/* * Copyright 2009-2012 Freescale Semiconductor, Inc. * Dave Liu * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include #include #include #include #include #include #include #include #include #include "fm.h" static struct eth_device *devlist[NUM_FM_PORTS]; static int num_controllers; #if defined(CONFIG_MII) || defined(CONFIG_CMD_MII) && !defined(BITBANGMII) #define TBIANA_SETTINGS (TBIANA_ASYMMETRIC_PAUSE | TBIANA_SYMMETRIC_PAUSE | \ TBIANA_FULL_DUPLEX) #define TBIANA_SGMII_ACK 0x4001 #define TBICR_SETTINGS (TBICR_ANEG_ENABLE | TBICR_RESTART_ANEG | \ TBICR_FULL_DUPLEX | TBICR_SPEED1_SET) /* Configure the TBI for SGMII operation */ static void dtsec_configure_serdes(struct fm_eth *priv) { #ifdef CONFIG_SYS_FMAN_V3 u32 value; struct mii_dev bus; bus.priv = priv->mac->phyregs; bool sgmii_2500 = (priv->enet_if == PHY_INTERFACE_MODE_SGMII_2500) ? true : false; /* SGMII IF mode + AN enable only for 1G SGMII, not for 2.5G */ value = PHY_SGMII_IF_MODE_SGMII; if (!sgmii_2500) value |= PHY_SGMII_IF_MODE_AN; memac_mdio_write(&bus, 0, MDIO_DEVAD_NONE, 0x14, value); /* Dev ability according to SGMII specification */ value = PHY_SGMII_DEV_ABILITY_SGMII; memac_mdio_write(&bus, 0, MDIO_DEVAD_NONE, 0x4, value); /* Adjust link timer for SGMII - 1.6 ms in units of 8 ns = 2 * 10^5 = 0x30d40 */ memac_mdio_write(&bus, 0, MDIO_DEVAD_NONE, 0x13, 0x3); memac_mdio_write(&bus, 0, MDIO_DEVAD_NONE, 0x12, 0xd40); /* Restart AN */ value = PHY_SGMII_CR_DEF_VAL; if (!sgmii_2500) value |= PHY_SGMII_CR_RESET_AN; memac_mdio_write(&bus, 0, MDIO_DEVAD_NONE, 0, value); #else struct dtsec *regs = priv->mac->base; struct tsec_mii_mng *phyregs = priv->mac->phyregs; /* * Access TBI PHY registers at given TSEC register offset as * opposed to the register offset used for external PHY accesses */ tsec_local_mdio_write(phyregs, in_be32(®s->tbipa), 0, TBI_TBICON, TBICON_CLK_SELECT); tsec_local_mdio_write(phyregs, in_be32(®s->tbipa), 0, TBI_ANA, TBIANA_SGMII_ACK); tsec_local_mdio_write(phyregs, in_be32(®s->tbipa), 0, TBI_CR, TBICR_SETTINGS); #endif } static void dtsec_init_phy(struct eth_device *dev) { struct fm_eth *fm_eth = dev->priv; #ifndef CONFIG_SYS_FMAN_V3 struct dtsec *regs = (struct dtsec *)CONFIG_SYS_FSL_FM1_DTSEC1_ADDR; /* Assign a Physical address to the TBI */ out_be32(®s->tbipa, CONFIG_SYS_TBIPA_VALUE); #endif if (fm_eth->enet_if == PHY_INTERFACE_MODE_SGMII || fm_eth->enet_if == PHY_INTERFACE_MODE_SGMII_2500) dtsec_configure_serdes(fm_eth); } static int tgec_is_fibre(struct eth_device *dev) { struct fm_eth *fm = dev->priv; char phyopt[20]; sprintf(phyopt, "fsl_fm%d_xaui_phy", fm->fm_index + 1); return hwconfig_arg_cmp(phyopt, "xfi"); } #endif static u16 muram_readw(u16 *addr) { u32 base = (u32)addr & ~0x3; u32 val32 = in_be32((u32 *)base); int byte_pos; u16 ret; byte_pos = (u32)addr & 0x3; if (byte_pos) ret = (u16)(val32 & 0x0000ffff); else ret = (u16)((val32 & 0xffff0000) >> 16); return ret; } static void muram_writew(u16 *addr, u16 val) { u32 base = (u32)addr & ~0x3; u32 org32 = in_be32((u32 *)base); u32 val32; int byte_pos; byte_pos = (u32)addr & 0x3; if (byte_pos) val32 = (org32 & 0xffff0000) | val; else val32 = (org32 & 0x0000ffff) | ((u32)val << 16); out_be32((u32 *)base, val32); } static void bmi_rx_port_disable(struct fm_bmi_rx_port *rx_port) { int timeout = 1000000; clrbits_be32(&rx_port->fmbm_rcfg, FMBM_RCFG_EN); /* wait until the rx port is not busy */ while ((in_be32(&rx_port->fmbm_rst) & FMBM_RST_BSY) && timeout--) ; } static void bmi_rx_port_init(struct fm_bmi_rx_port *rx_port) { /* set BMI to independent mode, Rx port disable */ out_be32(&rx_port->fmbm_rcfg, FMBM_RCFG_IM); /* clear FOF in IM case */ out_be32(&rx_port->fmbm_rim, 0); /* Rx frame next engine -RISC */ out_be32(&rx_port->fmbm_rfne, NIA_ENG_RISC | NIA_RISC_AC_IM_RX); /* Rx command attribute - no order, MR[3] = 1 */ clrbits_be32(&rx_port->fmbm_rfca, FMBM_RFCA_ORDER | FMBM_RFCA_MR_MASK); setbits_be32(&rx_port->fmbm_rfca, FMBM_RFCA_MR(4)); /* enable Rx statistic counters */ out_be32(&rx_port->fmbm_rstc, FMBM_RSTC_EN); /* disable Rx performance counters */ out_be32(&rx_port->fmbm_rpc, 0); } static void bmi_tx_port_disable(struct fm_bmi_tx_port *tx_port) { int timeout = 1000000; clrbits_be32(&tx_port->fmbm_tcfg, FMBM_TCFG_EN); /* wait until the tx port is not busy */ while ((in_be32(&tx_port->fmbm_tst) & FMBM_TST_BSY) && timeout--) ; } static void bmi_tx_port_init(struct fm_bmi_tx_port *tx_port) { /* set BMI to independent mode, Tx port disable */ out_be32(&tx_port->fmbm_tcfg, FMBM_TCFG_IM); /* Tx frame next engine -RISC */ out_be32(&tx_port->fmbm_tfne, NIA_ENG_RISC | NIA_RISC_AC_IM_TX); out_be32(&tx_port->fmbm_tfene, NIA_ENG_RISC | NIA_RISC_AC_IM_TX); /* Tx command attribute - no order, MR[3] = 1 */ clrbits_be32(&tx_port->fmbm_tfca, FMBM_TFCA_ORDER | FMBM_TFCA_MR_MASK); setbits_be32(&tx_port->fmbm_tfca, FMBM_TFCA_MR(4)); /* enable Tx statistic counters */ out_be32(&tx_port->fmbm_tstc, FMBM_TSTC_EN); /* disable Tx performance counters */ out_be32(&tx_port->fmbm_tpc, 0); } static int fm_eth_rx_port_parameter_init(struct fm_eth *fm_eth) { struct fm_port_global_pram *pram; u32 pram_page_offset; void *rx_bd_ring_base; void *rx_buf_pool; struct fm_port_bd *rxbd; struct fm_port_qd *rxqd; struct fm_bmi_rx_port *bmi_rx_port = fm_eth->rx_port; int i; /* alloc global parameter ram at MURAM */ pram = (struct fm_port_global_pram *)fm_muram_alloc(fm_eth->fm_index, FM_PRAM_SIZE, FM_PRAM_ALIGN); fm_eth->rx_pram = pram; /* parameter page offset to MURAM */ pram_page_offset = (u32)pram - fm_muram_base(fm_eth->fm_index); /* enable global mode- snooping data buffers and BDs */ out_be32(&pram->mode, PRAM_MODE_GLOBAL); /* init the Rx queue descriptor pionter */ out_be32(&pram->rxqd_ptr, pram_page_offset + 0x20); /* set the max receive buffer length, power of 2 */ muram_writew(&pram->mrblr, MAX_RXBUF_LOG2); /* alloc Rx buffer descriptors from main memory */ rx_bd_ring_base = malloc(sizeof(struct fm_port_bd) * RX_BD_RING_SIZE); if (!rx_bd_ring_base) return 