// SPDX-License-Identifier: GPL-2.0+ /* * sh_eth.c - Driver for Renesas ethernet controller. * * Copyright (C) 2008, 2011 Renesas Solutions Corp. * Copyright (c) 2008, 2011, 2014 2014 Nobuhiro Iwamatsu * Copyright (c) 2007 Carlos Munoz * Copyright (C) 2013, 2014 Renesas Electronics Corporation */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "sh_eth.h" #ifndef CFG_SH_ETHER_USE_PORT # error "Please define CFG_SH_ETHER_USE_PORT" #endif #ifndef CFG_SH_ETHER_PHY_ADDR # error "Please define CFG_SH_ETHER_PHY_ADDR" #endif #if defined(CFG_SH_ETHER_CACHE_WRITEBACK) && \ !CONFIG_IS_ENABLED(SYS_DCACHE_OFF) #define flush_cache_wback(addr, len) \ flush_dcache_range((unsigned long)addr, \ (unsigned long)(addr + ALIGN(len, CFG_SH_ETHER_ALIGNE_SIZE))) #else #define flush_cache_wback(...) #endif #if defined(CFG_SH_ETHER_CACHE_INVALIDATE) && defined(CONFIG_ARM) #define invalidate_cache(addr, len) \ { \ unsigned long line_size = CFG_SH_ETHER_ALIGNE_SIZE; \ unsigned long start, end; \ \ start = (unsigned long)addr; \ end = start + len; \ start &= ~(line_size - 1); \ end = ((end + line_size - 1) & ~(line_size - 1)); \ \ invalidate_dcache_range(start, end); \ } #else #define invalidate_cache(...) #endif #define TIMEOUT_CNT 1000 static int sh_eth_send_common(struct sh_eth_dev *eth, void *packet, int len) { int ret = 0, timeout; struct sh_eth_info *port_info = ð->port_info[eth->port]; if (!packet || len > 0xffff) { printf(SHETHER_NAME ": %s: Invalid argument\n", __func__); ret = -EINVAL; goto err; } /* packet must be a 4 byte boundary */ if ((uintptr_t)packet & 3) { printf(SHETHER_NAME ": %s: packet not 4 byte aligned\n" , __func__); ret = -EFAULT; goto err; } /* Update tx descriptor */ flush_cache_wback(packet, len); port_info->tx_desc_cur->td2 = ADDR_TO_PHY(packet); port_info->tx_desc_cur->td1 = len << 16; /* Must preserve the end of descriptor list indication */ if (port_info->tx_desc_cur->td0 & TD_TDLE) port_info->tx_desc_cur->td0 = TD_TACT | TD_TFP | TD_TDLE; else port_info->tx_desc_cur->td0 = TD_TACT | TD_TFP; flush_cache_wback(port_info->tx_desc_cur, sizeof(struct tx_desc_s)); /* Restart the transmitter if disabled */ if (!(sh_eth_read(port_info, EDTRR) & EDTRR_TRNS)) sh_eth_write(port_info, EDTRR_TRNS, EDTRR); /* Wait until packet is transmitted */ timeout = TIMEOUT_CNT; do { invalidate_cache(port_info->tx_desc_cur, sizeof(struct tx_desc_s)); udelay(100); } while (port_info->tx_desc_cur->td0 & TD_TACT && timeout--); if (timeout < 0) { printf(SHETHER_NAME ": transmit timeout\n"); ret = -ETIMEDOUT; goto err; } port_info->tx_desc_cur++; if (port_info->tx_desc_cur >= port_info->tx_desc_base + NUM_TX_DESC) port_info->tx_desc_cur = port_info->tx_desc_base; err: return ret; } static int sh_eth_recv_start(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; /* Check if the rx descriptor is ready */ invalidate_cache(port_info->rx_desc_cur, sizeof(struct rx_desc_s)); if (port_info->rx_desc_cur->rd0 & RD_RACT) return -EAGAIN; /* Check for errors */ if (port_info->rx_desc_cur->rd0 & RD_RFE) return 0; return port_info->rx_desc_cur->rd1 & 0xffff; } static void sh_eth_recv_finish(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; invalidate_cache(ADDR_TO_P2(port_info->rx_desc_cur->rd2), MAX_BUF_SIZE); /* Make current descriptor available again */ if (port_info->rx_desc_cur->rd0 & RD_RDLE) port_info->rx_desc_cur->rd0 = RD_RACT | RD_RDLE; else port_info->rx_desc_cur->rd0 = RD_RACT; flush_cache_wback(port_info->rx_desc_cur, sizeof(struct rx_desc_s)); /* Point to the next descriptor */ port_info->rx_desc_cur++; if (port_info->rx_desc_cur >= port_info->rx_desc_base + NUM_RX_DESC) port_info->rx_desc_cur = port_info->rx_desc_base; } static int sh_eth_reset(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; #if defined(SH_ETH_TYPE_GETHER) || defined(SH_ETH_TYPE_RZ) int ret = 0, i; /* Start e-dmac transmitter and receiver */ sh_eth_write(port_info, EDSR_ENALL, EDSR); /* Perform a software reset and wait for it to complete */ sh_eth_write(port_info, EDMR_SRST, EDMR); for (i = 0; i < TIMEOUT_CNT; i++) { if (!(sh_eth_read(port_info, EDMR) & EDMR_SRST)) break; udelay(1000); } if (i == TIMEOUT_CNT) { printf(SHETHER_NAME ": Software reset timeout\n"); ret = -EIO; } return ret; #else sh_eth_write(port_info, sh_eth_read(port_info, EDMR) | EDMR_SRST, EDMR); mdelay(3); sh_eth_write(port_info, sh_eth_read(port_info, EDMR) & ~EDMR_SRST, EDMR); return 0; #endif } static int sh_eth_tx_desc_init(struct sh_eth_dev *eth) { int i, ret = 0; u32 alloc_desc_size = NUM_TX_DESC * sizeof(struct tx_desc_s); struct sh_eth_info *port_info = ð->port_info[eth->port]; struct tx_desc_s *cur_tx_desc; /* * Allocate rx descriptors. They must be aligned to size of struct * tx_desc_s. */ port_info->tx_desc_alloc = memalign(sizeof(struct tx_desc_s), alloc_desc_size); if (!port_info->tx_desc_alloc) { printf(SHETHER_NAME ": memalign failed\n"); ret = -ENOMEM; goto err; } /* Make sure we use a P2 address (non-cacheable) */ port_info->tx_desc_base = (struct tx_desc_s *)ADDR_TO_P2((uintptr_t)port_info->tx_desc_alloc); port_info->tx_desc_cur = port_info->tx_desc_base; /* Initialize all descriptors */ for (cur_tx_desc = port_info->tx_desc_base, i = 0; i < NUM_TX_DESC; cur_tx_desc++, i++) { cur_tx_desc->td0 = 0x00; cur_tx_desc->td1 = 0x00; cur_tx_desc->td2 = 0x00; } /* Mark the end of the descriptors */ cur_tx_desc--; cur_tx_desc->td0 |= TD_TDLE; flush_cache_wback(port_info->tx_desc_alloc, alloc_desc_size); /* * Point the controller to the tx descriptor list. Must use physical * addresses */ sh_eth_write(port_info, ADDR_TO_PHY(port_info->tx_desc_base), TDLAR); #if defined(SH_ETH_TYPE_GETHER) || defined(SH_ETH_TYPE_RZ) sh_eth_write(port_info, ADDR_TO_PHY(port_info->tx_desc_base), TDFAR); sh_eth_write(port_info, ADDR_TO_PHY(cur_tx_desc), TDFXR); sh_eth_write(port_info, 0x01, TDFFR);/* Last discriptor bit */ #endif err: return ret; } static int sh_eth_rx_desc_init(struct sh_eth_dev *eth) { int i, ret = 0; u32 alloc_desc_size = NUM_RX_DESC * sizeof(struct rx_desc_s); struct sh_eth_info *port_info = ð->port_info[eth->port]; struct rx_desc_s *cur_rx_desc; u8 *rx_buf; /* * Allocate rx descriptors. They must be aligned to size of struct * rx_desc_s. */ port_info->rx_desc_alloc = memalign(sizeof(struct rx_desc_s), alloc_desc_size); if (!port_info->rx_desc_alloc) { printf(SHETHER_NAME ": memalign failed\n"); ret = -ENOMEM; goto err; } /* Make sure we use a P2 address (non-cacheable) */ port_info->rx_desc_base = (struct rx_desc_s *)ADDR_TO_P2((uintptr_t)port_info->rx_desc_alloc); port_info->rx_desc_cur = port_info->rx_desc_base; /* * Allocate rx data buffers. They must be RX_BUF_ALIGNE_SIZE bytes * aligned