/* Copyright 2008-2012 Freescale Semiconductor, Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Freescale Semiconductor nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * * ALTERNATIVELY, this software may be distributed under the terms of the * GNU General Public License ("GPL") as published by the Free Software * Foundation, either version 2 of that License or (at your option) any * later version. * * THIS SOFTWARE IS PROVIDED BY Freescale Semiconductor ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL Freescale Semiconductor BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifdef CONFIG_FSL_DPAA_ETH_DEBUG #define pr_fmt(fmt) \ KBUILD_MODNAME ": %s:%hu:%s() " fmt, \ KBUILD_BASENAME".c", __LINE__, __func__ #else #define pr_fmt(fmt) \ KBUILD_MODNAME ": " fmt #endif #include #include #include #include #include #include #include "dpaa_eth.h" #include "mac.h" #include "lnxwrp_fsl_fman.h" #include "error_ext.h" /* GET_ERROR_TYPE, E_OK */ #include "../fman/inc/flib/fsl_fman_dtsec.h" #include "../fman/inc/flib/fsl_fman_tgec.h" #include "../fman/inc/flib/fsl_fman_memac.h" #include "../fman/src/wrapper/lnxwrp_sysfs_fm.h" #define MAC_DESCRIPTION "FSL FMan MAC API based driver" MODULE_LICENSE("Dual BSD/GPL"); MODULE_AUTHOR("Emil Medve "); MODULE_DESCRIPTION(MAC_DESCRIPTION); struct mac_priv_s { struct fm_mac_dev *fm_mac; }; const char *mac_driver_description __initconst = MAC_DESCRIPTION; const size_t mac_sizeof_priv[] = { [DTSEC] = sizeof(struct mac_priv_s), [XGMAC] = sizeof(struct mac_priv_s), [MEMAC] = sizeof(struct mac_priv_s) }; static const enet_mode_t _100[] = { [PHY_INTERFACE_MODE_MII] = e_ENET_MODE_MII_100, [PHY_INTERFACE_MODE_RMII] = e_ENET_MODE_RMII_100 }; static const enet_mode_t _1000[] = { [PHY_INTERFACE_MODE_GMII] = e_ENET_MODE_GMII_1000, [PHY_INTERFACE_MODE_SGMII] = e_ENET_MODE_SGMII_1000, [PHY_INTERFACE_MODE_TBI] = e_ENET_MODE_TBI_1000, [PHY_INTERFACE_MODE_RGMII] = e_ENET_MODE_RGMII_1000, [PHY_INTERFACE_MODE_RGMII_ID] = e_ENET_MODE_RGMII_1000, [PHY_INTERFACE_MODE_RGMII_RXID] = e_ENET_MODE_RGMII_1000, [PHY_INTERFACE_MODE_RGMII_TXID] = e_ENET_MODE_RGMII_1000, [PHY_INTERFACE_MODE_RTBI] = e_ENET_MODE_RTBI_1000 }; static enet_mode_t __cold __attribute__((nonnull)) macdev2enetinterface(const struct mac_device *mac_dev) { switch (mac_dev->max_speed) { case SPEED_100: return _100[mac_dev->phy_if]; case SPEED_1000: return _1000[mac_dev->phy_if]; case SPEED_2500: return e_ENET_MODE_SGMII_2500; case SPEED_10000: return e_ENET_MODE_XGMII_10000; default: return e_ENET_MODE_MII_100; } } static void mac_exception(handle_t _mac_dev, e_FmMacExceptions exception) { struct mac_device *mac_dev; mac_dev = (struct mac_device *)_mac_dev; if (e_FM_MAC_EX_10G_RX_FIFO_OVFL == exception) { /* don't flag RX FIFO after the first */ fm_mac_set_exception(mac_dev->get_mac_handle(mac_dev), e_FM_MAC_EX_10G_RX_FIFO_OVFL, false); dev_err(mac_dev->dev, "10G MAC got RX FIFO Error = %x\n", exception); } dev_dbg(mac_dev->dev, "%s:%s() -> %d\n", KBUILD_BASENAME".c", __func__, exception); } static int __cold init(struct mac_device *mac_dev) { int _errno; struct mac_priv_s *priv; t_FmMacParams param; uint32_t version; priv = macdev_priv(mac_dev); param.baseAddr = (typeof(param.baseAddr))(uintptr_t)devm_ioremap( mac_dev->dev, mac_dev->res->start, 0x2000); param.enetMode = macdev2enetinterface(mac_dev); memcpy(¶m.addr, mac_dev->addr, min(sizeof(param.addr), sizeof(mac_dev->addr))); param.macId = mac_dev->cell_index; param.h_Fm = (handle_t)mac_dev->fm; param.mdioIrq = NO_IRQ; param.f_Exception = mac_exception; param.f_Event = mac_exception; param.h_App = mac_dev; priv->fm_mac = fm_mac_config(¶m); if (unlikely(priv->fm_mac == NULL)) { _errno = -EINVAL; goto _return; } fm_mac_set_handle(mac_dev->fm_dev, priv->fm_mac, (macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000) ? param.macId : param.macId + FM_MAX_NUM_OF_1G_MACS); _errno = fm_mac_config_max_frame_length(priv->fm_mac, fm_get_max_frm()); if (unlikely(_errno < 0)) goto _return_fm_mac_free; if (macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000) { /* 10G always works with pad and CRC */ _errno = fm_mac_config_pad_and_crc(priv->fm_mac, true); if (unlikely(_errno < 0)) goto _return_fm_mac_free; _errno = fm_mac_config_half_duplex(priv->fm_mac, mac_dev->half_duplex); if (unlikely(_errno < 0)) goto _return_fm_mac_free; } else { _errno = fm_mac_config_reset_on_init(priv->fm_mac, true); if (unlikely(_errno < 0)) goto _return_fm_mac_free; } _errno = fm_mac_init(priv->fm_mac); if (unlikely(_errno < 0)) goto _return_fm_mac_free; #ifndef CONFIG_FMAN_MIB_CNT_OVF_IRQ_EN /* For 1G MAC, disable by default the MIB counters overflow interrupt */ if (macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000) { _errno = fm_mac_set_exception(mac_dev->get_mac_handle(mac_dev), e_FM_MAC_EX_1G_RX_MIB_CNT_OVFL, FALSE); if (unlikely(_errno < 0)) goto _return_fm_mac_free; } #endif /* !CONFIG_FMAN_MIB_CNT_OVF_IRQ_EN */ /* For 10G MAC, disable Tx ECC exception */ if (macdev2enetinterface(mac_dev) == e_ENET_MODE_XGMII_10000) { _errno = fm_mac_set_exception(mac_dev->get_mac_handle(mac_dev), e_FM_MAC_EX_10G_1TX_ECC_ER, FALSE); if (unlikely(_errno < 0)) goto _return_fm_mac_free; } _errno = fm_mac_get_version(priv->fm_mac, &version); if (unlikely(_errno < 0)) goto _return_fm_mac_free; dev_info(mac_dev->dev, "FMan %s version: 0x%08x\n", ((macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000) ? "dTSEC" : "XGEC"), version); goto _return; _return_fm_mac_free: fm_mac_free(mac_dev->get_mac_handle(mac_dev)); _return: return _errno; } static int __cold memac_init(struct mac_device *mac_dev) { int _errno; struct mac_priv_s *priv; t_FmMacParams param; priv = macdev_priv(mac_dev); param.baseAddr = (typeof(param.baseAddr))(uintptr_t)devm_ioremap( mac_dev->dev, mac_dev->res->start, 0x2000); param.enetMode = macdev2enetinterface(mac_dev); memcpy(¶m.addr, mac_dev->addr, sizeof(mac_dev->addr)); param.macId = mac_dev->cell_index; param.h_Fm = (handle_t)mac_dev->fm; param.mdioIrq = NO_IRQ; param.f_Exception = mac_exception; param.f_Event = mac_exception; param.h_App = mac_dev; priv->fm_mac = fm_mac_config(¶m); if (unlikely(priv->fm_mac == NULL)) { _errno = -EINVAL; goto _return; } _errno = fm_mac_config_max_frame_length(priv->fm_mac, fm_get_max_frm()); if (unlikely(_errno < 0)) goto _return_fm_mac_free; _errno = fm_mac_config_reset_on_init(priv->fm_mac, true); if (unlikely(_errno < 0)) goto _return_fm_mac_free; _errno = fm_mac_init(priv->fm_mac); if (unlikely(_errno < 0)) goto _return_fm_mac_free; dev_info(mac_dev->dev, "FMan MEMAC\n"); goto _return; _return_fm_mac_free: fm_mac_free(priv->fm_mac); _return: return _errno; } static int __cold start(struct mac_device *mac_dev) { int _errno; struct phy_device *phy_dev = mac_dev->phy_dev; _errno = fm_mac_enable(mac_dev->get_mac_handle(mac_dev)); if (!_errno && phy_dev) { if (macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000) phy_start(phy_dev); else if (phy_dev->drv->read_status) phy_dev->drv->read_status(phy_dev); } return _errno; } static int __cold stop(struct mac_device *mac_dev) { if (mac_dev->phy_dev && (macdev2enetinterface(mac_dev) != e_ENET_MODE_XGMII_10000)) phy_stop(mac_dev->phy_dev); return fm_mac_disable(mac_dev->get_mac_handle(mac_dev)); } static int __cold set_multi(struct net_device *net_dev, struct mac_device *mac_dev) { struct mac_priv_s *mac_priv; struct mac_address *old_addr, *tmp; struct netdev_hw_addr *ha; int _errno; mac_priv = macdev_priv(mac_dev); /* Clear previous address list */ list_for_each_entry_safe(old_addr, tmp, &mac_dev->mc_addr_list, list) { _errno = fm_mac_remove_hash_mac_addr(mac_priv->fm_mac, (t_EnetAddr *)old_addr->addr); if (_errno < 0) return _errno; list_del(&old_addr->list); kfree(old_addr); } /* Add all the addresses from the new list */ netdev_for_each_mc_addr(ha, net_dev) { _errno = fm_mac_add_hash_mac_addr(mac_priv->fm_mac, (t_EnetAddr *)ha->addr); if (_errno < 0) return _errno; tmp = kmalloc(sizeof(struct mac_address), GFP_ATOMIC); if (!tmp) { dev_err(mac_dev->dev, "Out of memory\n"); return -ENOMEM; } memcpy(tmp->addr, ha->addr, ETH_ALEN); list_add(&tmp->list, &mac_dev->mc_addr_list); } return 0; } /* Avoid redundant calls to FMD, if the MAC driver already contains the desired * active PAUSE settings. Otherwise, the new active settings should be reflected * in FMan. */ int set_mac_active_pause(struct mac_device *mac_dev, bool rx, bool tx) { struct fm_mac_dev *fm_mac_dev = mac_dev->get_mac_handle(mac_dev); int _errno = 0; if (unlikely(rx != mac_dev->rx_pause_active)) { _errno = fm_mac_set_rx_pause_frames(fm_mac_dev, rx); if (likely(_errno == 0)) mac_dev->rx_pause_active = rx; } if (unlikely(tx != mac_dev->tx_pause_active)) { _errno = fm_mac_set_tx_pause_frames(fm_mac_dev, tx); if (likely(_errno == 0)) mac_dev->tx_pause_active = tx; } return _errno; } EXPORT_SYMBOL(set_mac_active_pause); /* Determine the MAC RX/TX PAUSE frames settings based on PHY * autonegotiation or values set by eththool. */ void get_pause_cfg(struct mac_device *mac_dev, bool *rx_pause, bool *tx_pause) { struct phy_device *phy_dev = mac_dev->phy_dev; u16 lcl_adv, rmt_adv; u8 flowctrl; *rx_pause = *tx_pause = false; if (!phy_dev->duplex) return; /* If PAUSE autonegotiation is disabled, the TX/RX PAUSE settings * are those set by ethtool. */ if (!mac_dev->autoneg_pause) { *rx_pause = mac_dev->rx_pause_req; *tx_pause = mac_dev->tx_pause_req; return; } /* Else if PAUSE autonegotiation is enabled, the TX/RX PAUSE * settings depend on the result of the link negotiation. */ /* get local capabilities */ lcl_adv = 0; if (phy_dev->advertising & ADVERTISED_Pause) lcl_adv |= ADVERTISE_PAUSE_CAP; if (phy_dev->advertising & ADVERTISED_Asym_Pause) lcl_adv |= ADVERTISE_PAUSE_ASYM; /* get link partner capabilities */ rmt_adv = 0; if (phy_dev->pause) rmt_adv |= LPA_PAUSE_CAP; if (phy_dev->asym_pause) rmt_adv |= LPA_PAUSE_ASYM; /* Calculate TX/RX settings based on local and peer advertised * symmetric/asymmetric PAUSE capabilities. */ flowctrl = mii_resolve_flowctrl_fdx(lcl_adv, rmt_adv); if (flowctrl & FLOW_CTRL_RX) *rx_pause = true; if (flowctrl & FLOW_CTRL_TX) *tx_pause = true; } EXPORT_SYMBOL(get_pause_cfg); static void adjust_link(struct net_device *net_dev) { struct dpa_priv_s *priv = netdev_priv(net_dev); struct mac_device *mac_dev = priv->mac_dev; struct phy_device *phy_dev = mac_dev->phy_dev; struct fm_mac_dev *fm_mac_dev; bool rx_pause, tx_pause; int _errno; fm_mac_dev = mac_dev->get_mac_handle(mac_dev); fm_mac_adjust_link(fm_mac_dev, phy_dev->link, phy_dev->speed, phy_dev->duplex); get_pause_cfg(mac_dev, &rx_pause, &tx_pause); _errno = set_mac_active_pause(mac_dev, rx_pause, tx_pause); if (unlikely(_errno < 0)) netdev_err(net_dev, "set_mac_active_pause() = %d\n", _errno); } /* Initializes driver's PHY state, and attaches to the PHY. * Returns 0 on success. */ static int dtsec_init_phy(struct net_device *net_dev, struct mac_device *mac_dev) { struct phy_device *phy_dev; if (!mac_dev->phy_node) phy_dev = phy_connect(net_dev, mac_dev->fixed_bus_id, &adjust_link, mac_dev->phy_if); else phy_dev = of_phy_connect(net_dev, mac_dev->phy_node, &adjust_link, 0, mac_dev->phy_if); if (unlikely(phy_dev == NULL) || IS_ERR(phy_dev)) { netdev_err(net_dev, "Could not connect to PHY %s\n", mac_dev->phy_node ? mac_dev->phy_node->full_name : mac_dev->fixed_bus_id); return phy_dev == NULL ? -ENODEV : PTR_ERR(phy_dev); } /* Remove any features not supported by the controller */ phy_dev->supported &= mac_dev->if_support; /* Enable the symmetric and asymmetric PAUSE frame advertisements, * as most of the PHY drivers do not enable them by default. */ phy_dev->supported |= (SUPPORTED_Pause | SUPPORTED_Asym_Pause); phy_dev->advertising = phy_dev->supported; mac_dev->phy_dev = phy_dev; return 0; } static int xgmac_init_phy(struct net_device *net_dev, struct mac_device *mac_dev) { struct phy_device *phy_dev; if (!mac_dev->phy_node) phy_dev = phy_attach(net_dev, mac_dev->fixed_bus_id, mac_dev->phy_if); else phy_dev = of_phy_attach(net_dev, mac_dev->phy_node, 0, mac_dev->phy_if); if (unlikely(phy_dev == NULL) || IS_ERR(phy_dev)) { netdev_err(net_dev, "Could not attach to PHY %s\n", mac_dev->phy_node ? mac_dev->phy_node->full_name : mac_dev->fixed_bus_id); return phy_dev == NULL ? -ENODEV : PTR_ERR(phy_dev); } phy_dev->supported &= mac_dev->if_support; /* Enable the symmetric and asymmetric PAUSE frame advertisements, * as most of the PHY drivers do not enable them by