/* * Ethernet driver for S6105 on chip network device * (c)2008 emlix GmbH http://www.emlix.com * Authors: Oskar Schirmer <os@emlix.com> * Daniel Gloeckner <dg@emlix.com> * * 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. */ #include <linux/kernel.h> #include <linux/module.h> #include <linux/interrupt.h> #include <linux/types.h> #include <linux/delay.h> #include <linux/init.h> #include <linux/spinlock.h> #include <linux/netdevice.h> #include <linux/etherdevice.h> #include <linux/if.h> #include <linux/stddef.h> #include <linux/mii.h> #include <linux/phy.h> #include <linux/platform_device.h> #include <variant/hardware.h> #include <variant/dmac.h> #define DRV_NAME "s6gmac" #define DRV_PRMT DRV_NAME ": " /* register declarations */ #define S6_GMAC_MACCONF1 0x000 #define S6_GMAC_MACCONF1_TXENA 0 #define S6_GMAC_MACCONF1_SYNCTX 1 #define S6_GMAC_MACCONF1_RXENA 2 #define S6_GMAC_MACCONF1_SYNCRX 3 #define S6_GMAC_MACCONF1_TXFLOWCTRL 4 #define S6_GMAC_MACCONF1_RXFLOWCTRL 5 #define S6_GMAC_MACCONF1_LOOPBACK 8 #define S6_GMAC_MACCONF1_RESTXFUNC 16 #define S6_GMAC_MACCONF1_RESRXFUNC 17 #define S6_GMAC_MACCONF1_RESTXMACCTRL 18 #define S6_GMAC_MACCONF1_RESRXMACCTRL 19 #define S6_GMAC_MACCONF1_SIMULRES 30 #define S6_GMAC_MACCONF1_SOFTRES 31 #define S6_GMAC_MACCONF2 0x004 #define S6_GMAC_MACCONF2_FULL 0 #define S6_GMAC_MACCONF2_CRCENA 1 #define S6_GMAC_MACCONF2_PADCRCENA 2 #define S6_GMAC_MACCONF2_LENGTHFCHK 4 #define S6_GMAC_MACCONF2_HUGEFRAMENA 5 #define S6_GMAC_MACCONF2_IFMODE 8 #define S6_GMAC_MACCONF2_IFMODE_NIBBLE 1 #define S6_GMAC_MACCONF2_IFMODE_BYTE 2 #define S6_GMAC_MACCONF2_IFMODE_MASK 3 #define S6_GMAC_MACCONF2_PREAMBLELEN 12 #define S6_GMAC_MACCONF2_PREAMBLELEN_MASK 0x0F #define S6_GMAC_MACIPGIFG 0x008 #define S6_GMAC_MACIPGIFG_B2BINTERPGAP 0 #define S6_GMAC_MACIPGIFG_B2BINTERPGAP_MASK 0x7F #define S6_GMAC_MACIPGIFG_MINIFGENFORCE 8 #define S6_GMAC_MACIPGIFG_B2BINTERPGAP2 16 #define S6_GMAC_MACIPGIFG_B2BINTERPGAP1 24 #define S6_GMAC_MACHALFDUPLEX 0x00C #define S6_GMAC_MACHALFDUPLEX_COLLISWIN 0 #define S6_GMAC_MACHALFDUPLEX_COLLISWIN_MASK 0x3F #define S6_GMAC_MACHALFDUPLEX_RETXMAX 12 #define S6_GMAC_MACHALFDUPLEX_RETXMAX_MASK 0x0F #define S6_GMAC_MACHALFDUPLEX_EXCESSDEF 16 #define S6_GMAC_MACHALFDUPLEX_NOBACKOFF 17 #define S6_GMAC_MACHALFDUPLEX_BPNOBCKOF 18 #define S6_GMAC_MACHALFDUPLEX_ALTBEBENA 19 #define S6_GMAC_MACHALFDUPLEX_ALTBEBTRN 20 #define S6_GMAC_MACHALFDUPLEX_ALTBEBTR_MASK 0x0F #define S6_GMAC_MACMAXFRAMELEN 0x010 #define S6_GMAC_MACMIICONF 0x020 #define S6_GMAC_MACMIICONF_CSEL 0 #define S6_GMAC_MACMIICONF_CSEL_DIV10 0 #define S6_GMAC_MACMIICONF_CSEL_DIV12 1 #define S6_GMAC_MACMIICONF_CSEL_DIV14 2 #define S6_GMAC_MACMIICONF_CSEL_DIV18 3 #define S6_GMAC_MACMIICONF_CSEL_DIV24 4 #define S6_GMAC_MACMIICONF_CSEL_DIV34 5 #define S6_GMAC_MACMIICONF_CSEL_DIV68 6 #define S6_GMAC_MACMIICONF_CSEL_DIV168 7 #define S6_GMAC_MACMIICONF_CSEL_MASK 7 #define S6_GMAC_MACMIICONF_PREAMBLESUPR 4 #define S6_GMAC_MACMIICONF_SCANAUTOINCR 5 #define S6_GMAC_MACMIICMD 0x024 #define S6_GMAC_MACMIICMD_READ 0 #define S6_GMAC_MACMIICMD_SCAN 1 #define S6_GMAC_MACMIIADDR 0x028 #define S6_GMAC_MACMIIADDR_REG 0 #define S6_GMAC_MACMIIADDR_REG_MASK 0x1F #define S6_GMAC_MACMIIADDR_PHY 8 #define S6_GMAC_MACMIIADDR_PHY_MASK 0x1F #define S6_GMAC_MACMIICTRL 0x02C #define S6_GMAC_MACMIISTAT 0x030 #define S6_GMAC_MACMIIINDI 0x034 #define S6_GMAC_MACMIIINDI_BUSY 0 #define S6_GMAC_MACMIIINDI_SCAN 1 #define S6_GMAC_MACMIIINDI_INVAL 2 #define S6_GMAC_MACINTERFSTAT 0x03C #define S6_GMAC_MACINTERFSTAT_LINKFAIL 3 #define S6_GMAC_MACINTERFSTAT_EXCESSDEF 9 #define S6_GMAC_MACSTATADDR1 0x040 #define S6_GMAC_MACSTATADDR2 0x044 #define S6_GMAC_FIFOCONF0 0x048 #define S6_GMAC_FIFOCONF0_HSTRSTWT 0 #define S6_GMAC_FIFOCONF0_HSTRSTSR 1 #define S6_GMAC_FIFOCONF0_HSTRSTFR 2 #define S6_GMAC_FIFOCONF0_HSTRSTST 3 #define S6_GMAC_FIFOCONF0_HSTRSTFT 4 #define S6_GMAC_FIFOCONF0_WTMENREQ 8 #define S6_GMAC_FIFOCONF0_SRFENREQ 9 #define S6_GMAC_FIFOCONF0_FRFENREQ 10 #define S6_GMAC_FIFOCONF0_STFENREQ 11 #define S6_GMAC_FIFOCONF0_FTFENREQ 12 #define S6_GMAC_FIFOCONF0_WTMENRPLY 16 #define S6_GMAC_FIFOCONF0_SRFENRPLY 