and in P2 area. */ port_info->rx_buf_alloc = memalign(RX_BUF_ALIGNE_SIZE, NUM_RX_DESC * MAX_BUF_SIZE); if (!port_info->rx_buf_alloc) { printf(SHETHER_NAME ": alloc failed\n"); ret = -ENOMEM; goto err_buf_alloc; } port_info->rx_buf_base = (u8 *)ADDR_TO_P2((uintptr_t)port_info->rx_buf_alloc); /* Initialize all descriptors */ for (cur_rx_desc = port_info->rx_desc_base, rx_buf = port_info->rx_buf_base, i = 0; i < NUM_RX_DESC; cur_rx_desc++, rx_buf += MAX_BUF_SIZE, i++) { cur_rx_desc->rd0 = RD_RACT; cur_rx_desc->rd1 = MAX_BUF_SIZE << 16; cur_rx_desc->rd2 = (u32)ADDR_TO_PHY(rx_buf); } /* Mark the end of the descriptors */ cur_rx_desc--; cur_rx_desc->rd0 |= RD_RDLE; invalidate_cache(port_info->rx_buf_alloc, NUM_RX_DESC * MAX_BUF_SIZE); flush_cache_wback(port_info->rx_desc_alloc, alloc_desc_size); /* Point the controller to the rx descriptor list */ sh_eth_write(port_info, ADDR_TO_PHY(port_info->rx_desc_base), RDLAR); #if defined(SH_ETH_TYPE_GETHER) || defined(SH_ETH_TYPE_RZ) sh_eth_write(port_info, ADDR_TO_PHY(port_info->rx_desc_base), RDFAR); sh_eth_write(port_info, ADDR_TO_PHY(cur_rx_desc), RDFXR); sh_eth_write(port_info, RDFFR_RDLF, RDFFR); #endif return ret; err_buf_alloc: free(port_info->rx_desc_alloc); port_info->rx_desc_alloc = NULL; err: return ret; } static void sh_eth_tx_desc_free(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; if (port_info->tx_desc_alloc) { free(port_info->tx_desc_alloc); port_info->tx_desc_alloc = NULL; } } static void sh_eth_rx_desc_free(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; if (port_info->rx_desc_alloc) { free(port_info->rx_desc_alloc); port_info->rx_desc_alloc = NULL; } if (port_info->rx_buf_alloc) { free(port_info->rx_buf_alloc); port_info->rx_buf_alloc = NULL; } } static int sh_eth_desc_init(struct sh_eth_dev *eth) { int ret = 0; ret = sh_eth_tx_desc_init(eth); if (ret) goto err_tx_init; ret = sh_eth_rx_desc_init(eth); if (ret) goto err_rx_init; return ret; err_rx_init: sh_eth_tx_desc_free(eth); err_tx_init: return ret; } static void sh_eth_write_hwaddr(struct sh_eth_info *port_info, unsigned char *mac) { u32 val; val = (mac[0] << 24) | (mac[1] << 16) | (mac[2] << 8) | mac[3]; sh_eth_write(port_info, val, MAHR); val = (mac[4] << 8) | mac[5]; sh_eth_write(port_info, val, MALR); } static void sh_eth_mac_regs_config(struct sh_eth_dev *eth, unsigned char *mac) { struct sh_eth_info *port_info = ð->port_info[eth->port]; unsigned long edmr; /* Configure e-dmac registers */ edmr = sh_eth_read(port_info, EDMR); edmr &= ~EMDR_DESC_R; edmr |= EMDR_DESC | EDMR_EL; #if defined(CONFIG_R8A77980) edmr |= EDMR_NBST; #endif sh_eth_write(port_info, edmr, EDMR); sh_eth_write(port_info, 0, EESIPR); sh_eth_write(port_info, 0, TRSCER); sh_eth_write(port_info, 0, TFTR); sh_eth_write(port_info, (FIFO_SIZE_T | FIFO_SIZE_R), FDR); sh_eth_write(port_info, RMCR_RST, RMCR); #if defined(SH_ETH_TYPE_GETHER) || defined(SH_ETH_TYPE_RZ) sh_eth_write(port_info, 0, RPADIR); #endif sh_eth_write(port_info, (FIFO_F_D_RFF | FIFO_F_D_RFD), FCFTR); /* Configure e-mac registers */ sh_eth_write(port_info, 0, ECSIPR); /* Set Mac address */ sh_eth_write_hwaddr(port_info, mac); sh_eth_write(port_info, RFLR_RFL_MIN, RFLR); #if defined(SH_ETH_TYPE_GETHER) sh_eth_write(port_info, 0, PIPR); #endif #if