/* * ibm_emac_core.c * * Ethernet driver for the built in ethernet on the IBM 4xx PowerPC * processors. * * (c) 2003 Benjamin Herrenschmidt * * Based on original work by * * Armin Kuster * Johnnie Peters * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. * TODO * - Check for races in the "remove" code path * - Add some Power Management to the MAC and the PHY * - Audit remaining of non-rewritten code (--BenH) * - Cleanup message display using msglevel mecanism * - Address all errata * - Audit all register update paths to ensure they * are being written post soft reset if required. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ibm_emac_core.h" //#define MDIO_DEBUG(fmt) printk fmt #define MDIO_DEBUG(fmt) //#define LINK_DEBUG(fmt) printk fmt #define LINK_DEBUG(fmt) //#define PKT_DEBUG(fmt) printk fmt #define PKT_DEBUG(fmt) #define DRV_NAME "emac" #define DRV_VERSION "2.0" #define DRV_AUTHOR "Benjamin Herrenschmidt " #define DRV_DESC "IBM EMAC Ethernet driver" /* * When mdio_idx >= 0, contains a list of emac ocp_devs * that have had their initialization deferred until the * common MDIO controller has been initialized. */ LIST_HEAD(emac_init_list); MODULE_AUTHOR(DRV_AUTHOR); MODULE_DESCRIPTION(DRV_DESC); MODULE_LICENSE("GPL"); static int skb_res = SKB_RES; module_param(skb_res, int, 0444); MODULE_PARM_DESC(skb_res, "Amount of data to reserve on skb buffs\n" "The 405 handles a misaligned IP header fine but\n" "this can help if you are routing to a tunnel or a\n" "device that needs aligned data. 0..2"); #define RGMII_PRIV(ocpdev) ((struct ibm_ocp_rgmii*)ocp_get_drvdata(ocpdev)) static unsigned int rgmii_enable[] = { RGMII_RTBI, RGMII_RGMII, RGMII_TBI, RGMII_GMII }; static unsigned int rgmii_speed_mask[] = { RGMII_MII2_SPDMASK, RGMII_MII3_SPDMASK }; static unsigned int rgmii_speed100[] = { RGMII_MII2_100MB, RGMII_MII3_100MB }; static unsigned int rgmii_speed1000[] = { RGMII_MII2_1000MB, RGMII_MII3_1000MB }; #define ZMII_PRIV(ocpdev) ((struct ibm_ocp_zmii*)ocp_get_drvdata(ocpdev)) static unsigned int zmii_enable[][4] = { {ZMII_SMII0, ZMII_RMII0, ZMII_MII0, ~(ZMII_MDI1 | ZMII_MDI2 | ZMII_MDI3)}, {ZMII_SMII1, ZMII_RMII1, ZMII_MII1, ~(ZMII_MDI0 | ZMII_MDI2 | ZMII_MDI3)}, {ZMII_SMII2, ZMII_RMII2, ZMII_MII2, ~(ZMII_MDI0 | ZMII_MDI1 | ZMII_MDI3)}, {ZMII_SMII3, ZMII_RMII3, ZMII_MII3, ~(ZMII_MDI0 | ZMII_MDI1 | ZMII_MDI2)} }; static unsigned int mdi_enable[] = { ZMII_MDI0, ZMII_MDI1, ZMII_MDI2, ZMII_MDI3 }; static unsigned int zmii_speed = 0x0; static unsigned int zmii_speed100[] = { ZMII_MII0_100MB, ZMII_MII1_100MB, ZMII_MII2_100MB, ZMII_MII3_100MB }; /* Since multiple EMACs share MDIO lines in various ways, we need * to avoid re-using the same PHY ID in cases where the arch didn't * setup precise phy_map entries */ static u32 busy_phy_map = 0; /* If EMACs share a common MDIO device, this points to it */ static struct net_device *mdio_ndev = NULL; struct emac_def_dev { struct list_head link; struct ocp_device *ocpdev; struct ibm_ocp_mal *mal; }; static struct net_device_stats *emac_stats(struct net_device *dev) { struct ocp_enet_private *fep = dev->priv; return &fep->stats; }; static int emac_init_rgmii(struct ocp_device *rgmii_dev, int input, int phy_mode) { struct ibm_ocp_rgmii *rgmii = RGMII_PRIV(rgmii_dev); const char *mode_name[] = { "RTBI", "RGMII", "TBI", "GMII" }; int mode = -1; if (!rgmii) { rgmii = kmalloc(sizeof(struct ibm_ocp_rgmii), GFP_KERNEL); if (rgmii == NULL) { printk(KERN_ERR "rgmii%d: Out of memory allocating RGMII structure!\n", rgmii_dev->def->index); return -ENOMEM; } memset(rgmii, 0, sizeof(*rgmii)); rgmii->base = (struct rgmii_regs *)ioremap(rgmii_dev->def->paddr, sizeof(*rgmii->base)); if (rgmii->base == NULL) { printk(KERN_ERR "rgmii%d: Cannot ioremap bridge registers!\n", rgmii_dev->def->index); kfree(rgmii); return -ENOMEM; } ocp_set_drvdata(rgmii_dev, rgmii); } if (phy_mode) { switch (phy_mode) { case PHY_MODE_GMII: mode = GMII; break; case PHY_MODE_TBI: mode = TBI; break; case PHY_MODE_RTBI: mode = RTBI; break; case PHY_MODE_RGMII: default: mode = RGMII; } rgmii->base->fer &= ~RGMII_FER_MASK(input); rgmii->base->fer |= rgmii_enable[mode] << (4 * input); } else { switch ((rgmii->base->fer & RGMII_FER_MASK(input)) >> (4 * input)) { case RGMII_RTBI: mode = RTBI; break; case RGMII_RGMII: mode = RGMII; break; case RGMII_TBI: mode = TBI; break; case RGMII_GMII: mode = GMII; } } /* Set mode to RGMII if nothing valid is detected */ if (mode < 0) mode = RGMII; printk(KERN_NOTICE "rgmii%d: input %d in %s mode\n", rgmii_dev->def->index, input, mode_name[mode]); rgmii->mode[input] = mode; rgmii->users++; return 0; } static void emac_rgmii_port_speed(struct ocp_device *ocpdev, int input, int speed) { struct ibm_ocp_rgmii *rgmii = RGMII_PRIV(ocpdev); unsigned int rgmii_speed; rgmii_speed = in_be32(&rgmii->base->ssr); rgmii_speed &= ~rgmii_speed_mask[input]; if (speed == 1000) rgmii_speed |= rgmii_speed1000[input]; else if (speed == 100) rgmii_speed |= rgmii_speed100[input]; out_be32(&rgmii->base->ssr, rgmii_speed); } static void emac_close_rgmii(struct ocp_device *ocpdev) { struct ibm_ocp_rgmii *rgmii = RGMII_PRIV(ocpdev); BUG_ON(!rgmii || rgmii->users == 0); if (!--rgmii->users) { ocp_set_drvdata(ocpdev, NULL); iounmap((void *)rgmii->base); kfree(rgmii); } } static int emac_init_zmii(struct ocp_device *zmii_dev, int input, int phy_mode) { struct ibm_ocp_zmii *zmii = ZMII_PRIV(zmii_dev); const char *mode_name[] = { "SMII", "RMII", "MII" }; int mode = -1; if (!zmii) { zmii = kmalloc(sizeof(struct ibm_ocp_zmii), GFP_KERNEL); if (zmii == NULL) { printk(KERN_ERR "zmii%d: Out of memory allocating ZMII structure!\n", zmii_dev->def->index); return -ENOMEM; } memset(zmii, 0, sizeof(*zmii)); zmii->base = (struct zmii_regs *)ioremap(zmii_dev->def->paddr, sizeof(*zmii->base)); if (zmii->base == NULL) { printk(KERN_ERR "zmii%d: Cannot ioremap bridge registers!