default. */ phy_dev->supported |= (SUPPORTED_Pause | SUPPORTED_Asym_Pause); phy_dev->advertising = phy_dev->supported; mac_dev->phy_dev = phy_dev; return 0; } static int memac_init_phy(struct net_device *net_dev, struct mac_device *mac_dev) { struct phy_device *phy_dev; if ((macdev2enetinterface(mac_dev) == e_ENET_MODE_XGMII_10000) || (macdev2enetinterface(mac_dev) == e_ENET_MODE_SGMII_2500)){ if (!mac_dev->phy_node) { mac_dev->phy_dev = NULL; return 0; } else phy_dev = of_phy_attach(net_dev, mac_dev->phy_node, 0, mac_dev->phy_if); } else { if (!mac_dev->phy_node) phy_dev = phy_connect(net_dev, mac_dev->fixed_bus_id, &adjust_link, mac_dev->phy_if); else phy_dev = of_phy_connect(net_dev, mac_dev->phy_node, &adjust_link, 0, mac_dev->phy_if); } if (unlikely(phy_dev == NULL) || IS_ERR(phy_dev)) { netdev_err(net_dev, "Could not connect to PHY %s\n", mac_dev->phy_node ? mac_dev->phy_node->full_name : mac_dev->fixed_bus_id); return phy_dev == NULL ? -ENODEV : PTR_ERR(phy_dev); } /* Remove any features not supported by the controller */ phy_dev->supported &= mac_dev->if_support; /* Enable the symmetric and asymmetric PAUSE frame advertisements, * as most of the PHY drivers do not enable them by default. */ phy_dev->supported |= (SUPPORTED_Pause | SUPPORTED_Asym_Pause); phy_dev->advertising = phy_dev->supported; mac_dev->phy_dev = phy_dev; return 0; } static int __cold uninit(struct fm_mac_dev *fm_mac_dev) { int _errno, __errno; _errno = fm_mac_disable(fm_mac_dev); __errno = fm_mac_free(fm_mac_dev); if (unlikely(__errno < 0)) _errno = __errno; return _errno; } static struct fm_mac_dev *get_mac_handle(struct mac_device *mac_dev) { const struct mac_priv_s *priv; priv = macdev_priv(mac_dev); return priv->fm_mac; } static int dtsec_dump_regs(struct mac_device *h_mac, char *buf, int nn) { struct dtsec_regs *p_mm = (struct dtsec_regs *) h_mac->vaddr; int i = 0, n = nn; FM_DMP_SUBTITLE(buf, n, "\n"); FM_DMP_TITLE(buf, n, p_mm, "FM MAC - DTSEC-%d", h_mac->cell_index); FM_DMP_V32(buf, n, p_mm, tsec_id); FM_DMP_V32(buf, n, p_mm, tsec_id2); FM_DMP_V32(buf, n, p_mm, ievent); FM_DMP_V32(buf, n, p_mm, imask); FM_DMP_V32(buf, n, p_mm, ecntrl); FM_DMP_V32(buf, n, p_mm, ptv); FM_DMP_V32(buf, n, p_mm, tmr_ctrl); FM_DMP_V32(buf, n, p_mm, tmr_pevent); FM_DMP_V32(buf, n, p_mm, tmr_pemask); FM_DMP_V32(buf, n, p_mm, tctrl); FM_DMP_V32(buf, n, p_mm, rctrl); FM_DMP_V32(buf, n, p_mm, maccfg1); FM_DMP_V32(buf, n, p_mm, maccfg2); FM_DMP_V32(buf, n, p_mm, ipgifg); FM_DMP_V32(buf, n, p_mm, hafdup); FM_DMP_V32(buf, n, p_mm, maxfrm); FM_DMP_V32(buf, n, p_mm, macstnaddr1); FM_DMP_V32(buf, n, p_mm, macstnaddr2); for (i = 0; i < 7; ++i) { FM_DMP_V32(buf, n, p_mm, macaddr[i].exact_match1); FM_DMP_V32(buf, n, p_mm, macaddr[i].exact_match2); } FM_DMP_V32(buf, n, p_mm, car1); FM_DMP_V32(buf, n, p_mm, car2); return n; } static int xgmac_dump_regs(struct mac_device *h_mac, char *buf, int nn) { struct tgec_regs *p_mm = (struct tgec_regs *) h_mac->vaddr; int n = nn; FM_DMP_SUBTITLE(buf, n, "\n"); FM_DMP_TITLE(buf, n, p_mm, "FM MAC - TGEC -%d", h_mac->cell_index); FM_DMP_V32(buf, n, p_mm, tgec_id); FM_DMP_V32(buf, n, p_mm, command_config); FM_DMP_V32(buf, n, p_mm, mac_addr_0); FM_DMP_V32(buf, n, p_mm, mac_addr_1); FM_DMP_V32(buf, n, p_mm, maxfrm); FM_DMP_V32(buf, n, p_mm, pause_quant); FM_DMP_V32(buf, n, p_mm, rx_fifo_sections); FM_DMP_V32(buf, n, p_mm, tx_fifo_sections); FM_DMP_V32(buf, n, p_mm, rx_fifo_almost_f_e); FM_DMP_V32(buf, n, p_mm, tx_fifo_almost_f_e); FM_DMP_V32(buf, n, p_mm, hashtable_ctrl); FM_DMP_V32(buf, n, p_mm, mdio_cfg_status); FM_DMP_V32(buf, n, p_mm, mdio_command); FM_DMP_V32(buf, n, p_mm, mdio_data); FM_DMP_V32(buf, n, p_mm, mdio_regaddr); FM_DMP_V32(buf, n, p_mm, status); FM_DMP_V32(buf, n, p_mm, tx_ipg_len); FM_DMP_V32(buf, n, p_mm, mac_addr_2); FM_DMP_V32(buf, n, p_mm, mac_addr_3); FM_DMP_V32(buf, n, p_mm, rx_fifo_ptr_rd); FM_DMP_V32(buf, n, p_mm, rx_fifo_ptr_wr); FM_DMP_V32(buf, n, p_mm, tx_fifo_ptr_rd); FM_DMP_V32(buf, n, p_mm, tx_fifo_ptr_wr); FM_DMP_V32(buf, n, p_mm, imask); FM_DMP_V32(buf, n, p_mm, ievent); return n; } static int memac_dump_regs(struct mac_device *h_mac, char *buf, int nn) { struct memac_regs *p_mm = (struct memac_regs *) h_mac->vaddr; int i = 0, n = nn; FM_DMP_SUBTITLE(buf, n, "\n"); FM_DMP_TITLE(buf, n, p_mm, "FM MAC - MEMAC -%d", h_mac->cell_index); FM_DMP_V32(buf, n, p_mm, command_config); FM_DMP_V32(buf, n, p_mm, mac_addr0.mac_addr_l); FM_DMP_V32(buf, n, p_mm, mac_addr0.mac_addr_u); FM_DMP_V32(buf, n, p_mm, maxfrm); FM_DMP_V32(buf, n, p_mm, hashtable_ctrl); FM_DMP_V32(buf, n, p_mm, ievent); FM_DMP_V32(buf, n, p_mm, tx_ipg_length); FM_DMP_V32(buf, n, p_mm, imask); for (i = 0; i < 4; ++i) FM_DMP_V32(buf, n, p_mm, pause_quanta[i]); for (i = 0; i < 4; ++i) FM_DMP_V32(buf, n, p_mm, pause_thresh[i]); FM_DMP_V32(buf, n, p_mm, rx_pause_status); for (i = 0; i < MEMAC_NUM_OF_PADDRS; ++i) { FM_DMP_V32(buf, n, p_mm, mac_addr[i].mac_addr_l); FM_DMP_V32(buf, n, p_mm, mac_addr[i].mac_addr_u); } FM_DMP_V32(buf, n, p_mm, lpwake_timer); FM_DMP_V32(buf, n, p_mm, sleep_timer); FM_DMP_V32(buf, n, p_mm, statn_config); FM_DMP_V32(buf, n, p_mm, if_mode); FM_DMP_V32(buf, n, p_mm, if_status); FM_DMP_V32(buf, n, p_mm, hg_config); FM_DMP_V32(buf, n, p_mm, hg_pause_quanta); FM_DMP_V32(buf, n, p_mm, hg_pause_thresh); FM_DMP_V32(buf, n, p_mm, hgrx_pause_status); FM_DMP_V32(buf, n, p_mm, hg_fifos_status); FM_DMP_V32(buf, n, p_mm, rhm); FM_DMP_V32(buf, n, p_mm, thm); return n; } static int memac_dump_regs_rx(struct mac_device *h_mac, char *buf, int nn) { struct memac_regs *p_mm = (struct memac_regs *) h_mac->vaddr; int n = nn; FM_DMP_SUBTITLE(buf, n, "\n"); FM_DMP_TITLE(buf, n, p_mm, "FM MAC - MEMAC -%d Rx stats", h_mac->cell_index); /* Rx Statistics Counter */ FM_DMP_V32(buf, n, p_mm, reoct_l); FM_DMP_V32(buf, n, p_mm, reoct_u); FM_DMP_V32(buf, n, p_mm, roct_l); FM_DMP_V32(buf, n, p_mm, roct_u); FM_DMP_V32(buf, n, p_mm, raln_l); FM_DMP_V32(buf, n, p_mm, raln_u); FM_DMP_V32(buf, n, p_mm, rxpf_l); FM_DMP_V32(buf, n, p_mm, rxpf_u); FM_DMP_V32(buf, n, p_mm, rfrm_l); FM_DMP_V32(buf, n, p_mm, rfrm_u); FM_DMP_V32(buf, n, p_mm, rfcs_l); FM_DMP_V32(buf, n, p_mm, rfcs_u); FM_DMP_V32(buf, n, p_mm, rvlan_l); FM_DMP_V32(buf, n, p_mm, rvlan_u); FM_DMP_