/* D-Link DL2000-based Gigabit Ethernet Adapter Linux driver */ /* Copyright (c) 2001, 2002 by D-Link Corporation Written by Edward Peng. Created 03-May-2001, base on Linux' sundance.c. 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. */ #ifndef __DL2K_H__ #define __DL2K_H__ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Processor type for cache alignment. */ #include #include #include #include #include #include #ifdef DL2K_COMPAT_WITH_OLD_KERNEL #include "crc32.h" #else #include #endif #define TX_RING_SIZE 256 #define TX_QUEUE_LEN (TX_RING_SIZE - 10) /* Limit ring entries actually used.*/ #define RX_RING_SIZE 256 #define TX_TOTAL_SIZE TX_RING_SIZE*sizeof(struct netdev_desc) #define RX_TOTAL_SIZE RX_RING_SIZE*sizeof(struct netdev_desc) /* This driver was written to use PCI memory space, however x86-oriented hardware often uses I/O space accesses. */ #ifndef MEM_MAPPING #undef readb #undef readw #undef readl #undef writeb #undef writew #undef writel #define readb inb #define readw inw #define readl inl #define writeb outb #define writew outw #define writel outl #endif /* Offsets to the device registers. Unlike software-only systems, device drivers interact with complex hardware. It's not useful to define symbolic names for every register bit in the device. The name can only partially document the semantics and make the driver longer and more difficult to read. In general, only the important configuration values or bits changed multiple times should be defined symbolically. */ enum dl2x_offsets { /* I/O register offsets */ DMACtrl = 0x00, RxDMAStatus = 0x08, TFDListPtr0 = 0x10, TFDListPtr1 = 0x14, TxDMABurstThresh = 0x18, TxDMAUrgentThresh = 0x19, TxDMAPollPeriod = 0x1a, RFDListPtr0 = 0x1c, RFDListPtr1 = 0x20, RxDMABurstThresh = 0x24, RxDMAUrgentThresh = 0x25, RxDMAPollPeriod = 0x26, RxDMAIntCtrl = 0x28, DebugCtrl = 0x2c, ASICCtrl = 0x30, FifoCtrl = 0x38, RxEarlyThresh = 0x3a, FlowOffThresh = 0x3c, FlowOnThresh = 0x3e, TxStartThresh = 0x44, EepromData = 0x48, EepromCtrl = 0x4a, ExpromAddr = 0x4c, Exprodata = 0x50, WakeEvent0x51, CountDown = 0x54, IntStatusAck = 0x5a, IntEnable = 0x5c, IntStatus = 0x5e, TxStatus = 0x60, MACCtrl = 0x6c, VLANTag = 0x70, PhyCtrl = 0x76, StationAddr0 = 0x78, StationAddr1 = 0x7a, StationAddr2 = 0x7c, VLANId = 0x80, MaxFrameSize = 0x86, ReceiveMode = 0x88, HashTable0 = 0x8c, HashTable1 = 0x90, RmonStatMask = 0x98, StatMask = 0x9c, RxJumboFrames = 0xbc, TCPCheckSumErrors = 0xc0, IPCheckSumErrors = 0xc2, UDPCheckSumErrors = 0xc4, TxJumboFrames = 0xf4, /* Ethernet MIB statistic register offsets */ OctetRcvOk = 0xa8, McstOctetRcvOk = 0xac, BcstOctetRcvOk = 0xb0, FramesRcvOk = 0xb4, McstFramesRcvdOk = 0xb8, BcstFramesRcvdOk = 0xbe, MacControlFramesRcvd = 0xc6, FrameTooLongErrors = 0xc8, InRangeLengthErrors = 0xca, FramesCheckSeqErrors = 0xcc, FramesLostRxErrors = 0xce, OctetXmtOk = 0xd0, McstOctetXmtOk = 0xd4, BcstOctetXmtOk = 0xd8, FramesXmtOk = 0xdc, McstFramesXmtdOk = 0xe0, FramesWDeferredXmt = 0xe4, LateCollisions = 0xe8, MultiColFrames = 0xec, SingleColFrames = 0xf0, BcstFramesXmtdOk = 0xf6, CarrierSenseErrors = 0xf8, MacControlFramesXmtd = 0xfa, FramesAbortXSColls = 0xfc, FramesWEXDeferal = 0xfe, /* RMON statistic register offsets */ EtherStatsCollisions = 0x100, EtherStatsOctetsTransmit = 0x104, EtherStatsPktsTransmit = 0x108, EtherStatsPkts64OctetTransmit = 0x10c, EtherStats65to127OctetsTransmit = 0x110, EtherStatsPkts128to255OctetsTransmit = 0x114, EtherStatsPkts256to511OctetsTransmit = 0x118, EtherStatsPkts512to1023OctetsTransmit = 0x11c, EtherStatsPkts1024to1518OctetsTransmit = 0x120, EtherStatsCRCAlignErrors = 0x124, EtherStatsUndersizePkts = 0x128, EtherStatsFragments = 0x12c, EtherStatsJabbers = 0x130, EtherStatsOctets = 0x134, EtherStatsPkts = 0x138, EtherStats64Octets = 0x13c, EtherStatsPkts65to127Octets = 0x140, EtherStatsPkts128to255Octets = 0x144, EtherStatsPkts256to511Octets = 