\n", zmii_dev->def->index); kfree(zmii); return -ENOMEM; } ocp_set_drvdata(zmii_dev, zmii); } if (phy_mode) { switch (phy_mode) { case PHY_MODE_MII: mode = MII; break; case PHY_MODE_RMII: mode = RMII; break; case PHY_MODE_SMII: default: mode = SMII; } zmii->base->fer &= ~ZMII_FER_MASK(input); zmii->base->fer |= zmii_enable[input][mode]; } else { switch ((zmii->base->fer & ZMII_FER_MASK(input)) << (4 * input)) { case ZMII_MII0: mode = MII; break; case ZMII_RMII0: mode = RMII; break; case ZMII_SMII0: mode = SMII; } } /* Set mode to SMII if nothing valid is detected */ if (mode < 0) mode = SMII; printk(KERN_NOTICE "zmii%d: input %d in %s mode\n", zmii_dev->def->index, input, mode_name[mode]); zmii->mode[input] = mode; zmii->users++; return 0; } static void emac_enable_zmii_port(struct ocp_device *ocpdev, int input) { u32 mask; struct ibm_ocp_zmii *zmii = ZMII_PRIV(ocpdev); mask = in_be32(&zmii->base->fer); mask &= zmii_enable[input][MDI]; /* turn all non enabled MDI's off */ mask |= zmii_enable[input][zmii->mode[input]] | mdi_enable[input]; out_be32(&zmii->base->fer, mask); } static void emac_zmii_port_speed(struct ocp_device *ocpdev, int input, int speed) { struct ibm_ocp_zmii *zmii = ZMII_PRIV(ocpdev); if (speed == 100) zmii_speed |= zmii_speed100[input]; else zmii_speed &= ~zmii_speed100[input]; out_be32(&zmii->base->ssr, zmii_speed); } static void emac_close_zmii(struct ocp_device *ocpdev) { struct ibm_ocp_zmii *zmii = ZMII_PRIV(ocpdev); BUG_ON(!zmii || zmii->users == 0); if (!--zmii->users) { ocp_set_drvdata(ocpdev, NULL); iounmap((void *)zmii->base); kfree(zmii); } } int emac_phy_read(struct net_device *dev, int mii_id, int reg) { int count; uint32_t stacr; struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; MDIO_DEBUG(("%s: phy_read, id: 0x%x, reg: 0x%x\n", dev->name, mii_id, reg)); /* Enable proper ZMII port */ if (fep->zmii_dev) emac_enable_zmii_port(fep->zmii_dev, fep->zmii_input); /* Use the EMAC that has the MDIO port */ if (fep->mdio_dev) { dev = fep->mdio_dev; fep = dev->priv; emacp = fep->emacp; } count = 0; while ((((stacr = in_be32(&emacp->em0stacr)) & EMAC_STACR_OC) == 0) && (count++ < MDIO_DELAY)) udelay(1); MDIO_DEBUG((" (count was %d)\n", count)); if ((stacr & EMAC_STACR_OC) == 0) { printk(KERN_WARNING "%s: PHY read timeout #1!\n", dev->name); return -1; } /* Clear the speed bits and make a read request to the PHY */ stacr = ((EMAC_STACR_READ | (reg & 0x1f)) & ~EMAC_STACR_CLK_100MHZ); stacr |= ((mii_id & 0x1F) << 5); out_be32(&emacp->em0stacr, stacr); count = 0; while ((((stacr = in_be32(&emacp->em0stacr)) & EMAC_STACR_OC) == 0) && (count++ < MDIO_DELAY)) udelay(1); MDIO_DEBUG((" (count was %d)\n", count)); if ((stacr & EMAC_STACR_OC) == 0) { printk(KERN_WARNING "%s: PHY read timeout #2!\n", dev->name); return -1; } /* Check for a read error */ if (stacr & EMAC_STACR_PHYE) { MDIO_DEBUG(("EMAC MDIO PHY error !\n")); return -1; } MDIO_DEBUG((" -> 0x%x\n", stacr >> 16)); return (stacr >> 16); } void emac_phy_write(struct net_device *dev, int mii_id, int reg, int data) { int count; uint32_t stacr; struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; MDIO_DEBUG(("%s phy_write, id: 0x%x, reg: 0x%x, data: 0x%x\n", dev->name, mii_id, reg, data)); /* Enable proper ZMII port */ if (fep->zmii_dev) emac_enable_zmii_port(fep->zmii_dev, fep->zmii_input); /* Use the EMAC that has the MDIO port */ if (fep->mdio_dev) { dev = fep->mdio_dev; fep = dev->priv; emacp = fep->emacp; } count = 0; while ((((stacr = in_be32(&emacp->em0stacr)) & EMAC_STACR_OC) == 0) && (count++ < MDIO_DELAY)) udelay(1); MDIO_DEBUG((" (count was %d)\n", count)); if ((stacr & EMAC_STACR_OC) == 0) { printk(KERN_WARNING "%s: PHY write timeout #2!\n", dev->name); return; } /* Clear the speed bits and make a read request to the PHY */ stacr = ((EMAC_STACR_WRITE | (reg & 0x1f)) & ~EMAC_STACR_CLK_100MHZ); stacr |= ((mii_id & 0x1f) << 5) | ((data & 0xffff) << 16); out_be32(&emacp->em0stacr, stacr); count = 0; while ((((stacr = in_be32(&emacp->em0stacr)) & EMAC_STACR_OC) == 0) && (count++ < MDIO_DELAY)) udelay(1); MDIO_DEBUG((" (count was %d)\n", count)); if ((stacr & EMAC_STACR_OC) == 0) printk(KERN_WARNING "%s: PHY write timeout #2!\n", dev->name); /* Check for a write error */ if ((stacr & EMAC_STACR_PHYE) != 0) { MDIO_DEBUG(("EMAC MDIO PHY error !\n")); } } static void emac_txeob_dev(void *param, u32 chanmask) { struct net_device *dev = param; struct ocp_enet_private *fep = dev->priv; unsigned long flags; spin_lock_irqsave(&fep->lock, flags); PKT_DEBUG(("emac_txeob_dev() entry, tx_cnt: %d\n", fep->tx_cnt)); while (fep->tx_cnt && !(fep->tx_desc[fep->ack_slot].ctrl & MAL_TX_CTRL_READY)) { if (fep->tx_desc[fep->ack_slot].ctrl & MAL_TX_CTRL_LAST) { /* Tell the system the transmit completed. */ dma_unmap_single(&fep->ocpdev->dev, fep->tx_desc[fep->ack_slot].data_ptr, fep->tx_desc[fep->ack_slot].data_len, DMA_TO_DEVICE); dev_kfree_skb_irq(fep->tx_skb[fep->ack_slot]); if (fep->tx_desc[fep->ack_slot].ctrl & (EMAC_TX_ST_EC | EMAC_TX_ST_MC | EMAC_TX_ST_SC)) fep->stats.collisions++; } fep->tx_skb[fep->ack_slot] = (struct sk_buff *)NULL; if (++fep->ack_slot == NUM_TX_BUFF) fep->ack_slot = 0; fep->tx_cnt--; } if (fep->tx_cnt < NUM_TX_BUFF) netif_wake_queue(dev); PKT_DEBUG(("emac_txeob_dev() exit, tx_cnt: %d\n", fep->tx_cnt)); spin_unlock_irqrestore(&fep->lock, flags); } /* Fill/Re-fill the rx chain with valid ctrl/ptrs. This function will fill from rx_slot up to the parm end. So to completely fill the chain pre-set rx_slot to 0 and pass in an end of 0. */ static void emac_rx_fill(struct net_device *dev, int end) { int i; struct ocp_enet_private *fep = dev->priv; i = fep->rx_slot; do { /* We don't want the 16 bytes skb_reserve done by dev_alloc_skb, * it breaks our cache line alignement. However, we still allocate * +16 so that we end up allocating the exact same size as * dev_alloc_skb() would do. * Also, because