0; memset(rx_bd_ring_base, 0, sizeof(struct fm_port_bd) * RX_BD_RING_SIZE); /* alloc Rx buffer from main memory */ rx_buf_pool = malloc(MAX_RXBUF_LEN * RX_BD_RING_SIZE); if (!rx_buf_pool) return 0; memset(rx_buf_pool, 0, MAX_RXBUF_LEN * RX_BD_RING_SIZE); /* save them to fm_eth */ fm_eth->rx_bd_ring = rx_bd_ring_base; fm_eth->cur_rxbd = rx_bd_ring_base; fm_eth->rx_buf = rx_buf_pool; /* init Rx BDs ring */ rxbd = (struct fm_port_bd *)rx_bd_ring_base; for (i = 0; i < RX_BD_RING_SIZE; i++) { muram_writew(&rxbd->status, RxBD_EMPTY); muram_writew(&rxbd->len, 0); muram_writew(&rxbd->buf_ptr_hi, 0); out_be32(&rxbd->buf_ptr_lo, (u32)rx_buf_pool + i * MAX_RXBUF_LEN); rxbd++; } /* set the Rx queue descriptor */ rxqd = &pram->rxqd; muram_writew(&rxqd->gen, 0); muram_writew(&rxqd->bd_ring_base_hi, 0); out_be32(&rxqd->bd_ring_base_lo, (u32)rx_bd_ring_base); muram_writew(&rxqd->bd_ring_size, sizeof(struct fm_port_bd) * RX_BD_RING_SIZE); muram_writew(&rxqd->offset_in, 0); muram_writew(&rxqd->offset_out, 0); /* set IM parameter ram pointer to Rx Frame Queue ID */ out_be32(&bmi_rx_port->fmbm_rfqid, pram_page_offset); return 1; } static int fm_eth_tx_port_parameter_init(struct fm_eth *fm_eth) { struct fm_port_global_pram *pram; u32 pram_page_offset; void *tx_bd_ring_base; struct fm_port_bd *txbd; struct fm_port_qd *txqd; struct fm_bmi_tx_port *bmi_tx_port = fm_eth->tx_port; int i; /* alloc global parameter ram at MURAM */ pram = (struct fm_port_global_pram *)fm_muram_alloc(fm_eth->fm_index, FM_PRAM_SIZE, FM_PRAM_ALIGN); fm_eth->tx_pram = pram; /* parameter page offset to MURAM */ pram_page_offset = (u32)pram - fm_muram_base(fm_eth->fm_index); /* enable global mode- snooping data buffers and BDs */ out_be32(&pram->mode, PRAM_MODE_GLOBAL); /* init the Tx queue descriptor pionter */ out_be32(&pram->txqd_ptr, pram_page_offset + 0x40); /* alloc Tx buffer descriptors from main memory */ tx_bd_ring_base = malloc(sizeof(struct fm_port_bd) * TX_BD_RING_SIZE); if (!tx_bd_ring_base) return 0; memset(tx_bd_ring_base, 0, sizeof(struct fm_port_bd) * TX_BD_RING_SIZE); /* save it to fm_eth */ fm_eth->tx_bd_ring = tx_bd_ring_base; fm_eth->cur_txbd = tx_bd_ring_base; /* init Tx BDs ring */ txbd = (struct fm_port_bd *)tx_bd_ring_base; for (i = 0; i < TX_BD_RING_SIZE; i++) { muram_writew(&txbd->status, TxBD_LAST); muram_writew(&txbd->len, 0); muram_writew(&txbd->buf_ptr_hi, 0); out_be32(&txbd->buf_ptr_lo, 0); txbd++; } /* set the Tx queue decriptor */ txqd = &pram->txqd; muram_writew(&txqd->bd_ring_base_hi, 0); out_be32(&txqd->bd_ring_base_lo, (u32)tx_bd_ring_base); muram_writew(&txqd->bd_ring_size, sizeof(struct fm_port_bd) * TX_BD_RING_SIZE); muram_writew(&txqd->offset_in, 0); muram_writew(&txqd->offset_out, 0); /* set IM parameter ram pointer to Tx Confirmation Frame Queue ID */ out_be32(&bmi_tx_port->fmbm_tcfqid, pram_page_offset); return 1; } static int fm_eth_init(struct fm_eth *fm_eth) { if (!fm_eth_rx_port_parameter_init(fm_eth)) return 0; if (!fm_eth_tx_port_parameter_init(fm_eth)) return 0; return 1; } static int fm_eth_startup(struct fm_eth *fm_eth) { struct fsl_enet_mac *mac; mac = fm_eth->mac; /* Rx/TxBDs, Rx/TxQDs, Rx buff and parameter ram init */ if (!fm_eth_init(fm_eth)) return 0; /* setup the MAC controller */ mac->init_mac(mac); /* For some reason we need to set SPEED_100 */ if (((fm_eth->enet_if == PHY_INTERFACE_MODE_SGMII) || (fm_eth->enet_if == PHY_INTERFACE_MODE_QSGMII)) && mac->set_if_mode) mac->set_if_mode(mac, fm_eth->enet_if, SPEED_100); /* init bmi rx port, IM mode and disable */ bmi_rx_port_init(fm_eth->rx_port); /* init bmi tx port, IM mode and disable */ bmi_tx_port_init(fm_eth->tx_port); return 1; } static void fmc_tx_port_graceful_stop_enable(struct fm_eth *fm_eth) { struct fm_port_global_pram *pram; pram = fm_eth->tx_pram; /* graceful stop transmission of frames */ setbits_be32(&pram->mode, PRAM_MODE_GRACEFUL_STOP); sync(); } static void fmc_tx_port_graceful_stop_disable(struct fm_eth *fm_eth) { struct fm_port_global_pram *pram; pram = fm_eth->tx_pram; /* re-enable transmission of frames */ clrbits_be32(&pram->mode, PRAM_MODE_GRACEFUL_STOP); sync(); } static int fm_eth_open(struct eth_device *dev, bd_t *bd) { struct fm_eth *fm_eth; struct fsl_enet_mac *mac; #ifdef CONFIG_PHYLIB int ret; #endif fm_eth = (struct fm_eth *)dev->priv; mac = fm_eth->mac; /* setup the MAC address */ if (dev->enetaddr[0] & 0x01) { printf("%s: MacAddress is multcast address\n", __func__); return 1; } mac->set_mac_addr(mac, dev->enetaddr); /* enable bmi Rx port */ setbits_be32(&fm_eth->rx_port->fmbm_rcfg, FMBM_RCFG_EN); /* enable MAC rx/tx port */ mac->enable_mac(mac); /* enable bmi Tx port */ setbits_be32(&fm_eth->tx_port->fmbm_tcfg, FMBM_TCFG_EN); /* re-enable transmission of frame */ fmc_tx_port_graceful_stop_disable(fm_eth); #ifdef CONFIG_PHYLIB if (fm_eth->phydev) { ret = phy_startup(fm_eth->phydev); if (ret) { printf("%s: Could not initialize\n", fm_eth->phydev->dev->name); return ret; } } else { return 0; } #else fm_eth->phydev->speed = SPEED_1000; fm_eth->phydev->link = 1; fm_eth->phydev->duplex = DUPLEX_FULL; #endif /* set the MAC-PHY mode */ mac->set_if_mode(mac, fm_eth->enet_if, fm_eth->phydev->speed); if (!fm_eth->phydev->link) printf("%s: No link.\n", fm_eth->phydev->dev->name); return fm_eth->phydev->link ? 0 : -1; } static void fm_eth_halt(struct eth_device *dev) { struct fm_eth *fm_eth; struct fsl_enet_mac *mac; fm_eth = (struct fm_eth *)dev->priv; mac = fm_eth->mac; /* graceful stop the transmission of frames */ fmc_tx_port_graceful_stop_enable(fm_eth); /* disable bmi Tx port */ bmi_tx_port_disable(fm_eth->tx_port); /* disable MAC rx/tx port */ mac->disable_mac(mac); /* disable bmi Rx port */ bmi_rx_port_disable(fm_eth->rx_port); if (fm_eth->phydev) phy_shutdown(fm_eth->phydev); } static int fm_eth_send(struct eth_device *dev, void *buf, int len) { struct fm_eth *fm_eth; struct fm_port_global_pram *pram; struct fm_port_bd *txbd, *txbd_base; u16 offset_in; int i; fm_eth = (struct fm_eth *)dev->priv; pram = fm_eth->tx_pram; txbd = fm_eth->cur_txbd; /* find one empty TxBD */ for (i = 0; muram_readw(&txbd->status) & TxBD_READY; i++) { udelay(100); if (i > 0x1000) { printf("%s: Tx buffer not ready, txbd->status = 0x%x\n", dev->name, muram_readw(&txbd->status)); return 0; } } /* setup TxBD */ muram_writew(&txbd->buf_ptr_hi, 0); out_be32(&txbd->buf_ptr_lo, (u32)buf); muram_writew(&txbd->len, len); sync(); muram_writew(&txbd->status, TxBD_READY | TxBD_LAST); sync(); /* update TxQD, let RISC to send the packet */ offset_in = muram_readw(&pram->txqd.offset_in); offset_in += sizeof(struct fm_port_bd); if (offset_in >= muram_readw(&pram->txqd.bd_ring_size)) offset_in = 0; muram_writew(&pram->txqd.offset_in, offset_in); sync(); /* wait for buffer to be transmitted */ for (i = 0; muram_readw(&txbd->status) & TxBD_READY; i++) { udelay(100); if (i > 0x10000) { printf("%s: Tx error, txbd->status = 0x%x\n", dev->name, muram_readw(&txbd->status)); return 0; } } /* advance the TxBD */ txbd++; txbd_base = (struct fm_port_bd *)fm_eth->tx_bd_ring; if (txbd >= (txbd_base + TX_BD_RING_SIZE)) txbd = txbd_base; /* update current txbd */ fm_eth->cur_txbd = (void *)txbd; return 1; } static int fm_eth_recv(struct eth_device *dev) { struct fm_eth *fm_eth; struct fm_port_global_pram *pram; struct fm_port_bd *rxbd, *rxbd_base; u16 status, len; u8 *data; u16 offset_out; int ret = 1; fm_eth = (struct fm_eth *)dev->priv; pram = fm_eth->rx_pram; rxbd = fm_eth->cur_rxbd; status = muram_readw(&rxbd->status); while (!(status & RxBD_EMPTY)) { if (!(status & RxBD_ERROR)) { data = (u8 *)in_be32(&rxbd->buf_ptr_lo); len = muram_readw(&rxbd->len); net_process_received_packet(data, len); } else { printf("%s: Rx error\n", dev->name); ret = 0; } /* clear the RxBDs */ muram_writew(&rxbd->status, RxBD_EMPTY); muram_writew(&rxbd->len, 0); sync(); /* advance RxBD */ rxbd++; rxbd_base = (struct fm_port_bd *)fm_eth->rx_bd_ring; if (rxbd >= (rxbd_base + RX_BD_RING_SIZE)) rxbd = rxbd_base; /* read next status */ status = muram_readw(&rxbd->status); /* update RxQD */ offset_out = muram_readw(&pram->rxqd.offset_out); offset_out += sizeof(struct fm_port_bd); if (offset_out >= muram_readw(&pram->rxqd.bd_ring_size)) offset_out = 0; muram_writew(&pram->rxqd.offset_out, offset_out); sync(); } fm_eth->cur_rxbd = (void *)rxbd; return ret; } static int fm_eth_init_mac(struct fm_eth *fm_eth, struct ccsr_fman *reg) { struct fsl_enet_mac *mac; int num; void *base, *phyregs = NULL; num = fm_eth->num; #ifdef CONFIG_SYS_FMAN_V3 #ifndef CONFIG_FSL_FM_10GEC_REGULAR_NOTATION if (fm_eth->type == FM_ETH_10G_E) { /* 10GEC1/10GEC2 use mEMAC9/mEMAC10 on T2080/T4240. * 10GEC3/10GEC4 use mEMAC1/mEMAC2 on T2080. * 10GEC1 uses mEMAC1 on T1024. * so it needs to change the num. */ if (fm_eth->num >= 2) num -= 2; else num += 8; } #endif base = ®->memac[num].fm_memac; phyregs = ®->memac[num].fm_memac_mdio; #else /* Get the mac registers base address */ if (fm_eth->type == FM_ETH_1G_E) { base = ®->mac_1g[num].fm_dtesc; phyregs = ®->mac_1g[num].fm_mdio.miimcfg; } else { base = ®->mac_10g[num].fm_10gec; phyregs = ®->mac_10g[num].fm_10gec_mdio; } #endif /* alloc mac controller */ mac = malloc(sizeof(struct fsl_enet_mac)); if (!mac) return 0; memset(mac, 0, sizeof(struct fsl_enet_mac)); /* save the mac to fm_eth struct */ fm_eth->mac = mac; #ifdef CONFIG_SYS_FMAN_V3 init_memac(mac, base, phyregs, MAX_RXBUF_LEN); #else if (fm_eth->type == FM_ETH_1G_E) init_dtsec(mac, base, phyregs, MAX_RXBUF_LEN); else init_tgec(mac, base, phyregs, MAX_RXBUF_LEN); #endif return 1; } static int init_phy(struct eth_device *dev) { struct fm_eth *fm_eth = dev->priv; struct phy_device *phydev = NULL; u32 supported; #ifdef CONFIG_PHYLIB if (fm_eth->type == FM_ETH_1G_E) dtsec_init_phy(dev); if (fm_eth->bus) { phydev = phy_connect(fm_eth->bus, fm_eth->phyaddr, dev, fm_eth->enet_if); if (!phydev) { printf("Failed to connect\n"); return -1; } } else { return 0; } if (fm_eth->type == FM_ETH_1G_E) { supported = (SUPPORTED_10baseT_Half | SUPPORTED_10baseT_Full | SUPPORTED_100baseT_Half | SUPPORTED_100baseT_Full | SUPPORTED_1000baseT_Full); } else { supported = SUPPORTED_10000baseT_Full; if (tgec_is_fibre(dev)) phydev->port = PORT_FIBRE; } phydev->supported &= supported; phydev->advertising = phydev->supported; fm_eth->phydev = phydev; phy_config(phydev); #endif return 0; } int fm_eth_initialize(struct ccsr_fman *reg, struct fm_eth_info *info) { struct eth_device *dev; struct fm_eth *fm_eth; int i, num = info->num; /* alloc eth device */ dev = (struct eth_device *)malloc(sizeof(struct eth_device)); if (!dev) return 0; memset(dev, 0, sizeof(struct eth_device)); /* alloc the FMan ethernet private struct */ fm_eth = (struct fm_eth *)malloc(sizeof(struct fm_eth)); if (!fm_eth) return 0; memset(fm_eth, 0, sizeof(struct fm_eth)); /* save off some things we need from the info struct */ fm_eth->fm_index = info->index - 1; /* keep as 0 based for muram */ fm_eth->num = num; fm_eth->type = info->type; fm_eth->rx_port = (void *)®->port[info->rx_port_id - 1].fm_bmi; fm_eth->tx_port = (void *)®->port[info->tx_port_id - 1].fm_bmi; /* set the ethernet max receive length */ fm_eth->max_rx_len = MAX_RXBUF_LEN; /* init global mac structure */ if (!fm_eth_init_mac(fm_eth, reg)) return 0; /* keep same as the manual, we call FMAN1, FMAN2, DTSEC1, DTSEC2, etc */ if (fm_eth->type == FM_ETH_1G_E) sprintf(dev->name, "FM%d@DTSEC%d", info->index, num + 1); else sprintf(dev->name, "FM%d@TGEC%d", info->index, num + 1); devlist[num_controllers++] = dev; dev->iobase = 0; dev->priv = (void *)fm_eth; dev->init = fm_eth_open; dev->halt = fm_eth_halt; dev->send = fm_eth_send; dev->recv = fm_eth_recv; fm_eth->dev = dev; fm_eth->bus = info->bus; fm_eth->phyaddr = info->phy_addr; fm_eth->enet_if = info->enet_if; /* startup the FM im */ if (!fm_eth_startup(fm_eth)) return 0; init_phy(dev); /* clear the ethernet address */ for (i = 0; i < 6; i++) dev->enetaddr[i] = 0; eth_register(dev); return 1; }