defined(SH_ETH_TYPE_GETHER) || defined(SH_ETH_TYPE_RZ) sh_eth_write(port_info, APR_AP, APR); sh_eth_write(port_info, MPR_MP, MPR); sh_eth_write(port_info, TPAUSER_TPAUSE, TPAUSER); #endif #if defined(CONFIG_CPU_SH7734) || defined(CONFIG_R8A7740) sh_eth_write(port_info, CONFIG_SH_ETHER_SH7734_MII, RMII_MII); #elif defined(CONFIG_RCAR_GEN2) || defined(CONFIG_R8A77980) sh_eth_write(port_info, sh_eth_read(port_info, RMIIMR) | 0x1, RMIIMR); #endif } static int sh_eth_phy_regs_config(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; struct phy_device *phy = port_info->phydev; int ret = 0; u32 val = 0; /* Set the transfer speed */ if (phy->speed == 100) { printf(SHETHER_NAME ": 100Base/"); #if defined(SH_ETH_TYPE_GETHER) sh_eth_write(port_info, GECMR_100B, GECMR); #elif defined(CONFIG_CPU_SH7757) || defined(CONFIG_CPU_SH7752) sh_eth_write(port_info, 1, RTRATE); #elif defined(CONFIG_RCAR_GEN2) || defined(CONFIG_R8A77980) val = ECMR_RTM; #endif } else if (phy->speed == 10) { printf(SHETHER_NAME ": 10Base/"); #if defined(SH_ETH_TYPE_GETHER) sh_eth_write(port_info, GECMR_10B, GECMR); #elif defined(CONFIG_CPU_SH7757) || defined(CONFIG_CPU_SH7752) sh_eth_write(port_info, 0, RTRATE); #endif } #if defined(SH_ETH_TYPE_GETHER) else if (phy->speed == 1000) { printf(SHETHER_NAME ": 1000Base/"); sh_eth_write(port_info, GECMR_1000B, GECMR); } #endif /* Check if full duplex mode is supported by the phy */ if (phy->duplex) { printf("Full\n"); sh_eth_write(port_info, val | (ECMR_CHG_DM | ECMR_RE | ECMR_TE | ECMR_DM), ECMR); } else { printf("Half\n"); sh_eth_write(port_info, val | (ECMR_CHG_DM | ECMR_RE | ECMR_TE), ECMR); } return ret; } static void sh_eth_start(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; /* * Enable the e-dmac receiver only. The transmitter will be enabled when * we have something to transmit */ sh_eth_write(port_info, EDRRR_R, EDRRR); } static void sh_eth_stop(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; sh_eth_write(port_info, ~EDRRR_R, EDRRR); } static int sh_eth_init_common(struct sh_eth_dev *eth, unsigned char *mac) { int ret = 0; ret = sh_eth_reset(eth); if (ret) return ret; ret = sh_eth_desc_init(eth); if (ret) return ret; sh_eth_mac_regs_config(eth, mac); return 0; } static int sh_eth_start_common(struct sh_eth_dev *eth) { struct sh_eth_info *port_info = ð->port_info[eth->port]; int ret; ret = phy_startup(port_info->phydev); if (ret) { printf(SHETHER_NAME ": phy startup failure\n"); return ret; } ret = sh_eth_phy_regs_config(eth); if (ret) return ret; sh_eth_start(eth); return 0; } struct sh_ether_priv { struct sh_eth_dev shdev; struct mii_dev *bus; phys_addr_t iobase; struct clk clk; }; static int sh_ether_send(struct udevice *dev, void *packet, int len) { struct sh_ether_priv *priv = dev_get_priv(dev); struct sh_eth_dev *eth = &priv->shdev; return sh_eth_send_common(eth, packet, len); } static int sh_ether_recv(struct udevice *dev, int flags, uchar **packetp) { struct sh_ether_priv *priv = dev_get_priv(dev); struct sh_eth_dev *eth = &priv->shdev; struct sh_eth_info *port_info = ð->port_info[eth->port]; uchar *packet = (uchar *)ADDR_TO_P2((uintptr_t)port_info->rx_desc_cur->rd2); int len; len = sh_eth_recv_start(eth); if (len > 0) { invalidate_cache(packet, len); *packetp = packet; return len; } /* Restart the receiver if disabled */ if (!