of the skb_res, the max DMA size we give to EMAC * is slighly wrong, causing it to potentially DMA 2 more bytes * from a broken/oversized packet. These 16 bytes will take care * that we don't walk on somebody else toes with that. */ fep->rx_skb[i] = alloc_skb(fep->rx_buffer_size + 16, GFP_ATOMIC); if (fep->rx_skb[i] == NULL) { /* Keep rx_slot here, the next time clean/fill is called * we will try again before the MAL wraps back here * If the MAL tries to use this descriptor with * the EMPTY bit off it will cause the * rxde interrupt. That is where we will * try again to allocate an sk_buff. */ break; } if (skb_res) skb_reserve(fep->rx_skb[i], skb_res); /* We must NOT dma_map_single the cache line right after the * buffer, so we must crop our sync size to account for the * reserved space */ fep->rx_desc[i].data_ptr = (unsigned char *)dma_map_single(&fep->ocpdev->dev, (void *)fep->rx_skb[i]-> data, fep->rx_buffer_size - skb_res, DMA_FROM_DEVICE); /* * Some 4xx implementations use the previously * reserved bits in data_len to encode the MS * 4-bits of a 36-bit physical address (ERPN) * This must be initialized. */ fep->rx_desc[i].data_len = 0; fep->rx_desc[i].ctrl = MAL_RX_CTRL_EMPTY | MAL_RX_CTRL_INTR | (i == (NUM_RX_BUFF - 1) ? MAL_RX_CTRL_WRAP : 0); } while ((i = (i + 1) % NUM_RX_BUFF) != end); fep->rx_slot = i; } static void emac_rx_csum(struct net_device *dev, unsigned short ctrl, struct sk_buff *skb) { struct ocp_enet_private *fep = dev->priv; /* Exit if interface has no TAH engine */ if (!fep->tah_dev) { skb->ip_summed = CHECKSUM_NONE; return; } /* Check for TCP/UDP/IP csum error */ if (ctrl & EMAC_CSUM_VER_ERROR) { /* Let the stack verify checksum errors */ skb->ip_summed = CHECKSUM_NONE; /* adapter->hw_csum_err++; */ } else { /* Csum is good */ skb->ip_summed = CHECKSUM_UNNECESSARY; /* adapter->hw_csum_good++; */ } } static int emac_rx_clean(struct net_device *dev) { int i, b, bnum = 0, buf[6]; int error, frame_length; struct ocp_enet_private *fep = dev->priv; unsigned short ctrl; i = fep->rx_slot; PKT_DEBUG(("emac_rx_clean() entry, rx_slot: %d\n", fep->rx_slot)); do { if (fep->rx_skb[i] == NULL) continue; /*we have already handled the packet but haved failed to alloc */ /* since rx_desc is in uncached mem we don't keep reading it directly we pull out a local copy of ctrl and do the checks on the copy. */ ctrl = fep->rx_desc[i].ctrl; if (ctrl & MAL_RX_CTRL_EMPTY) break; /*we don't have any more ready packets */ if (EMAC_IS_BAD_RX_PACKET(ctrl)) { fep->stats.rx_errors++; fep->stats.rx_dropped++; if (ctrl & EMAC_RX_ST_OE) fep->stats.rx_fifo_errors++; if (ctrl & EMAC_RX_ST_AE) fep->stats.rx_frame_errors++; if (ctrl & EMAC_RX_ST_BFCS) fep->stats.rx_crc_errors++; if (ctrl & (EMAC_RX_ST_RP | EMAC_RX_ST_PTL | EMAC_RX_ST_ORE | EMAC_RX_ST_IRE)) fep->stats.rx_length_errors++; } else { if ((ctrl & (MAL_RX_CTRL_FIRST | MAL_RX_CTRL_LAST)) == (MAL_RX_CTRL_FIRST | MAL_RX_CTRL_LAST)) { /* Single descriptor packet */ emac_rx_csum(dev, ctrl, fep->rx_skb[i]); /* Send the skb up the chain. */ frame_length = fep->rx_desc[i].data_len - 4; skb_put(fep->rx_skb[i], frame_length); fep->rx_skb[i]->dev = dev; fep->rx_skb[i]->protocol = eth_type_trans(fep->rx_skb[i], dev); error = netif_rx(fep->rx_skb[i]); if ((error == NET_RX_DROP) || (error == NET_RX_BAD)) { fep->stats.rx_dropped++; } else { fep->stats.rx_packets++; fep->stats.rx_bytes += frame_length; } fep->rx_skb[i] = NULL; } else { /* Multiple descriptor packet */ if (ctrl & MAL_RX_CTRL_FIRST) { if (fep->rx_desc[(i + 1) % NUM_RX_BUFF]. ctrl & MAL_RX_CTRL_EMPTY) break; bnum = 0; buf[bnum] = i; ++bnum; continue; } if (((ctrl & MAL_RX_CTRL_FIRST) != MAL_RX_CTRL_FIRST) && ((ctrl & MAL_RX_CTRL_LAST) != MAL_RX_CTRL_LAST)) { if (fep->rx_desc[(i + 1) % NUM_RX_BUFF].ctrl & MAL_RX_CTRL_EMPTY) { i = buf[0]; break; } buf[bnum] = i; ++bnum; continue; } if (ctrl & MAL_RX_CTRL_LAST) { buf[bnum] = i; ++bnum; skb_put(fep->rx_skb[buf[0]], fep->rx_desc[buf[0]].data_len); for (b = 1; b < bnum; b++) { /* * MAL is braindead, we need * to copy the remainder * of the packet from the * latter descriptor buffers * to the first skb. Then * dispose of the source * skbs. * * Once the stack is fixed * to handle frags on most * protocols we can generate * a fragmented skb with * no copies. */ memcpy(fep->rx_skb[buf[0]]-> data + fep->rx_skb[buf[0]]->len, fep->rx_skb[buf[b]]-> data, fep->rx_desc[buf[b]]. data_len); skb_put(fep->rx_skb[buf[0]], fep->rx_desc[buf[b]]. data_len); dma_unmap_single(&fep->ocpdev-> dev, fep-> rx_desc[buf [b]]. data_ptr, fep-> rx_desc[buf [b]]. data_len, DMA_FROM_DEVICE); dev_kfree_skb(fep-> rx_skb[buf[b]]); } emac_rx_csum(dev, ctrl, fep->rx_skb[buf[0]]); fep->rx_skb[buf[0]]->dev = dev; fep->rx_skb[buf[0]]->protocol = eth_type_trans(fep->rx_skb[buf[0]], dev); error = netif_rx(fep->rx_skb[buf[0]]); if ((error == NET_RX_DROP) || (error == NET_RX_BAD)) { fep->stats.rx_dropped++; } else { fep->stats.rx_packets++; fep->stats.rx_bytes += fep->rx_skb[buf[0]]->len; } for (b = 0; b < bnum; b++) fep->rx_skb[buf[b]] = NULL; } } } } while ((i = (i + 1) % NUM_RX_BUFF) != fep->rx_slot); PKT_DEBUG(("emac_rx_clean() exit, rx_slot: %d\n", fep->rx_slot)); return i; } static void emac_rxeob_dev(void *param, u32 chanmask) { struct net_device *dev = param; struct ocp_enet_private *fep = dev->priv; unsigned long flags; int n; spin_lock_irqsave(&fep->lock, flags); if ((n = emac_rx_clean(dev)) != fep->rx_slot) emac_rx_fill(dev, n); spin_unlock_irqrestore(&fep->lock, flags); } /* * This interrupt should never occurr, we don't program * the MAL for contiunous mode. */ static void emac_txde_dev(void *param, u32 chanmask) { struct net_device *dev = param; struct ocp_enet_private *fep = dev->priv; printk(KERN_WARNING "%s: transmit descriptor error\n", dev->name); emac_mac_dump(dev); emac_mal_dump(dev); /* Reenable the transmit channel */ mal_enable_tx_channels(fep->mal, fep->commac.tx_chan_mask); } /* * This interrupt should be very rare at best. This occurs when * the hardware has a problem with the receive descriptors. The manual * states that it occurs when the hardware cannot the receive descriptor * empty bit is not set. The recovery mechanism will be to * traverse through the descriptors, handle any that are marked to be * handled and reinitialize each along the way. At that point the driver * will be restarted. */ static void emac_rxde_dev(void *param, u32 chanmask) { struct net_device *dev = param; struct ocp_enet_private *fep = dev->priv; unsigned long flags; if (net_ratelimit()) { printk(KERN_WARNING "%s: receive descriptor error\n", fep->ndev->name); emac_mac_dump(dev); emac_mal_dump(dev); emac_desc_dump(dev); } /* Disable RX channel */ spin_lock_irqsave(&fep->lock, flags); mal_disable_rx_channels(fep->mal, fep->commac.rx_chan_mask); /* For now, charge the error against all emacs */ fep->stats.rx_errors++; /* so do we have any good packets still? */ emac_rx_clean(dev); /* When the interface is restarted it resets processing to the * first descriptor in the table. */ fep->rx_slot = 0; emac_rx_fill(dev, 0); set_mal_dcrn(fep->mal, DCRN_MALRXEOBISR, fep->commac.rx_chan_mask); set_mal_dcrn(fep->mal, DCRN_MALRXDEIR, fep->commac.rx_chan_mask); /* Reenable the receive channels */ mal_enable_rx_channels(fep->mal, fep->commac.rx_chan_mask); spin_unlock_irqrestore(&fep->lock, flags); } static irqreturn_t emac_mac_irq(int irq, void *dev_instance, struct pt_regs *regs) { struct net_device *dev = dev_instance; struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; unsigned long tmp_em0isr; /* EMAC interrupt */ tmp_em0isr = in_be32(&emacp->em0isr); if (tmp_em0isr & (EMAC_ISR_TE0 | EMAC_ISR_TE1)) { /* This error is a hard transmit error - could retransmit */ fep->stats.tx_errors++; /* Reenable the transmit channel */ mal_enable_tx_channels(fep->mal, fep->commac.tx_chan_mask); } else { fep->stats.rx_errors++; } if (tmp_em0isr & EMAC_ISR_RP) fep->stats.rx_length_errors++; if (tmp_em0isr & EMAC_ISR_ALE) fep->stats.rx_frame_errors++; if (tmp_em0isr & EMAC_ISR_BFCS) fep->stats.rx_crc_errors++; if (tmp_em0isr & EMAC_ISR_PTLE) fep->stats.rx_length_errors++; if (tmp_em0isr & EMAC_ISR_ORE) fep->stats.rx_length_errors++; if (tmp_em0isr & EMAC_ISR_TE0) fep->stats.tx_aborted_errors++; emac_err_dump(dev, tmp_em0isr); out_be32(&emacp->em0isr, tmp_em0isr); return IRQ_HANDLED; } static int emac_start_xmit(struct sk_buff *skb, struct net_device *dev) { unsigned short ctrl; unsigned long flags; struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; int len = skb->len; unsigned int offset = 0, size, f, tx_slot_first; unsigned int nr_frags = skb_shinfo(skb)->nr_frags; spin_lock_irqsave(&fep->lock, flags); len -= skb->data_len; if ((fep->tx_cnt + nr_frags + len / DESC_BUF_SIZE + 1) > NUM_TX_BUFF) { PKT_DEBUG(("emac_start_xmit() stopping queue\n")); netif_stop_queue(dev); spin_unlock_irqrestore(&fep->lock, flags); return -EBUSY; } tx_slot_first = fep->tx_slot; while (len) { size = min(len, DESC_BUF_SIZE); fep->tx_desc[fep->tx_slot].data_len = (short)size; fep->tx_desc[fep->tx_slot].data_ptr = (unsigned char *)dma_map_single(&fep->ocpdev->dev, (void *)((unsigned int)skb-> data + offset), size, DMA_TO_DEVICE); ctrl = EMAC_TX_CTRL_DFLT; if (fep->tx_slot != tx_slot_first) ctrl |= MAL_TX_CTRL_READY; if ((NUM_TX_BUFF - 1) == fep->tx_slot) ctrl |= MAL_TX_CTRL_WRAP; if (!nr_frags && (len == size)) { ctrl |= MAL_TX_CTRL_LAST; fep->tx_skb[fep->tx_slot] = skb; } if (skb->ip_summed == CHECKSUM_HW) ctrl |= EMAC_TX_CTRL_TAH_CSUM; fep->tx_desc[fep->tx_slot].ctrl = ctrl; len -= size; offset += size; /* Bump tx count */ if (++fep->tx_cnt == NUM_TX_BUFF) netif_stop_queue(dev); /* Next descriptor */ if (++fep->tx_slot == NUM_TX_BUFF) fep->tx_slot = 0; } for (f = 0; f < nr_frags; f++) { struct skb_frag_struct *frag; frag = &skb_shinfo(skb)->frags[f]; len = frag->size; offset = 0; while (len) { size = min(len, DESC_BUF_SIZE); dma_map_page(&fep->ocpdev->dev, frag->page, frag->page_offset + offset, size, DMA_TO_DEVICE); ctrl = EMAC_TX_CTRL_DFLT | MAL_TX_CTRL_READY; if ((NUM_TX_BUFF - 1) == fep->tx_slot) ctrl |= MAL_TX_CTRL_WRAP; if ((f == (nr_frags - 1)) && (len == size)) { ctrl |= MAL_TX_CTRL_LAST; fep->tx_skb[fep->tx_slot] = skb; } if (skb->ip_summed == CHECKSUM_HW) ctrl |= EMAC_TX_CTRL_TAH_CSUM; fep->tx_desc[fep->tx_slot].data_len = (short)size; fep->tx_desc[fep->tx_slot].data_ptr = (char *)((page_to_pfn(frag->page) << PAGE_SHIFT) + frag->page_offset + offset); fep->tx_desc[fep->tx_slot].ctrl = ctrl; len -= size; offset += size; /* Bump tx count */ if (++fep->tx_cnt == NUM_TX_BUFF) netif_stop_queue(dev); /* Next descriptor */ if (++fep->tx_slot == NUM_TX_BUFF) fep->tx_slot = 0; } } /* * Deferred set READY on first descriptor of packet to * avoid TX MAL race. */ fep->tx_desc[tx_slot_first].ctrl |= MAL_TX_CTRL_READY; /* Send the packet out. */ out_be32(&emacp->em0tmr0, EMAC_TMR0_XMIT); fep->stats.tx_packets++; fep->stats.tx_bytes += skb->len; PKT_DEBUG(("emac_start_xmit() exitn")); spin_unlock_irqrestore(&fep->lock, flags); return 0; } static int emac_adjust_to_link(struct ocp_enet_private *fep) { emac_t *emacp = fep->emacp; unsigned long mode_reg; int full_duplex, speed; full_duplex = 0; speed = SPEED_10; /* set mode register 1 defaults */ mode_reg = EMAC_M1_DEFAULT; /* Read link mode on PHY */ if (fep->phy_mii.def->ops->read_link(&fep->phy_mii) == 0) { /* If an error occurred, we don't deal with it yet */ full_duplex = (fep->phy_mii.duplex == DUPLEX_FULL); speed = fep->phy_mii.speed; } /* set speed (default is 10Mb) */ switch (speed) { case SPEED_1000: mode_reg |= EMAC_M1_RFS_16K; if (fep->rgmii_dev) { struct ibm_ocp_rgmii *rgmii = RGMII_PRIV(fep->rgmii_dev); if ((rgmii->mode[fep->rgmii_input] == RTBI) || (rgmii->mode[fep->rgmii_input] == TBI)) mode_reg |= EMAC_M1_MF_1000GPCS; else mode_reg |= EMAC_M1_MF_1000MBPS; emac_rgmii_port_speed(fep->rgmii_dev, fep->rgmii_input, 1000); } break; case SPEED_100: mode_reg |= EMAC_M1_MF_100MBPS | EMAC_M1_RFS_4K; if (fep->rgmii_dev) emac_rgmii_port_speed(fep->rgmii_dev, fep->rgmii_input, 100); if (fep->zmii_dev) emac_zmii_port_speed(fep->zmii_dev, fep->zmii_input, 100); break; case SPEED_10: default: mode_reg = (mode_reg & ~EMAC_M1_MF_100MBPS) | EMAC_M1_RFS_4K; if (fep->rgmii_dev) emac_rgmii_port_speed(fep->rgmii_dev, fep->rgmii_input, 10); if (fep->zmii_dev) emac_zmii_port_speed(fep->zmii_dev, fep->zmii_input, 10); } if (full_duplex) mode_reg |= EMAC_M1_FDE | EMAC_M1_EIFC | EMAC_M1_IST; else mode_reg &= ~(EMAC_M1_FDE | EMAC_M1_EIFC | EMAC_M1_ILE); LINK_DEBUG(("%s: adjust to link, speed: %d, duplex: %d, opened: %d\n", fep->ndev->name, speed, full_duplex, fep->opened)); printk(KERN_INFO "%s: Speed: %d, %s duplex.\n", fep->ndev->name, speed, full_duplex ? "Full" : "Half"); if (fep->opened) out_be32(&emacp->em0mr1, mode_reg); return 0; } static int emac_set_mac_address(struct net_device *ndev, void *p) { struct ocp_enet_private *fep = ndev->priv; emac_t *emacp = fep->emacp; struct sockaddr *addr = p; if (!is_valid_ether_addr(addr->sa_data)) return -EADDRNOTAVAIL; memcpy(ndev->dev_addr, addr->sa_data, ndev->addr_len); /* set the high address */ out_be32(&emacp->em0iahr, (fep->ndev->dev_addr[0] << 8) | fep->ndev->dev_addr[1]); /* set the low address */ out_be32(&emacp->em0ialr, (fep->ndev->dev_addr[2] << 24) | (fep->ndev->dev_addr[3] << 16) | (fep->ndev->dev_addr[4] << 8) | fep->ndev->dev_addr[5]); return 0; } static int emac_change_mtu(struct net_device *dev, int new_mtu) { struct ocp_enet_private *fep = dev->priv; int old_mtu = dev->mtu; unsigned long mode_reg; emac_t *emacp = fep->emacp; u32 em0mr0; int i, full; unsigned long flags; if ((new_mtu < EMAC_MIN_MTU) || (new_mtu > EMAC_MAX_MTU)) { printk(KERN_ERR "emac: Invalid MTU setting, MTU must be between %d and %d\n", EMAC_MIN_MTU, EMAC_MAX_MTU); return -EINVAL; } if (old_mtu != new_mtu && netif_running(dev)) { /* Stop rx engine */ em0mr0 = in_be32(&emacp->em0mr0); out_be32(&emacp->em0mr0, em0mr0 & ~EMAC_M0_RXE); /* Wait for descriptors to be empty */ do { full = 0; for (i = 0; i < NUM_RX_BUFF; i++) if (!(fep->rx_desc[i].ctrl & MAL_RX_CTRL_EMPTY)) { printk(KERN_NOTICE "emac: RX ring is still full\n"); full = 1; } } while (full); spin_lock_irqsave(&fep->lock, flags); mal_disable_rx_channels(fep->mal, fep->commac.rx_chan_mask); /* Destroy all old rx skbs */ for (i = 0; i < NUM_RX_BUFF; i++) { dma_unmap_single(&fep->ocpdev->dev, fep->rx_desc[i].data_ptr, fep->rx_desc[i].data_len, DMA_FROM_DEVICE); dev_kfree_skb(fep->rx_skb[i]); fep->rx_skb[i] = NULL; } /* Set new rx_buffer_size, jumbo cap, and advertise new mtu */ mode_reg = in_be32(&emacp->em0mr1); if (new_mtu > ENET_DEF_MTU_SIZE) { mode_reg |= EMAC_M1_JUMBO_ENABLE; fep->rx_buffer_size = EMAC_MAX_FRAME; } else { mode_reg &= ~EMAC_M1_JUMBO_ENABLE; fep->rx_buffer_size = ENET_DEF_BUF_SIZE; } dev->mtu = new_mtu; out_be32(&emacp->em0mr1, mode_reg); /* Re-init rx skbs */ fep->rx_slot = 0; emac_rx_fill(dev, 0); /* Restart the rx engine */ mal_enable_rx_channels(fep->mal, fep->commac.rx_chan_mask); out_be32(&emacp->em0mr0, em0mr0 | EMAC_M0_RXE); spin_unlock_irqrestore(&fep->lock, flags); } return 0; } static void __emac_set_multicast_list(struct net_device *dev) { struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; u32 rmr = in_be32(&emacp->em0rmr); /* First clear all special bits, they can be set later */ rmr &= ~(EMAC_RMR_PME | EMAC_RMR_PMME | EMAC_RMR_MAE); if (dev->flags & IFF_PROMISC) { rmr |= EMAC_RMR_PME; } else if (dev->flags & IFF_ALLMULTI || 32 < dev->mc_count) { /* * Must be setting up to use multicast * Now check for promiscuous multicast */ rmr |= EMAC_RMR_PMME; } else if (dev->flags & IFF_MULTICAST && 0 < dev->mc_count) { unsigned short em0gaht[4] = { 0, 0, 0, 0 }; struct dev_mc_list *dmi; /* Need to hash on the multicast address. */ for (dmi = dev->mc_list; dmi; dmi = dmi->next) { unsigned long mc_crc; unsigned int bit_number; mc_crc = ether_crc(6, (char *)dmi->dmi_addr); bit_number = 63 - (mc_crc >> 26); /* MSB: 0 LSB: 63 */ em0gaht[bit_number >> 4] |= 0x8000 >> (bit_number & 0x0f); } emacp->em0gaht1 = em0gaht[0]; emacp->em0gaht2 = em0gaht[1]; emacp->em0gaht3 = em0gaht[2]; emacp->em0gaht4 = em0gaht[3]; /* Turn on multicast addressing */ rmr |= EMAC_RMR_MAE; } out_be32(&emacp->em0rmr, rmr); } static int emac_init_tah(struct ocp_enet_private *fep) { tah_t *tahp; /* Initialize TAH and enable checksum verification */ tahp = (tah_t *) ioremap(fep->tah_dev->def->paddr, sizeof(*tahp)); if (tahp == NULL) { printk(KERN_ERR "tah%d: Cannot ioremap TAH registers!\n", fep->tah_dev->def->index); return -ENOMEM; } out_be32(&tahp->tah_mr, TAH_MR_SR); /* wait for reset to complete */ while (in_be32(&tahp->tah_mr) & TAH_MR_SR) ; /* 10KB TAH TX FIFO accomodates the max MTU of 9000 */ out_be32(&tahp->tah_mr, TAH_MR_CVR | TAH_MR_ST_768 | TAH_MR_TFS_10KB | TAH_MR_DTFP | TAH_MR_DIG); iounmap(&tahp); return 0; } static void emac_init_rings(struct net_device *dev) { struct ocp_enet_private *ep = dev->priv; int loop; ep->tx_desc = (struct mal_descriptor *)((char *)ep->mal->tx_virt_addr + (ep->mal_tx_chan * MAL_DT_ALIGN)); ep->rx_desc = (struct mal_descriptor *)((char *)ep->mal->rx_virt_addr + (ep->mal_rx_chan * MAL_DT_ALIGN)); /* Fill in the transmit descriptor ring. */ for (loop = 0; loop < NUM_TX_BUFF; loop++) { if (ep->tx_skb[loop]) { dma_unmap_single(&ep->ocpdev->dev, ep->tx_desc[loop].data_ptr, ep->tx_desc[loop].data_len, DMA_TO_DEVICE); dev_kfree_skb_irq(ep->tx_skb[loop]); } ep->tx_skb[loop] = NULL; ep->tx_desc[loop].ctrl = 0; ep->tx_desc[loop].data_len = 0; ep->tx_desc[loop].data_ptr = NULL; } ep->tx_desc[loop - 1].ctrl |= MAL_TX_CTRL_WRAP; /* Format the receive descriptor ring. */ ep->rx_slot = 0; /* Default is MTU=1500 + Ethernet overhead */ ep->rx_buffer_size = dev->mtu + ENET_HEADER_SIZE + ENET_FCS_SIZE; emac_rx_fill(dev, 0); if (ep->rx_slot != 0) { printk(KERN_ERR "%s: Not enough mem for RxChain durning Open?