V32(buf, n, p_mm, rerr_l); FM_DMP_V32(buf, n, p_mm, rerr_u); FM_DMP_V32(buf, n, p_mm, ruca_l); FM_DMP_V32(buf, n, p_mm, ruca_u); FM_DMP_V32(buf, n, p_mm, rmca_l); FM_DMP_V32(buf, n, p_mm, rmca_u); FM_DMP_V32(buf, n, p_mm, rbca_l); FM_DMP_V32(buf, n, p_mm, rbca_u); FM_DMP_V32(buf, n, p_mm, rdrp_l); FM_DMP_V32(buf, n, p_mm, rdrp_u); FM_DMP_V32(buf, n, p_mm, rpkt_l); FM_DMP_V32(buf, n, p_mm, rpkt_u); FM_DMP_V32(buf, n, p_mm, rund_l); FM_DMP_V32(buf, n, p_mm, rund_u); FM_DMP_V32(buf, n, p_mm, r64_l); FM_DMP_V32(buf, n, p_mm, r64_u); FM_DMP_V32(buf, n, p_mm, r127_l); FM_DMP_V32(buf, n, p_mm, r127_u); FM_DMP_V32(buf, n, p_mm, r255_l); FM_DMP_V32(buf, n, p_mm, r255_u); FM_DMP_V32(buf, n, p_mm, r511_l); FM_DMP_V32(buf, n, p_mm, r511_u); FM_DMP_V32(buf, n, p_mm, r1023_l); FM_DMP_V32(buf, n, p_mm, r1023_u); FM_DMP_V32(buf, n, p_mm, r1518_l); FM_DMP_V32(buf, n, p_mm, r1518_u); FM_DMP_V32(buf, n, p_mm, r1519x_l); FM_DMP_V32(buf, n, p_mm, r1519x_u); FM_DMP_V32(buf, n, p_mm, rovr_l); FM_DMP_V32(buf, n, p_mm, rovr_u); FM_DMP_V32(buf, n, p_mm, rjbr_l); FM_DMP_V32(buf, n, p_mm, rjbr_u); FM_DMP_V32(buf, n, p_mm, rfrg_l); FM_DMP_V32(buf, n, p_mm, rfrg_u); FM_DMP_V32(buf, n, p_mm, rcnp_l); FM_DMP_V32(buf, n, p_mm, rcnp_u); FM_DMP_V32(buf, n, p_mm, rdrntp_l); FM_DMP_V32(buf, n, p_mm, rdrntp_u); return n; } static int memac_dump_regs_tx(struct mac_device *h_mac, char *buf, int nn) { struct memac_regs *p_mm = (struct memac_regs *) h_mac->vaddr; int n = nn; FM_DMP_SUBTITLE(buf, n, "\n"); FM_DMP_TITLE(buf, n, p_mm, "FM MAC - MEMAC -%d Tx stats", h_mac->cell_index); /* Tx Statistics Counter */ FM_DMP_V32(buf, n, p_mm, teoct_l); FM_DMP_V32(buf, n, p_mm, teoct_u); FM_DMP_V32(buf, n, p_mm, toct_l); FM_DMP_V32(buf, n, p_mm, toct_u); FM_DMP_V32(buf, n, p_mm, txpf_l); FM_DMP_V32(buf, n, p_mm, txpf_u); FM_DMP_V32(buf, n, p_mm, tfrm_l); FM_DMP_V32(buf, n, p_mm, tfrm_u); FM_DMP_V32(buf, n, p_mm, tfcs_l); FM_DMP_V32(buf, n, p_mm, tfcs_u); FM_DMP_V32(buf, n, p_mm, tvlan_l); FM_DMP_V32(buf, n, p_mm, tvlan_u); FM_DMP_V32(buf, n, p_mm, terr_l); FM_DMP_V32(buf, n, p_mm, terr_u); FM_DMP_V32(buf, n, p_mm, tuca_l); FM_DMP_V32(buf, n, p_mm, tuca_u); FM_DMP_V32(buf, n, p_mm, tmca_l); FM_DMP_V32(buf, n, p_mm, tmca_u); FM_DMP_V32(buf, n, p_mm, tbca_l); FM_DMP_V32(buf, n, p_mm, tbca_u); FM_DMP_V32(buf, n, p_mm, tpkt_l); FM_DMP_V32(buf, n, p_mm, tpkt_u); FM_DMP_V32(buf, n, p_mm, tund_l); FM_DMP_V32(buf, n, p_mm, tund_u); FM_DMP_V32(buf, n, p_mm, t64_l); FM_DMP_V32(buf, n, p_mm, t64_u); FM_DMP_V32(buf, n, p_mm, t127_l); FM_DMP_V32(buf, n, p_mm, t127_u); FM_DMP_V32(buf, n, p_mm, t255_l); FM_DMP_V32(buf, n, p_mm, t255_u); FM_DMP_V32(buf, n, p_mm, t511_l); FM_DMP_V32(buf, n, p_mm, t511_u); FM_DMP_V32(buf, n, p_mm, t1023_l); FM_DMP_V32(buf, n, p_mm, t1023_u); FM_DMP_V32(buf, n, p_mm, t1518_l); FM_DMP_V32(buf, n, p_mm, t1518_u); FM_DMP_V32(buf, n, p_mm, t1519x_l); FM_DMP_V32(buf, n, p_mm, t1519x_u); FM_DMP_V32(buf, n, p_mm, tcnp_l); FM_DMP_V32(buf, n, p_mm, tcnp_u); return n; } int fm_mac_dump_regs(struct mac_device *h_mac, char *buf, int nn) { int n = nn; n = h_mac->dump_mac_regs(h_mac, buf, n); return