a response can get overwritten */ lmac->resp = event; /* Ensure response is updated before thread context starts */ smp_wmb(); /* There wont be separate events for link change initiated from * software; Hence report the command responses as events */ if (cgx_cmdresp_is_linkevent(event)) cgx_link_change_handler(event, lmac); /* Release thread waiting for completion */ lmac->cmd_pend = false; wake_up_interruptible(&lmac->wq_cmd_cmplt); break; case CGX_EVT_ASYNC: if (cgx_event_is_linkevent(event)) cgx_link_change_handler(event, lmac); break; } /* Any new event or command response will be posted by firmware * only after the current status is acked. * Ack the interrupt register as well. */ cgx_write(lmac->cgx, lmac->lmac_id, CGX_EVENT_REG, 0); cgx_write(lmac->cgx, lmac->lmac_id, offset, clear_bit); return IRQ_HANDLED; } /* APIs for PHY management using CGX firmware interface */ /* callback registration for hardware events like link change */ int cgx_lmac_evh_register(struct cgx_event_cb *cb, void *cgxd, int lmac_id) { struct cgx *cgx = cgxd; struct lmac *lmac; lmac = lmac_pdata(lmac_id, cgx); if (!lmac) return -ENODEV; lmac->event_cb = *cb; return 0; } int cgx_lmac_evh_unregister(void *cgxd, int lmac_id) { struct lmac *lmac; unsigned long flags; struct cgx *cgx = cgxd; lmac = lmac_pdata(lmac_id, cgx); if (!lmac) return -ENODEV; spin_lock_irqsave(&lmac->event_cb_lock, flags); lmac->event_cb.notify_link_chg = NULL; lmac->event_cb.data = NULL; spin_unlock_irqrestore(&lmac->event_cb_lock, flags); return 0; } int cgx_get_fwdata_base(u64 *base) { u64 req = 0, resp; struct cgx *cgx; int first_lmac; int err; cgx = list_first_entry_or_null(&cgx_list, struct cgx, cgx_list); if (!cgx) return -ENXIO; first_lmac = find_first_bit(&cgx->lmac_bmap, MAX_LMAC_PER_CGX); req = FIELD_SET(CMDREG_ID, CGX_CMD_GET_FWD_BASE, req); err = cgx_fwi_cmd_generic(req, &resp, cgx, first_lmac); if (!err) *base = FIELD_GET(RESP_FWD_BASE, resp); return err; } int cgx_set_link_mode(void *cgxd, struct cgx_set_link_mode_args args, int cgx_id, int lmac_id) { struct cgx *cgx = cgxd; u64 req = 0, resp; if (!cgx) return -ENODEV; if (args.mode) otx2_map_ethtool_link_modes(args.mode, &args); if (!args.speed && args.duplex && !args.an) return -EINVAL; req = FIELD_SET(CMDREG_ID, CGX_CMD_MODE_CHANGE, req); req = FIELD_SET(CMDMODECHANGE_SPEED, cgx_link_usertable_index_map(args.speed), req); req = FIELD_SET(CMDMODECHANGE_DUPLEX, args.duplex, req); req = FIELD_SET(CMDMODECHANGE_AN, args.an, req); req = FIELD_SET(CMDMODECHANGE_PORT, args.ports, req); req = FIELD_SET(CMDMODECHANGE_FLAGS, args.mode, req); return cgx_fwi_cmd_generic(req, &resp, cgx, lmac_id); } int cgx_set_fec(u64 fec, int cgx_id, int lmac_id) { u64 req = 0, resp; struct cgx *cgx; int err = 0; cgx = cgx_get_pdata(cgx_id); if (!cgx) return -ENXIO; req = FIELD_SET(CMDREG_ID, CGX_CMD_SET_FEC, req); req = FIELD_SET(CMDSETFEC, fec, req); err = cgx_fwi_cmd_generic(req, &resp, cgx, lmac_id); if (err) return err; cgx->lmac_idmap[lmac_id]->link_info.fec = FIELD_GET(RESP_LINKSTAT_FEC, resp); return cgx->lmac_idmap[lmac_id]->link_info.fec; } int cgx_get_phy_fec_stats(void *cgxd, int lmac_id) { struct cgx *cgx = cgxd; u64 req = 0, resp; if (!cgx) return -ENODEV; req = FIELD_SET(CMDREG_ID, CGX_CMD_GET_PHY_FEC_STATS, req); return cgx_fwi_cmd_generic(req, &resp, cgx, lmac_id); } static int cgx_fwi_link_change(struct cgx *cgx, int lmac_id, bool enable) { u64 req = 0; u64 resp; if (enable) req = FIELD_SET(CMDREG_ID, CGX_CMD_LINK_BRING_UP, req); else req = FIELD_SET(CMDREG_ID, CGX_CMD_LINK_BRING_DOWN, req); return cgx_fwi_cmd_generic(req, &resp, cgx, lmac_id); } static inline int cgx_fwi_read_version(u64 *resp, struct cgx *cgx) { int first_lmac = find_first_bit(&cgx->lmac_bmap, MAX_LMAC_PER_CGX); u64 req = 0; req = FIELD_SET(CMDREG_ID, CGX_CMD_GET_FW_VER, req); return cgx_fwi_cmd_generic(req, resp, cgx, first_lmac); } static int cgx_lmac_verify_fwi_version(struct cgx *cgx) { struct device *dev = &cgx->pdev->dev; int major_ver, minor_ver; u64 resp; int err; if (!cgx->lmac_count) return 0; err = cgx_fwi_read_version(&resp, cgx); if (err) return err; major_ver = FIELD_GET(RESP_MAJOR_VER, resp); minor_ver = FIELD_GET(RESP_MINOR_VER, resp); dev_dbg(dev, "Firmware command interface version = %d.%d\n", major_ver, minor_ver); if (major_ver != CGX_FIRMWARE_MAJOR_VER) return -EIO; else return 0; } static void cgx_lmac_linkup_work(struct work_struct *work) { struct cgx *cgx = container_of(work, struct cgx, cgx_cmd_work); struct device *dev = &cgx->pdev->dev; int i, err; /* Do Link up for all the enabled lmacs */ for_each_set_bit(i, &cgx->lmac_bmap, MAX_LMAC_PER_CGX) { err = cgx_fwi_link_change(cgx, i, true); if (err) dev_info(dev, "cgx port %d:%d Link up command failed\n", cgx->cgx_id, i); } } int cgx_lmac_linkup_start(void *cgxd) { struct cgx *cgx = cgxd; if (!cgx) return -ENODEV; queue_work(cgx->cgx_cmd_workq, &cgx->cgx_cmd_work); return 0; } static void cgx_lmac_get_fifolen(struct cgx *cgx) { u64 cfg; cfg = cgx_read(cgx, 0, CGX_CONST); cgx->mac_ops->fifo_len = FIELD_GET(CGX_CONST_RXFIFO_SIZE, cfg); } static int cgx_configure_interrupt(struct cgx *cgx, struct lmac *lmac, int cnt, bool req_free) { struct mac_ops *mac_ops = cgx->mac_ops; u64 offset, ena_bit; unsigned int irq; int err; irq = pci_irq_vector(cgx->pdev, mac_ops->lmac_fwi + cnt * mac_ops->irq_offset); offset = mac_ops->int_set_reg; ena_bit = mac_ops->int_ena_bit; if (req_free) { free_irq(irq, lmac); return 0; } err = request_irq(irq, cgx_fwi_event_handler, 0, lmac->name, lmac); if (err) return err; /* Enable interrupt */ cgx_write(cgx, lmac->lmac_id, offset, ena_bit); return 0; } int cgx_get_nr_lmacs(void *cgxd) { struct cgx *cgx = cgxd; return cgx_read(cgx, 0, CGXX_CMRX_RX_LMACS) & 