(sh_eth_read(port_info, EDRRR) & EDRRR_R)) sh_eth_write(port_info, EDRRR_R, EDRRR); return len; } static int sh_ether_free_pkt(struct udevice *dev, uchar *packet, int length) { struct sh_ether_priv *priv = dev_get_priv(dev); struct sh_eth_dev *eth = &priv->shdev; struct sh_eth_info *port_info = ð->port_info[eth->port]; sh_eth_recv_finish(eth); /* Restart the receiver if disabled */ if (!(sh_eth_read(port_info, EDRRR) & EDRRR_R)) sh_eth_write(port_info, EDRRR_R, EDRRR); return 0; } static int sh_ether_write_hwaddr(struct udevice *dev) { struct sh_ether_priv *priv = dev_get_priv(dev); struct sh_eth_dev *eth = &priv->shdev; struct sh_eth_info *port_info = ð->port_info[eth->port]; struct eth_pdata *pdata = dev_get_plat(dev); sh_eth_write_hwaddr(port_info, pdata->enetaddr); return 0; } static int sh_eth_phy_config(struct udevice *dev) { struct sh_ether_priv *priv = dev_get_priv(dev); struct eth_pdata *pdata = dev_get_plat(dev); struct sh_eth_dev *eth = &priv->shdev; int ret = 0; struct sh_eth_info *port_info = ð->port_info[eth->port]; struct phy_device *phydev; phydev = phy_connect(priv->bus, -1, dev, pdata->phy_interface); if (!phydev) return -ENODEV; port_info->phydev = phydev; phy_config(phydev); return ret; } static int sh_ether_start(struct udevice *dev) { struct sh_ether_priv *priv = dev_get_priv(dev); struct eth_pdata *pdata = dev_get_plat(dev); struct sh_eth_dev *eth = &priv->shdev; int ret; ret = sh_eth_init_common(eth, pdata->enetaddr); if (ret) return ret; ret = sh_eth_start_common(eth); if (ret) goto err_start; return 0; err_start: sh_eth_tx_desc_free(eth); sh_eth_rx_desc_free(eth); return ret; } static void sh_ether_stop(struct udevice *dev) { struct sh_ether_priv *priv = dev_get_priv(dev); struct sh_eth_dev *eth = &priv->shdev; struct sh_eth_info *port_info = ð->port_info[eth->port]; phy_shutdown(port_info->phydev); sh_eth_stop(&priv->shdev); } static int sh_ether_probe(struct udevice *udev) { struct eth_pdata *pdata = dev_get_plat(udev); struct sh_ether_priv *priv = dev_get_priv(udev); struct sh_eth_dev *eth = &priv->shdev; struct mii_dev *mdiodev; int ret; priv->iobase = pdata->iobase; #if CONFIG_IS_ENABLED(CLK) ret = clk_get_by_index(udev, 0, &priv->clk); if (ret < 0) return ret; #endif mdiodev = mdio_alloc(); if (!mdiodev) { ret = -ENOMEM; return ret; } mdiodev->read = bb_miiphy_read; mdiodev->write = bb_miiphy_write; bb_miiphy_buses[0].priv = eth; snprintf(mdiodev->name, sizeof(mdiodev->name), udev->name); ret = mdio_register(mdiodev); if (ret < 0) goto err_mdio_register; priv->bus = miiphy_get_dev_by_name(udev->name); eth->port = CFG_SH_ETHER_USE_PORT; eth->port_info[eth->port].phy_addr = CFG_SH_ETHER_PHY_ADDR; eth->port_info[eth->port].iobase = (void __iomem *)(uintptr_t)(BASE_IO_ADDR + 0x800 * eth->port); #if CONFIG_IS_ENABLED(CLK) ret = clk_enable(&priv->clk); if (ret) goto err_mdio_register; #endif ret = sh_eth_init_common(eth, pdata->enetaddr); if (ret) goto err_phy_config; ret = sh_eth_phy_config(udev); if (ret) { printf(SHETHER_NAME ": phy config timeout\n"); goto err_phy_config; } return 0; err_phy_config: #if CONFIG_IS_ENABLED(CLK) clk_disable(&priv->clk); #endif err_mdio_register: mdio_free(mdiodev); return ret; } static int sh_ether_remove(struct udevice *udev) { struct sh_ether_priv *priv = dev_get_priv(udev); struct sh_eth_dev *eth = &priv->shdev; struct sh_eth_info *port_info = ð->port_info[eth->port]; #if