n; } EXPORT_SYMBOL(fm_mac_dump_regs); int fm_mac_dump_rx_stats(struct mac_device *h_mac, char *buf, int nn) { int n = nn; if(h_mac->dump_mac_rx_stats) n = h_mac->dump_mac_rx_stats(h_mac, buf, n); return n; } EXPORT_SYMBOL(fm_mac_dump_rx_stats); int fm_mac_dump_tx_stats(struct mac_device *h_mac, char *buf, int nn) { int n = nn; if(h_mac->dump_mac_tx_stats) n = h_mac->dump_mac_tx_stats(h_mac, buf, n); return n; } EXPORT_SYMBOL(fm_mac_dump_tx_stats); static void __cold setup_dtsec(struct mac_device *mac_dev) { mac_dev->init_phy = dtsec_init_phy; mac_dev->init = init; mac_dev->start = start; mac_dev->stop = stop; mac_dev->set_promisc = fm_mac_set_promiscuous; mac_dev->change_addr = fm_mac_modify_mac_addr; mac_dev->set_multi = set_multi; mac_dev->uninit = uninit; mac_dev->ptp_enable = fm_mac_enable_1588_time_stamp; mac_dev->ptp_disable = fm_mac_disable_1588_time_stamp; mac_dev->get_mac_handle = get_mac_handle; mac_dev->set_tx_pause = fm_mac_set_tx_pause_frames; mac_dev->set_rx_pause = fm_mac_set_rx_pause_frames; mac_dev->fm_rtc_enable = fm_rtc_enable; mac_dev->fm_rtc_disable = fm_rtc_disable; mac_dev->fm_rtc_get_cnt = fm_rtc_get_cnt; mac_dev->fm_rtc_set_cnt = fm_rtc_set_cnt; mac_dev->fm_rtc_get_drift = fm_rtc_get_drift; mac_dev->fm_rtc_set_drift = fm_rtc_set_drift; mac_dev->fm_rtc_set_alarm = fm_rtc_set_alarm; mac_dev->fm_rtc_set_fiper = fm_rtc_set_fiper; mac_dev->set_wol = fm_mac_set_wol; mac_dev->dump_mac_regs = dtsec_dump_regs; } static void __cold setup_xgmac(struct mac_device *mac_dev) { mac_dev->init_phy = xgmac_init_phy; mac_dev->init = init; mac_dev->start = start; mac_dev->stop = stop; mac_dev->set_promisc = fm_mac_set_promiscuous; mac_dev->change_addr = fm_mac_modify_mac_addr; mac_dev->set_multi = set_multi; mac_dev->uninit = uninit; mac_dev->get_mac_handle = get_mac_handle; mac_dev->set_tx_pause = fm_mac_set_tx_pause_frames; mac_dev->set_rx_pause = fm_mac_set_rx_pause_frames; mac_dev->set_wol = fm_mac_set_wol; mac_dev->dump_mac_regs = xgmac_dump_regs; } static void __cold setup_memac(struct mac_device *mac_dev) { mac_dev->init_phy = memac_init_phy; mac_dev->init = memac_init; mac_dev->start = start; mac_dev->stop = stop; mac_dev->set_promisc = fm_mac_set_promiscuous; mac_dev->change_addr = fm_mac_modify_mac_addr; mac_dev->set_multi = set_multi; mac_dev->uninit = uninit; mac_dev->get_mac_handle = get_mac_handle; mac_dev->set_tx_pause = fm_mac_set_tx_pause_frames; mac_dev->set_rx_pause = fm_mac_set_rx_pause_frames; mac_dev->fm_rtc_enable = fm_rtc_enable; mac_dev->fm_rtc_disable = fm_rtc_disable; mac_dev->fm_rtc_get_cnt = fm_rtc_get_cnt; mac_dev->fm_rtc_set_cnt = fm_rtc_set_cnt; mac_dev->fm_rtc_get_drift = fm_rtc_get_drift; mac_dev->fm_rtc_set_drift = fm_rtc_set_drift; mac_dev->fm_rtc_set_alarm = fm_rtc_set_alarm; mac_dev->fm_rtc_set_fiper = fm_rtc_set_fiper; mac_dev->set_wol = fm_mac_set_wol; mac_dev->dump_mac_regs = memac_dump_regs; mac_dev->dump_mac_rx_stats = memac_dump_regs_rx; mac_dev->dump_mac_tx_stats = memac_dump_regs_tx; } void (*const mac_setup[])(struct mac_device *mac_dev) = { [DTSEC] = setup_dtsec, [XGMAC] = setup_xgmac, [MEMAC] = setup_memac };