17 #define S6_GMAC_FIFOCONF0_FRFENRPLY 18 #define S6_GMAC_FIFOCONF0_STFENRPLY 19 #define S6_GMAC_FIFOCONF0_FTFENRPLY 20 #define S6_GMAC_FIFOCONF1 0x04C #define S6_GMAC_FIFOCONF2 0x050 #define S6_GMAC_FIFOCONF2_CFGLWM 0 #define S6_GMAC_FIFOCONF2_CFGHWM 16 #define S6_GMAC_FIFOCONF3 0x054 #define S6_GMAC_FIFOCONF3_CFGFTTH 0 #define S6_GMAC_FIFOCONF3_CFGHWMFT 16 #define S6_GMAC_FIFOCONF4 0x058 #define S6_GMAC_FIFOCONF_RSV_PREVDROP 0 #define S6_GMAC_FIFOCONF_RSV_RUNT 1 #define S6_GMAC_FIFOCONF_RSV_FALSECAR 2 #define S6_GMAC_FIFOCONF_RSV_CODEERR 3 #define S6_GMAC_FIFOCONF_RSV_CRCERR 4 #define S6_GMAC_FIFOCONF_RSV_LENGTHERR 5 #define S6_GMAC_FIFOCONF_RSV_LENRANGE 6 #define S6_GMAC_FIFOCONF_RSV_OK 7 #define S6_GMAC_FIFOCONF_RSV_MULTICAST 8 #define S6_GMAC_FIFOCONF_RSV_BROADCAST 9 #define S6_GMAC_FIFOCONF_RSV_DRIBBLE 10 #define S6_GMAC_FIFOCONF_RSV_CTRLFRAME 11 #define S6_GMAC_FIFOCONF_RSV_PAUSECTRL 12 #define S6_GMAC_FIFOCONF_RSV_UNOPCODE 13 #define S6_GMAC_FIFOCONF_RSV_VLANTAG 14 #define S6_GMAC_FIFOCONF_RSV_LONGEVENT 15 #define S6_GMAC_FIFOCONF_RSV_TRUNCATED 16 #define S6_GMAC_FIFOCONF_RSV_MASK 0x3FFFF #define S6_GMAC_FIFOCONF5 0x05C #define S6_GMAC_FIFOCONF5_DROPLT64 18 #define S6_GMAC_FIFOCONF5_CFGBYTM 19 #define S6_GMAC_FIFOCONF5_RXDROPSIZE 20 #define S6_GMAC_FIFOCONF5_RXDROPSIZE_MASK 0xF #define S6_GMAC_STAT_REGS 0x080 #define S6_GMAC_STAT_SIZE_MIN 12 #define S6_GMAC_STATTR64 0x080 #define S6_GMAC_STATTR64_SIZE 18 #define S6_GMAC_STATTR127 0x084 #define S6_GMAC_STATTR127_SIZE 18 #define S6_GMAC_STATTR255 0x088 #define S6_GMAC_STATTR255_SIZE 18 #define S6_GMAC_STATTR511 0x08C #define S6_GMAC_STATTR511_SIZE 18 #define S6_GMAC_STATTR1K 0x090 #define S6_GMAC_STATTR1K_SIZE 18 #define S6_GMAC_STATTRMAX 0x094 #define S6_GMAC_STATTRMAX_SIZE 18 #define S6_GMAC_STATTRMGV 0x098 #define S6_GMAC_STATTRMGV_SIZE 18 #define S6_GMAC_STATRBYT 0x09C #define S6_GMAC_STATRBYT_SIZE 24 #define S6_GMAC_STATRPKT 0x0A0 #define S6_GMAC_STATRPKT_SIZE 18 #define S6_GMAC_STATRFCS 0x0A4 #define S6_GMAC_STATRFCS_SIZE 12 #define S6_GMAC_STATRMCA 0x0A8 #define S6_GMAC_STATRMCA_SIZE 18 #define S6_GMAC_STATRBCA 0x0AC #define S6_GMAC_STATRBCA_SIZE 22 #define S6_GMAC_STATRXCF 0x0B0 #define S6_GMAC_STATRXCF_SIZE 18 #define S6_GMAC_STATRXPF 0x0B4 #define S6_GMAC_STATRXPF_SIZE 12 #define S6_GMAC_STATRXUO 0x0B8 #define S6_GMAC_STATRXUO_SIZE 12 #define S6_GMAC_STATRALN 0x0BC #define S6_GMAC_STATRALN_SIZE 12 #define S6_GMAC_STATRFLR 0x0C0 #define S6_GMAC_STATRFLR_SIZE 16 #define S6_GMAC_STATRCDE 0x0C4 #define S6_GMAC_STATRCDE_SIZE 12 #define S6_GMAC_STATRCSE 0x0C8 #define S6_GMAC_STATRCSE_SIZE 12 #define S6_GMAC_STATRUND 0x0CC #define S6_GMAC_STATRUND_SIZE 12 #define S6_GMAC_STATROVR 0x0D0 #define S6_GMAC_STATROVR_SIZE 12 #define S6_GMAC_STATRFRG 0x0D4 #define S6_GMAC_STATRFRG_SIZE 12 #define S6_GMAC_STATRJBR 0x0D8 #define S6_GMAC_STATRJBR_SIZE 12 #define S6_GMAC_STATRDRP 0x0DC #define S6_GMAC_STATRDRP_SIZE 12 #define S6_GMAC_STATTBYT 0x0E0 #define S6_GMAC_STATTBYT_SIZE 24 #define S6_GMAC_STATTPKT 0x0E4 #define S6_GMAC_STATTPKT_SIZE 18 #define S6_GMAC_STATTMCA 0x0E8 #define S6_GMAC_STATTMCA_SIZE 18 #define S6_GMAC_STATTBCA 0x0EC #define S6_GMAC_STATTBCA_SIZE 18 #define S6_GMAC_STATTXPF 0x0F0 #define S6_GMAC_STATTXPF_SIZE 12 #define S6_GMAC_STATTDFR 0x0F4 #define S6_GMAC_STATTDFR_SIZE 12 #define S6_GMAC_STATTEDF 0x0F8 #define S6_GMAC_STATTEDF_SIZE 12 #define S6_GMAC_STATTSCL 0x0FC #define S6_GMAC_STATTSCL_SIZE 12 #define S6_GMAC_STATTMCL 0x100 #define S6_GMAC_STATTMCL_SIZE 12 #define S6_GMAC_STATTLCL 0x104 #define S6_GMAC_STATTLCL_SIZE 12 #define S6_GMAC_STATTXCL 0x108 #define S6_GMAC_STATTXCL_SIZE 12 #define S6_GMAC_STATTNCL 0x10C #define S6_GMAC_STATTNCL_SIZE 13 #define S6_GMAC_STATTPFH 0x110 #define S6_GMAC_STATTPFH_SIZE 12 #define S6_GMAC_STATTDRP 0x114 #define S6_GMAC_STATTDRP_SIZE 12 #define S6_GMAC_STATTJBR 0x118 #define S6_GMAC_STATTJBR_SIZE 12 #define S6_GMAC_STATTFCS 0x11C #define S6_GMAC_STATTFCS_SIZE 12 #define S6_GMAC_STATTXCF 0x120 #define S6_GMAC_STATTXCF_SIZE 12 #define S6_GMAC_STATTOVR 0x124 #define S6_GMAC_STATTOVR_SIZE 12 #define S6_GMAC_STATTUND 0x128 #define