\n", dev->name); /*We couldn't fill the ring at startup? *We could clean up and fail to open but right now we will try to *carry on. It may be a sign of a bad NUM_RX_BUFF value */ } ep->tx_cnt = 0; ep->tx_slot = 0; ep->ack_slot = 0; } static void emac_reset_configure(struct ocp_enet_private *fep) { emac_t *emacp = fep->emacp; int i; mal_disable_tx_channels(fep->mal, fep->commac.tx_chan_mask); mal_disable_rx_channels(fep->mal, fep->commac.rx_chan_mask); /* * Check for a link, some PHYs don't provide a clock if * no link is present. Some EMACs will not come out of * soft reset without a PHY clock present. */ if (fep->phy_mii.def->ops->poll_link(&fep->phy_mii)) { /* Reset the EMAC */ out_be32(&emacp->em0mr0, EMAC_M0_SRST); udelay(20); for (i = 0; i < 100; i++) { if ((in_be32(&emacp->em0mr0) & EMAC_M0_SRST) == 0) break; udelay(10); } if (i >= 100) { printk(KERN_ERR "%s: Cannot reset EMAC\n", fep->ndev->name); return; } } /* Switch IRQs off for now */ out_be32(&emacp->em0iser, 0); /* Configure MAL rx channel */ mal_set_rcbs(fep->mal, fep->mal_rx_chan, DESC_BUF_SIZE_REG); /* set the high address */ out_be32(&emacp->em0iahr, (fep->ndev->dev_addr[0] << 8) | fep->ndev->dev_addr[1]); /* set the low address */ out_be32(&emacp->em0ialr, (fep->ndev->dev_addr[2] << 24) | (fep->ndev->dev_addr[3] << 16) | (fep->ndev->dev_addr[4] << 8) | fep->ndev->dev_addr[5]); /* Adjust to link */ if (netif_carrier_ok(fep->ndev)) emac_adjust_to_link(fep); /* enable broadcast/individual address and RX FIFO defaults */ out_be32(&emacp->em0rmr, EMAC_RMR_DEFAULT); /* set transmit request threshold register */ out_be32(&emacp->em0trtr, EMAC_TRTR_DEFAULT); /* Reconfigure multicast */ __emac_set_multicast_list(fep->ndev); /* Set receiver/transmitter defaults */ out_be32(&emacp->em0rwmr, EMAC_RWMR_DEFAULT); out_be32(&emacp->em0tmr0, EMAC_TMR0_DEFAULT); out_be32(&emacp->em0tmr1, EMAC_TMR1_DEFAULT); /* set frame gap */ out_be32(&emacp->em0ipgvr, CONFIG_IBM_EMAC_FGAP); /* set VLAN Tag Protocol Identifier */ out_be32(&emacp->em0vtpid, 0x8100); /* Init ring buffers */ emac_init_rings(fep->ndev); } static void emac_kick(struct ocp_enet_private *fep) { emac_t *emacp = fep->emacp; unsigned long emac_ier; emac_ier = EMAC_ISR_PP | EMAC_ISR_BP | EMAC_ISR_RP | EMAC_ISR_SE | EMAC_ISR_PTLE | EMAC_ISR_ALE | EMAC_ISR_BFCS | EMAC_ISR_ORE | EMAC_ISR_IRE; out_be32(&emacp->em0iser, emac_ier); /* enable all MAL transmit and receive channels */ mal_enable_tx_channels(fep->mal, fep->commac.tx_chan_mask); mal_enable_rx_channels(fep->mal, fep->commac.rx_chan_mask); /* set transmit and receive enable */ out_be32(&emacp->em0mr0, EMAC_M0_TXE | EMAC_M0_RXE); } static void emac_start_link(struct ocp_enet_private *fep, struct ethtool_cmd *ep) { u32 advertise; int autoneg; int forced_speed; int forced_duplex; /* Default advertise */ advertise = ADVERTISED_10baseT_Half | ADVERTISED_10baseT_Full | ADVERTISED_100baseT_Half | ADVERTISED_100baseT_Full | ADVERTISED_1000baseT_Half | ADVERTISED_1000baseT_Full; autoneg = fep->want_autoneg; forced_speed = fep->phy_mii.speed; forced_duplex = fep->phy_mii.duplex; /* Setup link parameters */ if (ep) { if (ep->autoneg == AUTONEG_ENABLE) { advertise = ep->advertising; autoneg = 1; } else { autoneg = 0; forced_speed = ep->speed; forced_duplex = ep->duplex; } } /* Configure PHY & start aneg */ fep->want_autoneg = autoneg; if (autoneg) { LINK_DEBUG(("%s: start link aneg, advertise: 0x%x\n", fep->ndev->name, advertise)); fep->phy_mii.def->ops->setup_aneg(&fep->phy_mii, advertise); } else { LINK_DEBUG(("%s: start link forced, speed: %d, duplex: %d\n", fep->ndev->name, forced_speed, forced_duplex)); fep->phy_mii.def->ops->setup_forced(&fep->phy_mii, forced_speed, forced_duplex); } fep->timer_ticks = 0; mod_timer(&fep->link_timer, jiffies + HZ); } static void emac_link_timer(unsigned long data) { struct ocp_enet_private *fep = (struct ocp_enet_private *)data; int link; if (fep->going_away) return; spin_lock_irq(&fep->lock); link = fep->phy_mii.def->ops->poll_link(&fep->phy_mii); LINK_DEBUG(("%s: poll_link: %d\n", fep->ndev->name, link)); if (link == netif_carrier_ok(fep->ndev)) { if (!link && fep->want_autoneg && (++fep->timer_ticks) > 10) emac_start_link(fep, NULL); goto out; } printk(KERN_INFO "%s: Link is %s\n", fep->ndev->name, link ? "Up" : "Down"); if (link) { netif_carrier_on(fep->ndev); /* Chip needs a full reset on config change. That sucks, so I * should ultimately move that to some tasklet to limit * latency peaks caused by this code */ emac_reset_configure(fep); if (fep->opened) emac_kick(fep); } else { fep->timer_ticks = 0; netif_carrier_off(fep->ndev); } out: mod_timer(&fep->link_timer, jiffies + HZ); spin_unlock_irq(&fep->lock); } static void emac_set_multicast_list(struct net_device *dev) { struct ocp_enet_private *fep = dev->priv; spin_lock_irq(&fep->lock); __emac_set_multicast_list(dev); spin_unlock_irq(&fep->lock); } static int emac_get_settings(struct net_device *ndev, struct ethtool_cmd *cmd) { struct ocp_enet_private *fep = ndev->priv; cmd->supported = fep->phy_mii.def->features; cmd->port = PORT_MII; cmd->transceiver = XCVR_EXTERNAL; cmd->phy_address = fep->mii_phy_addr; spin_lock_irq(&fep->lock); cmd->autoneg = fep->want_autoneg; cmd->speed = fep->phy_mii.speed; cmd->duplex = fep->phy_mii.duplex; spin_unlock_irq(&fep->lock); return 0; } static int emac_set_settings(struct net_device *ndev, struct ethtool_cmd *cmd) { struct ocp_enet_private *fep = ndev->priv; unsigned long features = fep->phy_mii.def->features; if (!capable(CAP_NET_ADMIN)) return -EPERM; if (cmd->autoneg != AUTONEG_ENABLE && cmd->autoneg != AUTONEG_DISABLE) return -EINVAL; if (cmd->autoneg == AUTONEG_ENABLE && cmd->advertising == 0) return -EINVAL; if (cmd->duplex != DUPLEX_HALF && cmd->duplex != DUPLEX_FULL) return -EINVAL; if (cmd->autoneg == AUTONEG_DISABLE) switch (cmd->speed) { case SPEED_10: if (cmd->duplex == DUPLEX_HALF && (features & SUPPORTED_10baseT_Half) == 0) return -EINVAL; if (cmd->duplex == DUPLEX_FULL && (features & SUPPORTED_10baseT_Full) == 0) return -EINVAL; break; case SPEED_100: if (cmd->duplex == DUPLEX_HALF && (features & SUPPORTED_100baseT_Half) == 0) return -EINVAL; if (cmd->duplex == DUPLEX_FULL && (features & SUPPORTED_100baseT_Full) == 0) return -EINVAL; break; case SPEED_1000: if (cmd->duplex == DUPLEX_HALF && (features & SUPPORTED_1000baseT_Half) == 0) return -EINVAL; if (cmd->duplex == DUPLEX_FULL && (features & SUPPORTED_1000baseT_Full) == 0) return -EINVAL; break; default: return -EINVAL; } else if ((features & SUPPORTED_Autoneg) == 0) return -EINVAL; spin_lock_irq(&fep->lock); emac_start_link(fep, cmd); spin_unlock_irq(&fep->lock); return 0; } static void emac_get_drvinfo(struct net_device *ndev, struct ethtool_drvinfo *info) { struct ocp_enet_private *fep = ndev->priv; strcpy(info->driver, DRV_NAME); strcpy(info->version, DRV_VERSION); info->fw_version[0] = '\0'; sprintf(info->bus_info, "IBM EMAC %d", fep->ocpdev->def->index); info->regdump_len = 0; } static int emac_nway_reset(struct net_device *ndev) { struct ocp_enet_private *fep = ndev->priv; if (!fep->want_autoneg) return -EINVAL; spin_lock_irq(&fep->lock); emac_start_link(fep, NULL); spin_unlock_irq(&fep->lock); return 0; } static u32 emac_get_link(struct net_device *ndev) { return netif_carrier_ok(ndev); } static struct ethtool_ops emac_ethtool_ops = { .get_settings = emac_get_settings, .set_settings = emac_set_settings, .get_drvinfo = emac_get_drvinfo, .nway_reset = emac_nway_reset, .get_link = emac_get_link }; static int emac_ioctl(struct net_device *dev, struct ifreq *rq, int cmd) { struct ocp_enet_private *fep = dev->priv; uint16_t *data = (uint16_t *) & rq->ifr_ifru; switch (cmd) { case SIOCGMIIPHY: data[0] = fep->mii_phy_addr; /* Fall through */ case SIOCGMIIREG: data[3] = emac_phy_read(dev, fep->mii_phy_addr, data[1]); return 0; case SIOCSMIIREG: if (!capable(CAP_NET_ADMIN)) return -EPERM; emac_phy_write(dev, fep->mii_phy_addr, data[1], data[2]); return 0; default: return -EOPNOTSUPP; } } static int emac_open(struct net_device *dev) { struct ocp_enet_private *fep = dev->priv; int rc; spin_lock_irq(&fep->lock); fep->opened = 1; netif_carrier_off(dev); /* Reset & configure the chip */ emac_reset_configure(fep); spin_unlock_irq(&fep->lock); /* Request our interrupt lines */ rc = request_irq(dev->irq, emac_mac_irq, 0, "IBM EMAC MAC", dev); if (rc != 0) { printk("dev->irq %d failed\n", dev->irq); goto bail; } /* Kick the chip rx & tx channels into life */ spin_lock_irq(&fep->lock); emac_kick(fep); spin_unlock_irq(&fep->lock); netif_start_queue(dev); bail: return rc; } static int emac_close(struct net_device *dev) { struct ocp_enet_private *fep = dev->priv; emac_t *emacp = fep->emacp; /* XXX Stop IRQ emitting here */ spin_lock_irq(&fep->lock); fep->opened = 0; mal_disable_tx_channels(fep->mal, fep->commac.tx_chan_mask); mal_disable_rx_channels(fep->mal, fep->commac.rx_chan_mask); netif_carrier_off(dev); netif_stop_queue(dev); /* * Check for a link, some PHYs don't provide a clock if * no link is present. Some EMACs will not come out of * soft reset without a PHY clock present. */ if (fep->phy_mii.def->ops->poll_link(&fep->phy_mii)) { out_be32(&emacp->em0mr0, EMAC_M0_SRST); udelay(10); if (emacp->em0mr0 & EMAC_M0_SRST) { /*not sure what to do here hopefully it clears before another open */ printk(KERN_ERR "%s: Phy SoftReset didn't clear, no link?\n", dev->name); } } /* Free the irq's */ free_irq(dev->irq, dev); spin_unlock_irq(&fep->lock); return 0; } static void emac_remove(struct ocp_device *ocpdev) { struct net_device *dev = ocp_get_drvdata(ocpdev); struct ocp_enet_private *ep = dev->priv; /* FIXME: locking, races, ... */ ep->going_away = 1; ocp_set_drvdata(ocpdev, NULL); if (ep->rgmii_dev) emac_close_rgmii(ep->rgmii_dev); if (ep->zmii_dev) emac_close_zmii(ep->zmii_dev); unregister_netdev(dev); del_timer_sync(&ep->link_timer); mal_unregister_commac(ep->mal, &ep->commac); iounmap((void *)ep->emacp); kfree(dev); } struct mal_commac_ops emac_commac_ops = { .txeob = &emac_txeob_dev, .txde = &emac_txde_dev, .rxeob = &emac_rxeob_dev, .rxde = &emac_rxde_dev, }; #ifdef CONFIG_NET_POLL_CONTROLLER static int emac_netpoll(struct net_device *ndev) { emac_rxeob_dev((void *)ndev, 0); emac_txeob_dev((void *)ndev, 0); return 0; } #endif static int emac_init_device(struct ocp_device *ocpdev, struct ibm_ocp_mal *mal) { int deferred_init = 0; int rc = 0, i; struct net_device *ndev; struct ocp_enet_private *ep; struct ocp_func_emac_data *emacdata; int commac_reg = 0; u32 phy_map; emacdata = (struct ocp_func_emac_data *)ocpdev->def->additions; if (!emacdata) { printk(KERN_ERR "emac%d: Missing additional data!\n", ocpdev->def->index); return -ENODEV; } /* Allocate our net_device structure */ ndev = alloc_etherdev(sizeof(struct ocp_enet_private)); if (ndev == NULL) { printk(KERN_ERR "emac%d: Could not allocate ethernet device.\n", ocpdev->def->index); return -ENOMEM; } ep = ndev->priv; ep->ndev = ndev; ep->ocpdev = ocpdev; ndev->irq = ocpdev->def->irq; ep->wol_irq = emacdata->wol_irq; if (emacdata->mdio_idx >= 0) { if (emacdata->mdio_idx == ocpdev->def->index) { /* Set the common MDIO net_device */ mdio_ndev = ndev; deferred_init = 1; } ep->mdio_dev = mdio_ndev; } else { ep->mdio_dev = ndev; } ocp_set_drvdata(ocpdev, ndev); spin_lock_init(&ep->lock); /* Fill out MAL informations and register commac */ ep->mal = mal; ep->mal_tx_chan = emacdata->mal_tx_chan; ep->mal_rx_chan = emacdata->mal_rx_chan; ep->commac.ops = &emac_commac_ops; ep->commac.dev = ndev; ep->commac.tx_chan_mask = MAL_CHAN_MASK(ep->mal_tx_chan); ep->commac.rx_chan_mask = MAL_CHAN_MASK(ep->mal_rx_chan); rc = mal_register_commac(ep->mal, &ep->commac); if (rc != 0) goto bail; commac_reg = 1; /* Map our MMIOs */ ep->emacp = (emac_t *) ioremap(ocpdev->def->paddr, sizeof(emac_t)); /* Check if we need to attach to a ZMII */ if (emacdata->zmii_idx >= 0) { ep->zmii_input = emacdata->zmii_mux; ep->zmii_dev = ocp_find_device(OCP_ANY_ID, OCP_FUNC_ZMII, emacdata->zmii_idx); if (ep->zmii_dev == NULL) printk(KERN_WARNING "emac%d: ZMII %d requested but not found !