0x7ULL; } u8 cgx_get_lmacid(void *cgxd, u8 lmac_index) { struct cgx *cgx = cgxd; return cgx->lmac_idmap[lmac_index]->lmac_id; } unsigned long cgx_get_lmac_bmap(void *cgxd) { struct cgx *cgx = cgxd; return cgx->lmac_bmap; } static int cgx_lmac_init(struct cgx *cgx) { struct lmac *lmac; u64 lmac_list; int i, err; cgx_lmac_get_fifolen(cgx); cgx->lmac_count = cgx->mac_ops->get_nr_lmacs(cgx); /* lmac_list specifies which lmacs are enabled * when bit n is set to 1, LMAC[n] is enabled */ if (cgx->mac_ops->non_contiguous_serdes_lane) lmac_list = cgx_read(cgx, 0, CGXX_CMRX_RX_LMACS) & 0xFULL; if (cgx->lmac_count > MAX_LMAC_PER_CGX) cgx->lmac_count = MAX_LMAC_PER_CGX; for (i = 0; i < cgx->lmac_count; i++) { lmac = kzalloc(sizeof(struct lmac), GFP_KERNEL); if (!lmac) return -ENOMEM; lmac->name = kcalloc(1, sizeof("cgx_fwi_xxx_yyy"), GFP_KERNEL); if (!lmac->name) { err = -ENOMEM; goto err_lmac_free; } sprintf(lmac->name, "cgx_fwi_%d_%d", cgx->cgx_id, i); if (cgx->mac_ops->non_contiguous_serdes_lane) { lmac->lmac_id = __ffs64(lmac_list); lmac_list &= ~BIT_ULL(lmac->lmac_id); } else { lmac->lmac_id = i; } lmac->cgx = cgx; lmac->mac_to_index_bmap.max = MAX_DMAC_ENTRIES_PER_CGX / cgx->lmac_count; err = rvu_alloc_bitmap(&lmac->mac_to_index_bmap); if (err) goto err_name_free; /* Reserve first entry for default MAC address */ set_bit(0, lmac->mac_to_index_bmap.bmap); init_waitqueue_head(&lmac->wq_cmd_cmplt); mutex_init(&lmac->cmd_lock); spin_lock_init(&lmac->event_cb_lock); err = cgx_configure_interrupt(cgx, lmac, lmac->lmac_id, false); if (err) goto err_bitmap_free; /* Add reference */ cgx->lmac_idmap[lmac->lmac_id] = lmac; set_bit(lmac->lmac_id, &cgx->lmac_bmap); cgx->mac_ops->mac_pause_frm_config(cgx, lmac->lmac_id, true); } return cgx_lmac_verify_fwi_version(cgx); err_bitmap_free: rvu_free_bitmap(&lmac->mac_to_index_bmap); err_name_free: kfree(lmac->name); err_lmac_free: kfree(lmac); return err; } static int cgx_lmac_exit(struct cgx *cgx) { struct lmac *lmac; int i; if (cgx->cgx_cmd_workq) { flush_workqueue(cgx->cgx_cmd_workq); destroy_workqueue(cgx->cgx_cmd_workq); cgx->cgx_cmd_workq = NULL; } /* Free all lmac related resources */ for_each_set_bit(i, &cgx->lmac_bmap, MAX_LMAC_PER_CGX) { lmac = cgx->lmac_idmap[i]; if (!lmac) continue; cgx->mac_ops->mac_pause_frm_config(cgx, lmac->lmac_id, false); cgx_configure_interrupt(cgx, lmac, lmac->lmac_id, true); kfree(lmac->mac_to_index_bmap.bmap); kfree(lmac->name); kfree(lmac); } return 0; } static void cgx_populate_features(struct cgx *cgx) { if (is_dev_rpm(cgx)) cgx->hw_features = (RVU_MAC_RPM | RVU_LMAC_FEAT_FC); else cgx->hw_features = (RVU_LMAC_FEAT_FC | RVU_LMAC_FEAT_PTP); } static struct mac_ops cgx_mac_ops = { .name = "cgx", .csr_offset = 0, .lmac_offset = 18, .int_register = CGXX_CMRX_INT, .int_set_reg = CGXX_CMRX_INT_ENA_W1S, .irq_offset = 9, .int_ena_bit = FW_CGX_INT, .lmac_fwi = CGX_LMAC_FWI, .non_contiguous_serdes_lane = false, .rx_stats_cnt = 9, .tx_stats_cnt = 18, .get_nr_lmacs = cgx_get_nr_lmacs, .get_lmac_type = cgx_get_lmac_type, .mac_lmac_intl_lbk = cgx_lmac_internal_loopback, .mac_get_rx_stats = cgx_get_rx_stats, .mac_get_tx_stats = cgx_get_tx_stats, .mac_enadis_rx_pause_fwding = cgx_lmac_enadis_rx_pause_fwding, .mac_get_pause_frm_status = cgx_lmac_get_pause_frm_status, .mac_enadis_pause_frm = cgx_lmac_enadis_pause_frm, .mac_pause_frm_config = cgx_lmac_pause_frm_config, }; static int cgx_probe(struct pci_dev *pdev, const struct pci_device_id *id) { struct device *dev = &pdev->dev; struct cgx *cgx; int err, nvec; cgx = devm_kzalloc(dev, sizeof(*cgx), GFP_KERNEL); if (!cgx) return -ENOMEM; cgx->pdev = pdev; pci_set_drvdata(pdev, cgx); /* Use mac_ops to get MAC specific features */ if (pdev->device == PCI_DEVID_CN10K_RPM) cgx->mac_ops = rpm_get_mac_ops(); else cgx->mac_ops = &cgx_mac_ops; err = pci_enable_device(pdev); if (err) { dev_err(dev, "Failed to enable PCI device\n"); pci_set_drvdata(pdev, NULL); return err; } err = pci_request_regions(pdev, DRV_NAME); if (err) { dev_err(dev, "PCI request regions failed 0x%x\n", err); goto err_disable_device; } /* MAP configuration registers */ cgx->reg_base = pcim_iomap(pdev, PCI_CFG_REG_BAR_NUM, 0); if (!cgx->reg_base) { dev_err(dev, "CGX: Cannot map CSR memory space, aborting\n"); err = -ENOMEM; goto err_release_regions; } nvec = pci_msix_vec_count(cgx->pdev); err = pci_alloc_irq_vectors(pdev, nvec, nvec, PCI_IRQ_MSIX); if (err < 0 || err != nvec) { dev_err(dev, "Request for %d msix vectors failed, err %d\n", nvec, err); goto err_release_regions; } cgx->cgx_id = (pci_resource_start(pdev, PCI_CFG_REG_BAR_NUM) >> 24) & CGX_ID_MASK; /* init wq for processing linkup requests */ INIT_WORK(&cgx->cgx_cmd_work, cgx_lmac_linkup_work); cgx->cgx_cmd_workq = alloc_workqueue("cgx_cmd_workq", 0, 0); if (!cgx->cgx_cmd_workq) { dev_err(dev, "alloc workqueue failed for cgx cmd"); err = -ENOMEM; goto err_free_irq_vectors; } list_add(&cgx->cgx_list, &cgx_list); cgx_populate_features(cgx); mutex_init(&cgx->lock); err = cgx_lmac_init(cgx); if (err) goto err_release_lmac; return 0; err_release_lmac: cgx_lmac_exit(cgx); list_del(&cgx->cgx_list); err_free_irq_vectors: pci_free_irq_vectors(pdev); err_release_regions: pci_release_regions(pdev); err_disable_device: pci_disable_device(pdev); pci_set_drvdata(pdev, NULL); return err; } static void cgx_remove(struct pci_dev *pdev) { struct cgx *cgx = pci_get_drvdata(pdev); if (cgx) { cgx_lmac_exit(cgx); list_del(&cgx->cgx_list); } pci_free_irq_vectors(pdev); pci_release_regions(pdev); pci_disable_device(pdev); pci_set_drvdata(pdev, NULL); } struct pci_driver cgx_driver = { .name = DRV_NAME, .id_table = cgx_id_table, .probe = cgx_probe, .remove = cgx_remove, };
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