S6_GMAC_STATTUND_SIZE 12 #define S6_GMAC_STATTFRG 0x12C #define S6_GMAC_STATTFRG_SIZE 12 #define S6_GMAC_STATCARRY(n) (0x130 + 4*(n)) #define S6_GMAC_STATCARRYMSK(n) (0x138 + 4*(n)) #define S6_GMAC_STATCARRY1_RDRP 0 #define S6_GMAC_STATCARRY1_RJBR 1 #define S6_GMAC_STATCARRY1_RFRG 2 #define S6_GMAC_STATCARRY1_ROVR 3 #define S6_GMAC_STATCARRY1_RUND 4 #define S6_GMAC_STATCARRY1_RCSE 5 #define S6_GMAC_STATCARRY1_RCDE 6 #define S6_GMAC_STATCARRY1_RFLR 7 #define S6_GMAC_STATCARRY1_RALN 8 #define S6_GMAC_STATCARRY1_RXUO 9 #define S6_GMAC_STATCARRY1_RXPF 10 #define S6_GMAC_STATCARRY1_RXCF 11 #define S6_GMAC_STATCARRY1_RBCA 12 #define S6_GMAC_STATCARRY1_RMCA 13 #define S6_GMAC_STATCARRY1_RFCS 14 #define S6_GMAC_STATCARRY1_RPKT 15 #define S6_GMAC_STATCARRY1_RBYT 16 #define S6_GMAC_STATCARRY1_TRMGV 25 #define S6_GMAC_STATCARRY1_TRMAX 26 #define S6_GMAC_STATCARRY1_TR1K 27 #define S6_GMAC_STATCARRY1_TR511 28 #define S6_GMAC_STATCARRY1_TR255 29 #define S6_GMAC_STATCARRY1_TR127 30 #define S6_GMAC_STATCARRY1_TR64 31 #define S6_GMAC_STATCARRY2_TDRP 0 #define S6_GMAC_STATCARRY2_TPFH 1 #define S6_GMAC_STATCARRY2_TNCL 2 #define S6_GMAC_STATCARRY2_TXCL 3 #define S6_GMAC_STATCARRY2_TLCL 4 #define S6_GMAC_STATCARRY2_TMCL 5 #define S6_GMAC_STATCARRY2_TSCL 6 #define S6_GMAC_STATCARRY2_TEDF 7 #define S6_GMAC_STATCARRY2_TDFR 8 #define S6_GMAC_STATCARRY2_TXPF 9 #define S6_GMAC_STATCARRY2_TBCA 10 #define S6_GMAC_STATCARRY2_TMCA 11 #define S6_GMAC_STATCARRY2_TPKT 12 #define S6_GMAC_STATCARRY2_TBYT 13 #define S6_GMAC_STATCARRY2_TFRG 14 #define S6_GMAC_STATCARRY2_TUND 15 #define S6_GMAC_STATCARRY2_TOVR 16 #define S6_GMAC_STATCARRY2_TXCF 17 #define S6_GMAC_STATCARRY2_TFCS 18 #define S6_GMAC_STATCARRY2_TJBR 19 #define S6_GMAC_HOST_PBLKCTRL 0x140 #define S6_GMAC_HOST_PBLKCTRL_TXENA 0 #define S6_GMAC_HOST_PBLKCTRL_RXENA 1 #define S6_GMAC_HOST_PBLKCTRL_TXSRES 2 #define S6_GMAC_HOST_PBLKCTRL_RXSRES 3 #define S6_GMAC_HOST_PBLKCTRL_TXBSIZ 8 #define S6_GMAC_HOST_PBLKCTRL_RXBSIZ 12 #define S6_GMAC_HOST_PBLKCTRL_SIZ_16 4 #define S6_GMAC_HOST_PBLKCTRL_SIZ_32 5 #define S6_GMAC_HOST_PBLKCTRL_SIZ_64 6 #define S6_GMAC_HOST_PBLKCTRL_SIZ_128 7 #define S6_GMAC_HOST_PBLKCTRL_SIZ_MASK 0xF #define S6_GMAC_HOST_PBLKCTRL_STATENA 16 #define S6_GMAC_HOST_PBLKCTRL_STATAUTOZ 17 #define S6_GMAC_HOST_PBLKCTRL_STATCLEAR 18 #define S6_GMAC_HOST_PBLKCTRL_RGMII 19 #define S6_GMAC_HOST_INTMASK 0x144 #define S6_GMAC_HOST_INTSTAT 0x148 #define S6_GMAC_HOST_INT_TXBURSTOVER 3 #define S6_GMAC_HOST_INT_TXPREWOVER 4 #define S6_GMAC_HOST_INT_RXBURSTUNDER 5 #define S6_GMAC_HOST_INT_RXPOSTRFULL 6 #define S6_GMAC_HOST_INT_RXPOSTRUNDER 7 #define S6_GMAC_HOST_RXFIFOHWM 0x14C #define S6_GMAC_HOST_CTRLFRAMXP 0x150 #define S6_GMAC_HOST_DSTADDRLO(n) (0x160 + 8*(n)) #define S6_GMAC_HOST_DSTADDRHI(n) (0x164 + 8*(n)) #define S6_GMAC_HOST_DSTMASKLO(n) (0x180 + 8*(n)) #define S6_GMAC_HOST_DSTMASKHI(n) (0x184 + 8*(n)) #define S6_GMAC_BURST_PREWR 0x1B0 #define S6_GMAC_BURST_PREWR_LEN 0 #define S6_GMAC_BURST_PREWR_LEN_MASK ((1 << 20) - 1) #define S6_GMAC_BURST_PREWR_CFE 20 #define S6_GMAC_BURST_PREWR_PPE 21 #define S6_GMAC_BURST_PREWR_FCS 22 #define S6_GMAC_BURST_PREWR_PAD 23 #define S6_GMAC_BURST_POSTRD 0x1D0 #define S6_GMAC_BURST_POSTRD_LEN 0 #define S6_GMAC_BURST_POSTRD_LEN_MASK ((1 << 20) - 1) #define S6_GMAC_BURST_POSTRD_DROP 20 /* data handling */ #define S6_NUM_TX_SKB 8 /* must be larger than TX fifo size */ #define S6_NUM_RX_SKB 16 #define S6_MAX_FRLEN 1536 struct s6gmac { u32 reg; u32 tx_dma; u32 rx_dma; u32 io; u8 tx_chan; u8 rx_chan; spinlock_t lock; u8 tx_skb_i, tx_skb_o; u8 rx_skb_i, rx_skb_o; struct sk_buff *tx_skb[S6_NUM_TX_SKB]; struct sk_buff *rx_skb[S6_NUM_RX_SKB]; unsigned long carry[sizeof(struct net_device_stats) / sizeof(long)]; unsigned long stats[sizeof(struct net_device_stats) / sizeof(long)]; struct phy_device *phydev; struct { struct mii_bus *bus; int irq[PHY_MAX_ADDR]; } mii; struct { unsigned int mbit; u8 giga; u8 isup; u8 full; } link; }; static void s6gmac_rx_fillfifo(struct s6gmac *pd) { struct sk_buff *skb; while ((((u8)(pd->rx_skb_i - pd->rx_skb_o)) < S6_NUM_RX_SKB) && (!s6dmac_fifo_full(pd->rx_dma, pd->rx_chan)) && (skb = dev_alloc_skb(S6_MAX_FRLEN + 2))) { pd->rx_skb[(pd->rx_skb_i++) % S6_NUM_RX_SKB] = skb; s6dmac_put_fifo_cache(pd->rx_dma, pd->rx_chan, pd->io, (u32)skb->data, S6_MAX_FRLEN); } } static void s6gmac_rx_interrupt(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); u32 pfx; struct sk_buff *skb; while (((u8)(pd->rx_skb_i - pd->rx_skb_o)) > s6dmac_pending_count(pd->rx_dma, pd->rx_chan)) { skb = pd->rx_skb[(pd->rx_skb_o++) % S6_NUM_RX_SKB]; pfx = readl(pd->reg + S6_GMAC_BURST_POSTRD); if (pfx & (1 << S6_GMAC_BURST_POSTRD_DROP)) { dev_kfree_skb_irq(skb); } else { skb_put(skb, (pfx >> S6_GMAC_BURST_POSTRD_LEN) & S6_GMAC_BURST_POSTRD_LEN_MASK); skb->protocol = eth_type_trans(skb, dev); skb->ip_summed = CHECKSUM_UNNECESSARY; netif_rx(skb); } } } static void s6gmac_tx_interrupt(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); while (((u8)(pd->tx_skb_i - pd->tx_skb_o)) > s6dmac_pending_count(pd->tx_dma, pd->tx_chan)) { dev_kfree_skb_irq(pd->tx_skb[(pd->tx_skb_o++) % S6_NUM_TX_SKB]); } if (!s6dmac_fifo_full(pd->tx_dma, pd->tx_chan)) netif_wake_queue(dev); } struct s6gmac_statinf { unsigned reg_size : 4; /* 0: unused */ unsigned reg_off : 6; unsigned net_index : 6; }; #define S6_STATS_B (8 * sizeof(u32)) #define S6_STATS_C(b, r, f) [b] = { \ BUILD_BUG_ON_ZERO(r##_SIZE < S6_GMAC_STAT_SIZE_MIN) + \ BUILD_BUG_ON_ZERO((r##_SIZE - (S6_GMAC_STAT_SIZE_MIN - 1)) \ >= (1<<4)) + \ r##_SIZE - (S6_GMAC_STAT_SIZE_MIN - 1), \ BUILD_BUG_ON_ZERO(((unsigned)((r - S6_GMAC_STAT_REGS) / sizeof(u32))) \ >= ((1<<6)-1)) + \ (r - S6_GMAC_STAT_REGS) / sizeof(u32), \ BUILD_BUG_ON_ZERO((offsetof(struct net_device_stats, f)) \ % sizeof(unsigned long)) + \ BUILD_BUG_ON_ZERO((((unsigned)(offsetof(struct net_device_stats, f)) \ / sizeof(unsigned long)) >= (1<<6))) + \ BUILD_BUG_ON_ZERO((sizeof(((struct net_device_stats *)0)->f) \ != sizeof(unsigned long))) + \ (offsetof(struct net_device_stats, f)) / sizeof(unsigned long)}, static const struct s6gmac_statinf statinf[2][S6_STATS_B] = { { S6_STATS_C(S6_GMAC_STATCARRY1_RBYT, S6_GMAC_STATRBYT, rx_bytes) S6_STATS_C(S6_GMAC_STATCARRY1_RPKT, S6_GMAC_STATRPKT, rx_packets) S6_STATS_C(S6_GMAC_STATCARRY1_RFCS, S6_GMAC_STATRFCS, rx_crc_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RMCA, S6_GMAC_STATRMCA, multicast) S6_STATS_C(S6_GMAC_STATCARRY1_RALN, S6_GMAC_STATRALN, rx_frame_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RFLR, S6_GMAC_STATRFLR, rx_length_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RCDE, S6_GMAC_STATRCDE, rx_missed_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RUND, S6_GMAC_STATRUND, rx_length_errors) S6_STATS_C(S6_GMAC_STATCARRY1_ROVR, S6_GMAC_STATROVR, rx_length_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RFRG, S6_GMAC_STATRFRG, rx_crc_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RJBR, S6_GMAC_STATRJBR, rx_crc_errors) S6_STATS_C(S6_GMAC_STATCARRY1_RDRP, S6_GMAC_STATRDRP, rx_dropped) }, { S6_STATS_C(S6_GMAC_STATCARRY2_TBYT, S6_GMAC_STATTBYT, tx_bytes) S6_STATS_C(S6_GMAC_STATCARRY2_TPKT, S6_GMAC_STATTPKT, tx_packets) S6_STATS_C(S6_GMAC_STATCARRY2_TEDF, S6_GMAC_STATTEDF, tx_aborted_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TXCL, S6_GMAC_STATTXCL, tx_aborted_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TNCL, S6_GMAC_STATTNCL, collisions) S6_STATS_C(S6_GMAC_STATCARRY2_TDRP, S6_GMAC_STATTDRP, tx_dropped) S6_STATS_C(S6_GMAC_STATCARRY2_TJBR, S6_GMAC_STATTJBR, tx_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TFCS, S6_GMAC_STATTFCS, tx_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TOVR, S6_GMAC_STATTOVR, tx_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TUND, S6_GMAC_STATTUND, tx_errors) S6_STATS_C(S6_GMAC_STATCARRY2_TFRG, S6_GMAC_STATTFRG, tx_errors) } }; static void s6gmac_stats_collect(struct s6gmac *pd, const struct s6gmac_statinf *inf) { int b; for (b = 0; b < S6_STATS_B; b++) { if (inf[b].reg_size) { pd->stats[inf[b].net_index] += readl(pd->reg + S6_GMAC_STAT_REGS + sizeof(u32) * inf[b].reg_off); } } } static void s6gmac_stats_carry(struct s6gmac *pd, const struct s6gmac_statinf *inf, u32 mask) { int b; while (mask) { b = fls(mask) - 1; mask &= ~(1 << b); pd->carry[inf[b].net_index] += (1 << inf[b].reg_size); } } static inline u32 s6gmac_stats_pending(struct s6gmac *pd, int carry) { int r = readl(pd->reg + S6_GMAC_STATCARRY(carry)) & ~readl(pd->reg + S6_GMAC_STATCARRYMSK(carry)); return r; } static inline void s6gmac_stats_interrupt(struct s6gmac *pd, int carry) { u32 mask; mask = s6gmac_stats_pending(pd, carry); if (mask) { writel(mask, pd->reg + S6_GMAC_STATCARRY(carry)); s6gmac_stats_carry(pd, &statinf[carry][0], mask); } } static irqreturn_t s6gmac_interrupt(int irq, void *dev_id) { struct net_device *dev = (struct net_device *)dev_id; struct s6gmac *pd = netdev_priv(dev); if (!dev) return IRQ_NONE; spin_lock(&pd->lock); if (s6dmac_termcnt_irq(pd->rx_dma, pd->rx_chan)) s6gmac_rx_interrupt(dev); s6gmac_rx_fillfifo(pd); if (s6dmac_termcnt_irq(pd->tx_dma, pd->tx_chan)) s6gmac_tx_interrupt(dev); s6gmac_stats_interrupt(pd, 0); s6gmac_stats_interrupt(pd, 1); spin_unlock(&pd->lock); return IRQ_HANDLED; } static inline void s6gmac_set_dstaddr(struct s6gmac *pd, int n, u32 addrlo, u32 addrhi, u32 masklo, u32 maskhi) { writel(addrlo, pd->reg + S6_GMAC_HOST_DSTADDRLO(n)); writel(addrhi, pd->reg + S6_GMAC_HOST_DSTADDRHI(n)); writel(masklo, pd->reg + S6_GMAC_HOST_DSTMASKLO(n)); writel(maskhi, pd->reg + S6_GMAC_HOST_DSTMASKHI(n)); } static inline void s6gmac_stop_device(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); writel(0, pd->reg + S6_GMAC_MACCONF1); } static inline void s6gmac_init_device(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); int is_rgmii = !!(pd->phydev->supported & (SUPPORTED_1000baseT_Full | SUPPORTED_1000baseT_Half)); #if 0 writel(1 << S6_GMAC_MACCONF1_SYNCTX | 1 << S6_GMAC_MACCONF1_SYNCRX | 1 << S6_GMAC_MACCONF1_TXFLOWCTRL | 1 << S6_GMAC_MACCONF1_RXFLOWCTRL | 1 << S6_GMAC_MACCONF1_RESTXFUNC | 1 << S6_GMAC_MACCONF1_RESRXFUNC | 1 << S6_GMAC_MACCONF1_RESTXMACCTRL | 1 << S6_GMAC_MACCONF1_RESRXMACCTRL, pd->reg + S6_GMAC_MACCONF1); #endif writel(1 << S6_GMAC_MACCONF1_SOFTRES, pd->reg + S6_GMAC_MACCONF1); udelay(1000); writel(1 << S6_GMAC_MACCONF1_TXENA | 1 << S6_GMAC_MACCONF1_RXENA, pd->reg + S6_GMAC_MACCONF1); writel(1 << S6_GMAC_HOST_PBLKCTRL_TXSRES | 1 << S6_GMAC_HOST_PBLKCTRL_RXSRES, pd->reg + S6_GMAC_HOST_PBLKCTRL); writel(S6_GMAC_HOST_PBLKCTRL_SIZ_128 << S6_GMAC_HOST_PBLKCTRL_TXBSIZ | S6_GMAC_HOST_PBLKCTRL_SIZ_128 << S6_GMAC_HOST_PBLKCTRL_RXBSIZ | 1 << S6_GMAC_HOST_PBLKCTRL_STATENA | 1 << S6_GMAC_HOST_PBLKCTRL_STATCLEAR | is_rgmii << S6_GMAC_HOST_PBLKCTRL_RGMII, pd->reg + S6_GMAC_HOST_PBLKCTRL); writel(1 << S6_GMAC_MACCONF1_TXENA | 1 << S6_GMAC_MACCONF1_RXENA | (dev->flags & IFF_LOOPBACK ? 1 : 0) << S6_GMAC_MACCONF1_LOOPBACK, pd->reg + S6_GMAC_MACCONF1); writel(dev->mtu && (dev->mtu < (S6_MAX_FRLEN - ETH_HLEN-ETH_FCS_LEN)) ? dev->mtu+ETH_HLEN+ETH_FCS_LEN : S6_MAX_FRLEN, pd->reg + S6_GMAC_MACMAXFRAMELEN); writel((pd->link.full ? 1 : 0) << S6_GMAC_MACCONF2_FULL | 1 << S6_GMAC_MACCONF2_PADCRCENA | 1 << S6_GMAC_MACCONF2_LENGTHFCHK | (pd->link.giga ? S6_GMAC_MACCONF2_IFMODE_BYTE : S6_GMAC_MACCONF2_IFMODE_NIBBLE) << S6_GMAC_MACCONF2_IFMODE | 7 << S6_GMAC_MACCONF2_PREAMBLELEN, pd->reg + S6_GMAC_MACCONF2); writel(0, pd->reg + S6_GMAC_MACSTATADDR1); writel(0, pd->reg + S6_GMAC_MACSTATADDR2); writel(1 << S6_GMAC_FIFOCONF0_WTMENREQ | 1 << S6_GMAC_FIFOCONF0_SRFENREQ | 1 << S6_GMAC_FIFOCONF0_FRFENREQ | 1 << S6_GMAC_FIFOCONF0_STFENREQ | 1 << S6_GMAC_FIFOCONF0_FTFENREQ, pd->reg + S6_GMAC_FIFOCONF0); writel(128 << S6_GMAC_FIFOCONF3_CFGFTTH | 128 << S6_GMAC_FIFOCONF3_CFGHWMFT, pd->reg + S6_GMAC_FIFOCONF3); writel((S6_GMAC_FIFOCONF_RSV_MASK & ~( 1 << S6_GMAC_FIFOCONF_RSV_RUNT | 1 << S6_GMAC_FIFOCONF_RSV_CRCERR | 1 << S6_GMAC_FIFOCONF_RSV_OK | 1 << S6_GMAC_FIFOCONF_RSV_DRIBBLE | 1 << S6_GMAC_FIFOCONF_RSV_CTRLFRAME | 1 << S6_GMAC_FIFOCONF_RSV_PAUSECTRL | 1 << S6_GMAC_FIFOCONF_RSV_UNOPCODE | 1 << S6_GMAC_FIFOCONF_RSV_TRUNCATED)) | 1 << S6_GMAC_FIFOCONF5_DROPLT64 | pd->link.giga << S6_GMAC_FIFOCONF5_CFGBYTM | 1 << S6_GMAC_FIFOCONF5_RXDROPSIZE, pd->reg + S6_GMAC_FIFOCONF5); writel(1 << S6_GMAC_FIFOCONF_RSV_RUNT | 1 << S6_GMAC_FIFOCONF_RSV_CRCERR | 1 << S6_GMAC_FIFOCONF_RSV_DRIBBLE | 1 << S6_GMAC_FIFOCONF_RSV_CTRLFRAME | 1 << S6_GMAC_FIFOCONF_RSV_PAUSECTRL | 1 << S6_GMAC_FIFOCONF_RSV_UNOPCODE | 1 << S6_GMAC_FIFOCONF_RSV_TRUNCATED, pd->reg + S6_GMAC_FIFOCONF4); s6gmac_set_dstaddr(pd, 0, 0xFFFFFFFF, 0x0000FFFF, 0xFFFFFFFF, 0x0000FFFF); s6gmac_set_dstaddr(pd, 1, dev->dev_addr[5] | dev->dev_addr[4] << 8 | dev->dev_addr[3] << 16 | dev->dev_addr[2] << 24, dev->dev_addr[1] | dev->dev_addr[0] << 8, 0xFFFFFFFF, 0x0000FFFF); s6gmac_set_dstaddr(pd, 2, 0x00000000, 0x00000100, 0x00000000, 0x00000100); s6gmac_set_dstaddr(pd, 3, 0x00000000, 0x00000000, 0x00000000, 0x00000000); writel(1 << S6_GMAC_HOST_PBLKCTRL_TXENA | 1 << S6_GMAC_HOST_PBLKCTRL_RXENA | S6_GMAC_HOST_PBLKCTRL_SIZ_128 << S6_GMAC_HOST_PBLKCTRL_TXBSIZ | S6_GMAC_HOST_PBLKCTRL_SIZ_128 << S6_GMAC_HOST_PBLKCTRL_RXBSIZ | 1 << S6_GMAC_HOST_PBLKCTRL_STATENA | 1 << S6_GMAC_HOST_PBLKCTRL_STATCLEAR | is_rgmii << S6_GMAC_HOST_PBLKCTRL_RGMII, pd->reg + S6_GMAC_HOST_PBLKCTRL); } static void s6mii_enable(struct s6gmac *pd) { writel(readl(pd->reg + S6_GMAC_MACCONF1) & ~(1 << S6_GMAC_MACCONF1_SOFTRES), pd->reg + S6_GMAC_MACCONF1); writel((readl(pd->reg + S6_GMAC_MACMIICONF) & ~(S6_GMAC_MACMIICONF_CSEL_MASK << S6_GMAC_MACMIICONF_CSEL)) | (S6_GMAC_MACMIICONF_CSEL_DIV168 << S6_GMAC_MACMIICONF_CSEL), pd->reg + S6_GMAC_MACMIICONF); } static int s6mii_busy(struct s6gmac *pd, int tmo) { while (readl(pd->reg + S6_GMAC_MACMIIINDI)) { if (--tmo == 0) return -ETIME; udelay(64); } return 0; } static int s6mii_read(struct mii_bus *bus, int phy_addr, int regnum) { struct s6gmac *pd = bus->priv; s6mii_enable(pd); if (s6mii_busy(pd, 256)) return -ETIME; writel(phy_addr << S6_GMAC_MACMIIADDR_PHY | regnum << S6_GMAC_MACMIIADDR_REG, pd->reg + S6_GMAC_MACMIIADDR); writel(1 << S6_GMAC_MACMIICMD_READ, pd->reg + S6_GMAC_MACMIICMD); writel(0, pd->reg + S6_GMAC_MACMIICMD); if (s6mii_busy(pd, 256)) return -ETIME; return (u16)readl(pd->reg + S6_GMAC_MACMIISTAT); } static int s6mii_write(struct mii_bus *bus, int phy_addr, int regnum, u16 value) { struct s6gmac *pd = bus->priv; s6mii_enable(pd); if (s6mii_busy(pd, 256)) return -ETIME; writel(phy_addr << S6_GMAC_MACMIIADDR_PHY | regnum << S6_GMAC_MACMIIADDR_REG, pd->reg + S6_GMAC_MACMIIADDR); writel(value, pd->reg + S6_GMAC_MACMIICTRL); if (s6mii_busy(pd, 256)) return -ETIME; return 0; } static int s6mii_reset(struct mii_bus *bus) { struct s6gmac *pd = bus->priv; s6mii_enable(pd); if (s6mii_busy(pd, PHY_INIT_TIMEOUT)) return -ETIME; return 0; } static void s6gmac_set_rgmii_txclock(struct s6gmac *pd) { u32 pllsel = readl(S6_REG_GREG1 + S6_GREG1_PLLSEL); pllsel &= ~(S6_GREG1_PLLSEL_GMAC_MASK << S6_GREG1_PLLSEL_GMAC); switch (pd->link.mbit) { case 10: pllsel |= S6_GREG1_PLLSEL_GMAC_2500KHZ << S6_GREG1_PLLSEL_GMAC; break; case 100: pllsel |= S6_GREG1_PLLSEL_GMAC_25MHZ << S6_GREG1_PLLSEL_GMAC; break; case 1000: pllsel |= S6_GREG1_PLLSEL_GMAC_125MHZ << S6_GREG1_PLLSEL_GMAC; break; default: return; } writel(pllsel, S6_REG_GREG1 + S6_GREG1_PLLSEL); } static inline void s6gmac_linkisup(struct net_device *dev, int isup) { struct s6gmac *pd = netdev_priv(dev); struct phy_device *phydev = pd->phydev; pd->link.full = phydev->duplex; pd->link.giga = (phydev->speed == 1000); if (pd->link.mbit != phydev->speed) { pd->link.mbit = phydev->speed; s6gmac_set_rgmii_txclock(pd); } pd->link.isup = isup; if (isup) netif_carrier_on(dev); phy_print_status(phydev); } static void s6gmac_adjust_link(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); struct phy_device *phydev = pd->phydev; if (pd->link.isup && (!phydev->link || (pd->link.mbit != phydev->speed) || (pd->link.full != phydev->duplex))) { pd->link.isup = 0; netif_tx_disable(dev); if (!phydev->link) { netif_carrier_off(dev); phy_print_status(phydev); } } if (!pd->link.isup && phydev->link) { if (pd->link.full != phydev->duplex) { u32 maccfg = readl(pd->reg + S6_GMAC_MACCONF2); if (phydev->duplex) maccfg |= 1 << S6_GMAC_MACCONF2_FULL; else maccfg &= ~(1 << S6_GMAC_MACCONF2_FULL); writel(maccfg, pd->reg + S6_GMAC_MACCONF2); } if (pd->link.giga != (phydev->speed == 1000)) { u32 fifocfg = readl(pd->reg + S6_GMAC_FIFOCONF5); u32 maccfg = readl(pd->reg + S6_GMAC_MACCONF2); maccfg &= ~(S6_GMAC_MACCONF2_IFMODE_MASK << S6_GMAC_MACCONF2_IFMODE); if (phydev->speed == 1000) { fifocfg |= 1 << S6_GMAC_FIFOCONF5_CFGBYTM; maccfg |= S6_GMAC_MACCONF2_IFMODE_BYTE << S6_GMAC_MACCONF2_IFMODE; } else { fifocfg &= ~(1 << S6_GMAC_FIFOCONF5_CFGBYTM); maccfg |= S6_GMAC_MACCONF2_IFMODE_NIBBLE << S6_GMAC_MACCONF2_IFMODE; } writel(fifocfg, pd->reg + S6_GMAC_FIFOCONF5); writel(maccfg, pd->reg + S6_GMAC_MACCONF2); } if (!s6dmac_fifo_full(pd->tx_dma, pd->tx_chan)) netif_wake_queue(dev); s6gmac_linkisup(dev, 1); } } static inline int s6gmac_phy_start(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); int i = 0; struct phy_device *p = NULL; while ((i < PHY_MAX_ADDR) && (!(p = pd->mii.bus->phy_map[i]))) i++; p = phy_connect(dev, dev_name(&p->dev), &s6gmac_adjust_link, 0, PHY_INTERFACE_MODE_RGMII); if (IS_ERR(p)) { printk(KERN_ERR "%s: Could not attach to PHY\n", dev->name); return PTR_ERR(p); } p->supported &= PHY_GBIT_FEATURES; p->advertising = p->supported; pd->phydev = p; return 0; } static inline void s6gmac_init_stats(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); u32 mask; mask = 1 << S6_GMAC_STATCARRY1_RDRP | 1 << S6_GMAC_STATCARRY1_RJBR | 1 << S6_GMAC_STATCARRY1_RFRG | 1 << S6_GMAC_STATCARRY1_ROVR | 1 << S6_GMAC_STATCARRY1_RUND | 1 << S6_GMAC_STATCARRY1_RCDE | 1 << S6_GMAC_STATCARRY1_RFLR | 1 << S6_GMAC_STATCARRY1_RALN | 1 << S6_GMAC_STATCARRY1_RMCA | 1 << S6_GMAC_STATCARRY1_RFCS | 1 << S6_GMAC_STATCARRY1_RPKT | 1 << S6_GMAC_STATCARRY1_RBYT; writel(mask, pd->reg + S6_GMAC_STATCARRY(0)); writel(~mask, pd->reg + S6_GMAC_STATCARRYMSK(0)); mask = 1 << S6_GMAC_STATCARRY2_TDRP | 1 << S6_GMAC_STATCARRY2_TNCL | 1 << S6_GMAC_STATCARRY2_TXCL | 1 << S6_GMAC_STATCARRY2_TEDF | 1 << S6_GMAC_STATCARRY2_TPKT | 1 << S6_GMAC_STATCARRY2_TBYT | 1 << S6_GMAC_STATCARRY2_TFRG | 1 << S6_GMAC_STATCARRY2_TUND | 1 << S6_GMAC_STATCARRY2_TOVR | 1 << S6_GMAC_STATCARRY2_TFCS | 1 << S6_GMAC_STATCARRY2_TJBR; writel(mask, pd->reg + S6_GMAC_STATCARRY(1)); writel(~mask, pd->reg + S6_GMAC_STATCARRYMSK(1)); } static inline void s6gmac_init_dmac(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); s6dmac_disable_chan(pd->tx_dma, pd->tx_chan); s6dmac_disable_chan(pd->rx_dma, pd->rx_chan); s6dmac_disable_error_irqs(pd->tx_dma, 1 << S6_HIFDMA_GMACTX); s6dmac_disable_error_irqs(pd->rx_dma, 1 << S6_HIFDMA_GMACRX); } static int s6gmac_tx(struct sk_buff *skb, struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); unsigned long flags; spin_lock_irqsave(&pd->lock, flags); writel(skb->len << S6_GMAC_BURST_PREWR_LEN | 0 << S6_GMAC_BURST_PREWR_CFE | 1 << S6_GMAC_BURST_PREWR_PPE | 1 << S6_GMAC_BURST_PREWR_FCS | ((skb->len < ETH_ZLEN) ? 1 : 0) << S6_GMAC_BURST_PREWR_PAD, pd->reg + S6_GMAC_BURST_PREWR); s6dmac_put_fifo_cache(pd->tx_dma, pd->tx_chan, (u32)skb->data, pd->io, skb->len); if (s6dmac_fifo_full(pd->tx_dma, pd->tx_chan)) netif_stop_queue(dev); if (((u8)(pd->tx_skb_i - pd->tx_skb_o)) >= S6_NUM_TX_SKB) { printk(KERN_ERR "GMAC BUG: skb tx ring overflow [%x, %x]\n", pd->tx_skb_o, pd->tx_skb_i); BUG(); } pd->tx_skb[(pd->tx_skb_i++) % S6_NUM_TX_SKB] = skb; spin_unlock_irqrestore(&pd->lock, flags); return 0; } static void s6gmac_tx_timeout(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); unsigned long flags; spin_lock_irqsave(&pd->lock, flags); s6gmac_tx_interrupt(dev); spin_unlock_irqrestore(&pd->lock, flags); } static int s6gmac_open(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); unsigned long flags; phy_read_status(pd->phydev); spin_lock_irqsave(&pd->lock, flags); pd->link.mbit = 0; s6gmac_linkisup(dev, pd->phydev->link); s6gmac_init_device(dev); s6gmac_init_stats(dev); s6gmac_init_dmac(dev); s6gmac_rx_fillfifo(pd); s6dmac_enable_chan(pd->rx_dma, pd->rx_chan, 2, 1, 0, 1, 0, 0, 0, 7, -1, 2, 0, 1); s6dmac_enable_chan(pd->tx_dma, pd->tx_chan, 2, 0, 1, 0, 0, 0, 0, 7, -1, 2, 0, 1); writel(0 << S6_GMAC_HOST_INT_TXBURSTOVER | 0 << S6_GMAC_HOST_INT_TXPREWOVER | 0 << S6_GMAC_HOST_INT_RXBURSTUNDER | 0 << S6_GMAC_HOST_INT_RXPOSTRFULL | 0 << S6_GMAC_HOST_INT_RXPOSTRUNDER, pd->reg + S6_GMAC_HOST_INTMASK); spin_unlock_irqrestore(&pd->lock, flags); phy_start(pd->phydev); netif_start_queue(dev); return 0; } static int s6gmac_stop(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); unsigned long flags; netif_stop_queue(dev); phy_stop(pd->phydev); spin_lock_irqsave(&pd->lock, flags); s6gmac_init_dmac(dev); s6gmac_stop_device(dev); while (pd->tx_skb_i != pd->tx_skb_o) dev_kfree_skb(pd->tx_skb[(pd->tx_skb_o++) % S6_NUM_TX_SKB]); while (pd->rx_skb_i != pd->rx_skb_o) dev_kfree_skb(pd->rx_skb[(pd->rx_skb_o++) % S6_NUM_RX_SKB]); spin_unlock_irqrestore(&pd->lock, flags); return 0; } static struct net_device_stats *s6gmac_stats(struct net_device *dev) { struct s6gmac *pd = netdev_priv(dev); struct net_device_stats *st = (struct net_device_stats *)&pd->stats; int i; do { unsigned long flags; spin_lock_irqsave(&pd->lock, flags); for (i = 0; i < sizeof(pd->stats) / sizeof(unsigned long); i++) pd->stats[i] = pd->carry[i] << (S6_GMAC_STAT_SIZE_MIN - 1); s6gmac_stats_collect(pd, &statinf[0][0]); s6gmac_stats_collect(pd, &statinf[1][0]); i = s6gmac_stats_pending(pd, 0) | s6gmac_stats_pending(pd, 1); spin_unlock_irqrestore(&pd->lock, flags); } while (i); st->rx_errors = st->rx_crc_errors + st->rx_frame_errors + st->rx_length_errors + st->rx_missed_errors; st->tx_errors += st->tx_aborted_errors; return st; } static int __devinit s6gmac_probe(struct platform_device *pdev) { struct net_device *dev; struct s6gmac *pd; int res; unsigned long i; struct mii_bus *mb; dev = alloc_etherdev(sizeof(*pd)); if (!dev) { printk(KERN_ERR DRV_PRMT "etherdev alloc failed, aborting.\n"); return -ENOMEM; } dev->open = s6gmac_open; dev->stop = s6gmac_stop; dev->hard_start_xmit = s6gmac_tx; dev->tx_timeout = s6gmac_tx_timeout; dev->watchdog_timeo = HZ; dev->get_stats = s6gmac_stats; dev->irq = platform_get_irq(pdev, 0); pd = netdev_priv(dev); memset(pd, 0, sizeof(*pd)); spin_lock_init(&pd->lock); pd->reg = platform_get_resource(pdev, IORESOURCE_MEM, 0)->start; i = platform_get_resource(pdev, IORESOURCE_DMA, 0)->start; pd->tx_dma = DMA_MASK_DMAC(i); pd->tx_chan = DMA_INDEX_CHNL(i); i = platform_get_resource(pdev, IORESOURCE_DMA, 1)->start; pd->rx_dma = DMA_MASK_DMAC(i); pd->rx_chan = DMA_INDEX_CHNL(i); pd->io = platform_get_resource(pdev, IORESOURCE_IO, 0)->start; res = request_irq(dev->irq, s6gmac_interrupt, 0, dev->name, dev); if (res) { printk(KERN_ERR DRV_PRMT "irq request failed: %d\n", dev->irq); goto errirq; } res = register_netdev(dev); if (res) { printk(KERN_ERR DRV_PRMT "error registering device %s\n", dev->name); goto errdev; } mb = mdiobus_alloc(); if (!mb) { printk(KERN_ERR DRV_PRMT "error allocating mii bus\n"); goto errmii; } mb->name = "s6gmac_mii"; mb->read = s6mii_read; mb->write = s6mii_write; mb->reset = s6mii_reset; mb->priv = pd; snprintf(mb->id, MII_BUS_ID_SIZE, "0"); mb->phy_mask = ~(1 << 0); mb->irq = &pd->mii.irq[0]; for (i = 0; i < PHY_MAX_ADDR; i++) { int n = platform_get_irq(pdev, i + 1); if (n < 0) n = PHY_POLL; pd->mii.irq[i] = n; } mdiobus_register(mb); pd->mii.bus = mb; res = s6gmac_phy_start(dev); if (res) return res; platform_set_drvdata(pdev, dev); return 0; errmii: unregister_netdev(dev); errdev: free_irq(dev->irq, dev); errirq: free_netdev(dev); return res; } static int __devexit s6gmac_remove(struct platform_device *pdev) { struct net_device *dev = platform_get_drvdata(pdev); if (dev) { struct s6gmac *pd = netdev_priv(dev); mdiobus_unregister(pd->mii.bus); unregister_netdev(dev); free_irq(dev->irq, dev); free_netdev(dev); platform_set_drvdata(pdev, NULL); } return 0; } static struct platform_driver s6gmac_driver = { .probe = s6gmac_probe, .remove = __devexit_p(s6gmac_remove), .driver = { .name = "s6gmac", .owner = THIS_MODULE, }, }; static int __init s6gmac_init(void) { printk(KERN_INFO DRV_PRMT "S6 GMAC ethernet driver\n"); return platform_driver_register(&s6gmac_driver); } static void __exit s6gmac_exit(void) { platform_driver_unregister(&s6gmac_driver); } module_init(s6gmac_init); module_exit(s6gmac_exit); MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("S6105 on chip Ethernet driver"); MODULE_AUTHOR("Oskar Schirmer <os@emlix.com>");