\n", ocpdev->def->index, emacdata->zmii_idx); else if ((rc = emac_init_zmii(ep->zmii_dev, ep->zmii_input, emacdata->phy_mode)) != 0) goto bail; } /* Check if we need to attach to a RGMII */ if (emacdata->rgmii_idx >= 0) { ep->rgmii_input = emacdata->rgmii_mux; ep->rgmii_dev = ocp_find_device(OCP_ANY_ID, OCP_FUNC_RGMII, emacdata->rgmii_idx); if (ep->rgmii_dev == NULL) printk(KERN_WARNING "emac%d: RGMII %d requested but not found !\n", ocpdev->def->index, emacdata->rgmii_idx); else if ((rc = emac_init_rgmii(ep->rgmii_dev, ep->rgmii_input, emacdata->phy_mode)) != 0) goto bail; } /* Check if we need to attach to a TAH */ if (emacdata->tah_idx >= 0) { ep->tah_dev = ocp_find_device(OCP_ANY_ID, OCP_FUNC_TAH, emacdata->tah_idx); if (ep->tah_dev == NULL) printk(KERN_WARNING "emac%d: TAH %d requested but not found !\n", ocpdev->def->index, emacdata->tah_idx); else if ((rc = emac_init_tah(ep)) != 0) goto bail; } if (deferred_init) { if (!list_empty(&emac_init_list)) { struct list_head *entry; struct emac_def_dev *ddev; list_for_each(entry, &emac_init_list) { ddev = list_entry(entry, struct emac_def_dev, link); emac_init_device(ddev->ocpdev, ddev->mal); } } } /* Init link monitoring timer */ init_timer(&ep->link_timer); ep->link_timer.function = emac_link_timer; ep->link_timer.data = (unsigned long)ep; ep->timer_ticks = 0; /* Fill up the mii_phy structure */ ep->phy_mii.dev = ndev; ep->phy_mii.mdio_read = emac_phy_read; ep->phy_mii.mdio_write = emac_phy_write; ep->phy_mii.mode = emacdata->phy_mode; /* Find PHY */ phy_map = emacdata->phy_map | busy_phy_map; for (i = 0; i <= 0x1f; i++, phy_map >>= 1) { if ((phy_map & 0x1) == 0) { int val = emac_phy_read(ndev, i, MII_BMCR); if (val != 0xffff && val != -1) break; } } if (i == 0x20) { printk(KERN_WARNING "emac%d: Can't find PHY.\n", ocpdev->def->index); rc = -ENODEV; goto bail; } busy_phy_map |= 1 << i; ep->mii_phy_addr = i; rc = mii_phy_probe(&ep->phy_mii, i); if (rc) { printk(KERN_WARNING "emac%d: Failed to probe PHY type.\n", ocpdev->def->index); rc = -ENODEV; goto bail; } /* Setup initial PHY config & startup aneg */ if (ep->phy_mii.def->ops->init) ep->phy_mii.def->ops->init(&ep->phy_mii); netif_carrier_off(ndev); if (ep->phy_mii.def->features & SUPPORTED_Autoneg) ep->want_autoneg = 1; emac_start_link(ep, NULL); /* read the MAC Address */ for (i = 0; i < 6; i++) ndev->dev_addr[i] = emacdata->mac_addr[i]; /* Fill in the driver function table */ ndev->open = &emac_open; ndev->hard_start_xmit = &emac_start_xmit; ndev->stop = &emac_close; ndev->get_stats = &emac_stats; if (emacdata->jumbo) ndev->change_mtu = &emac_change_mtu; ndev->set_mac_address = &emac_set_mac_address; ndev->set_multicast_list = &emac_set_multicast_list; ndev->do_ioctl = &emac_ioctl; SET_ETHTOOL_OPS(ndev, &emac_ethtool_ops); if (emacdata->tah_idx >= 0) ndev->features = NETIF_F_IP_CSUM | NETIF_F_SG; #ifdef CONFIG_NET_POLL_CONTROLLER ndev->poll_controller = emac_netpoll; #endif SET_MODULE_OWNER(ndev); rc = register_netdev(ndev); if (rc != 0) goto bail; printk("%s: IBM emac, MAC %02x:%02x:%02x:%02x:%02x:%02x\n", ndev->name, ndev->dev_addr[0], ndev->dev_addr[1], ndev->dev_addr[2], ndev->dev_addr[3], ndev->dev_addr[4], ndev->dev_addr[5]); printk(KERN_INFO "%s: Found %s PHY (0x%02x)\n", ndev->name, ep->phy_mii.def->name, ep->mii_phy_addr); bail: if (rc && commac_reg) mal_unregister_commac(ep->mal, &ep->commac); if (rc && ndev) kfree(ndev); return rc; } static int emac_probe(struct ocp_device *ocpdev) { struct ocp_device *maldev; struct ibm_ocp_mal *mal; struct ocp_func_emac_data *emacdata; emacdata = (struct ocp_func_emac_data *)ocpdev->def->additions; if (emacdata == NULL) { printk(KERN_ERR "emac%d: Missing additional datas !\n", ocpdev->def->index); return -ENODEV; } /* Get the MAL device */ maldev = ocp_find_device(OCP_ANY_ID, OCP_FUNC_MAL, emacdata->mal_idx); if (maldev == NULL) { printk("No maldev\n"); return -ENODEV; } /* * Get MAL driver data, it must be here due to link order. * When the driver is modularized, symbol dependencies will * ensure the MAL driver is already present if built as a * module. */ mal = (struct ibm_ocp_mal *)ocp_get_drvdata(maldev); if (mal == NULL) { printk("No maldrv\n"); return -ENODEV; } /* If we depend on another EMAC for MDIO, wait for it to show up */ if (emacdata->mdio_idx >= 0 && (emacdata->mdio_idx != ocpdev->def->index) && !mdio_ndev) { struct emac_def_dev *ddev; /* Add this index to the deferred init table */ ddev = kmalloc(sizeof(struct emac_def_dev), GFP_KERNEL); ddev->ocpdev = ocpdev; ddev->mal = mal; list_add_tail(&ddev->link, &emac_init_list); } else { emac_init_device(ocpdev, mal); } return 0; } /* Structure for a device driver */ static struct ocp_device_id emac_ids[] = { {.vendor = OCP_ANY_ID,.function = OCP_FUNC_EMAC}, {.vendor = OCP_VENDOR_INVALID} }; static struct ocp_driver emac_driver = { .name = "emac", .id_table = emac_ids, .probe = emac_probe, .remove = emac_remove, }; static int __init emac_init(void) { printk(KERN_INFO DRV_NAME ": " DRV_DESC ", version " DRV_VERSION "\n"); printk(KERN_INFO "Maintained by " DRV_AUTHOR "\n"); if (skb_res > 2) { printk(KERN_WARNING "Invalid skb_res: %d, cropping to 2\n", skb_res); skb_res = 2; } return ocp_register_driver(&emac_driver); } static void __exit emac_exit(void) { ocp_unregister_driver(&emac_driver); } module_init(emac_init); module_exit(emac_exit);