CONFIG_IS_ENABLED(CLK) clk_disable(&priv->clk); #endif free(port_info->phydev); mdio_unregister(priv->bus); mdio_free(priv->bus); return 0; } static const struct eth_ops sh_ether_ops = { .start = sh_ether_start, .send = sh_ether_send, .recv = sh_ether_recv, .free_pkt = sh_ether_free_pkt, .stop = sh_ether_stop, .write_hwaddr = sh_ether_write_hwaddr, }; int sh_ether_of_to_plat(struct udevice *dev) { struct eth_pdata *pdata = dev_get_plat(dev); const fdt32_t *cell; pdata->iobase = dev_read_addr(dev); pdata->phy_interface = dev_read_phy_mode(dev); if (pdata->phy_interface == PHY_INTERFACE_MODE_NA) return -EINVAL; pdata->max_speed = 1000; cell = fdt_getprop(gd->fdt_blob, dev_of_offset(dev), "max-speed", NULL); if (cell) pdata->max_speed = fdt32_to_cpu(*cell); sprintf(bb_miiphy_buses[0].name, dev->name); return 0; } static const struct udevice_id sh_ether_ids[] = { { .compatible = "renesas,ether-r7s72100" }, { .compatible = "renesas,ether-r8a7790" }, { .compatible = "renesas,ether-r8a7791" }, { .compatible = "renesas,ether-r8a7793" }, { .compatible = "renesas,ether-r8a7794" }, { .compatible = "renesas,gether-r8a77980" }, { } }; U_BOOT_DRIVER(eth_sh_ether) = { .name = "sh_ether", .id = UCLASS_ETH, .of_match = sh_ether_ids, .of_to_plat = sh_ether_of_to_plat, .probe = sh_ether_probe, .remove = sh_ether_remove, .ops = &sh_ether_ops, .priv_auto = sizeof(struct sh_ether_priv), .plat_auto = sizeof(struct eth_pdata), .flags = DM_FLAG_ALLOC_PRIV_DMA, }; /******* for bb_miiphy *******/ static int sh_eth_bb_init(struct bb_miiphy_bus *bus) { return 0; } static int sh_eth_bb_mdio_active(struct bb_miiphy_bus *bus) { struct sh_eth_dev *eth = bus->priv; struct sh_eth_info *port_info = ð->port_info[eth->port]; sh_eth_write(port_info, sh_eth_read(port_info, PIR) | PIR_MMD, PIR); return 0; } static int sh_eth_bb_mdio_tristate(struct bb_miiphy_bus *bus) { struct sh_eth_dev *eth = bus->priv; struct sh_eth_info *port_info = ð->port_info[eth->port]; sh_eth_write(port_info, sh_eth_read(port_info, PIR) & ~PIR_MMD, PIR); return 0; } static int sh_eth_bb_set_mdio(struct bb_miiphy_bus *bus, int v) { struct sh_eth_dev *eth = bus->priv; struct sh_eth_info *port_info = ð->port_info[eth->port]; if (v) sh_eth_write(port_info, sh_eth_read(port_info, PIR) | PIR_MDO, PIR); else sh_eth_write(port_info, sh_eth_read(port_info, PIR) & ~PIR_MDO, PIR); return 0; } static int sh_eth_bb_get_mdio(struct bb_miiphy_bus *bus, int *v) { struct sh_eth_dev *eth = bus->priv; struct sh_eth_info *port_info = ð->port_info[eth->port]; *v = (sh_eth_read(port_info, PIR) & PIR_MDI) >> 3; return 0; } static int sh_eth_bb_set_mdc(struct bb_miiphy_bus *bus, int v) { struct sh_eth_dev *eth = bus->priv; struct sh_eth_info *port_info = ð->port_info[eth->port]; if (v) sh_eth_write(port_info, sh_eth_read(port_info, PIR) | PIR_MDC, PIR); else sh_eth_write(port_info, sh_eth_read(port_info, PIR) & ~PIR_MDC, PIR); return 0; } static int sh_eth_bb_delay(struct bb_miiphy_bus *bus) { udelay(10); return 0; } struct bb_miiphy_bus bb_miiphy_buses[] = { { .name = "sh_eth", .init = sh_eth_bb_init, .mdio_active = sh_eth_bb_mdio_active, .mdio_tristate = sh_eth_bb_mdio_tristate, .set_mdio = sh_eth_bb_set_mdio, .get_mdio = sh_eth_bb_get_mdio, .set_mdc = sh_eth_bb_set_mdc, .delay = sh_eth_bb_delay, } }; int bb_miiphy_buses_num = ARRAY_SIZE(bb_miiphy_buses);