0x148, EtherStatsPkts512to1023Octets = 0x14c, EtherStatsPkts1024to1518Octets = 0x150, }; /* Bits in the interrupt status/mask registers. */ enum IntStatus_bits { InterruptStatus = 0x0001, HostError = 0x0002, MACCtrlFrame = 0x0008, TxComplete = 0x0004, RxComplete = 0x0010, RxEarly = 0x0020, IntRequested = 0x0040, UpdateStats = 0x0080, LinkEvent = 0x0100, TxDMAComplete = 0x0200, RxDMAComplete = 0x0400, RFDListEnd = 0x0800, RxDMAPriority = 0x1000, }; /* Bits in the ReceiveMode register. */ enum ReceiveMode_bits { ReceiveUnicast = 0x0001, ReceiveMulticast = 0x0002, ReceiveBroadcast = 0x0004, ReceiveAllFrames = 0x0008, ReceiveMulticastHash = 0x0010, ReceiveIPMulticast = 0x0020, ReceiveVLANMatch = 0x0100, ReceiveVLANHash = 0x0200, }; /* Bits in MACCtrl. */ enum MACCtrl_bits { DuplexSelect = 0x20, TxFlowControlEnable = 0x80, RxFlowControlEnable = 0x0100, RcvFCS = 0x200, AutoVLANtagging = 0x1000, AutoVLANuntagging = 0x2000, StatsEnable = 0x00200000, StatsDisable = 0x00400000, StatsEnabled = 0x00800000, TxEnable = 0x01000000, TxDisable = 0x02000000, TxEnabled = 0x04000000, RxEnable = 0x08000000, RxDisable = 0x10000000, RxEnabled = 0x20000000, }; enum ASICCtrl_LoWord_bits { PhyMedia = 0x0080, }; enum ASICCtrl_HiWord_bits { GlobalReset = 0x0001, RxReset = 0x0002, TxReset = 0x0004, DMAReset = 0x0008, FIFOReset = 0x0010, NetworkReset = 0x0020, HostReset = 0x0040, ResetBusy = 0x0400, }; /* Transmit Frame Control bits */ enum TFC_bits { DwordAlign = 0x00000000, WordAlignDisable = 0x00030000, WordAlign = 0x00020000, TCPChecksumEnable = 0x00040000, UDPChecksumEnable = 0x00080000, IPChecksumEnable = 0x00100000, FCSAppendDisable = 0x00200000, TxIndicate = 0x00400000, TxDMAIndicate = 0x00800000, FragCountShift = 24, VLANTagInsert = 0x0000000010000000, TFDDone = 0x80000000, VIDShift = 32, UsePriorityShift = 48, }; /* Receive Frames Status bits */ enum RFS_bits { RxFIFOOverrun = 0x00010000, RxRuntFrame = 0x00020000, RxAlignmentError = 0x00040000, RxFCSError = 0x00080000, RxOverSizedFrame = 0x00100000, RxLengthError = 0x00200000, VLANDetected = 0x00400000, TCPDetected = 0x00800000, TCPError = 0x01000000, UDPDetected = 0x02000000, UDPError = 0x04000000, IPDetected = 0x08000000, IPError = 0x10000000, FrameStart = 0x20000000, FrameEnd = 0x40000000, RFDDone = 0x80000000, TCIShift = 32, RFS_Errors = 0x003f0000, }; #define MII_RESET_TIME_OUT 10000 /* MII register */ enum _mii_reg { MII_BMCR = 0, MII_BMSR = 1, MII_PHY_ID1 = 2, MII_PHY_ID2 = 3, MII_ANAR = 4, MII_ANLPAR = 5, MII_ANER = 6, MII_ANNPT = 7, MII_ANLPRNP = 8, MII_MSCR = 9, MII_MSSR = 10, MII_ESR = 15, MII_PHY_SCR = 16, }; /* PCS register */ enum _pcs_reg { PCS_BMCR = 0, PCS_BMSR = 1, PCS_ANAR = 4, PCS_ANLPAR = 5, PCS_ANER = 6, PCS_ANNPT = 7, PCS_ANLPRNP = 8, PCS_ESR = 15, }; /* Basic Mode Control Register */ typedef union t_MII_BMCR { u16 image; struct { u16 _bit_5_0:6; // bit 5:0 u16 speed1000:1; // bit 6 u16 col_test_enable:1; // bit 7 u16 duplex_mode:1; // bit 8 u16 restart_an:1; // bit 9 u16 isolate:1; // bit 10 u16 power_down:1; // bit 11 u16 an_enable:1; // bit 12 u16 speed100:1; // bit 13 u16 loopback:1; // bit 14 u16 reset:1; // bit 15 } bits; } BMCR_t, *PBMCR_t; enum _mii_bmcr { MII_BMCR_RESET = 0x8000, MII_BMCR_LOOP_BACK = 0x4000, MII_BMCR_SPEED_LSB = 0x2000, MII_BMCR_AN_ENABLE = 0x1000, MII_BMCR_POWER_DOWN = 0x0800, MII_BMCR_ISOLATE = 0x0400, MII_BMCR_RESTART_AN = 0x0200, MII_BMCR_DUPLEX_MODE = 0x0100, MII_BMCR_COL_TEST = 0x0080, MII_BMCR_SPEED_MSB = 0x0040, MII_BMCR_SPEED_RESERVED = 0x003f, MII_BMCR_SPEED_10 = 0, MII_BMCR_SPEED_100 = MII_BMCR_SPEED_LSB, MII_BMCR_SPEED_1000 = MII_BMCR_SPEED_MSB, }; /* Basic Mode Status Register */ typedef union t_MII_BMSR { u16 image; struct { u16 ext_capability:1; // bit 0 u16 japper_detect:1; // bit 1 u16 link_status:1; // bit 2 u16 an_ability:1; // bit 3 u16 remote_fault:1; // bit 4 u16 an_complete:1; // bit 5 u16 preamble_supp:1; // bit 6 u16 _bit_7:1; // bit 7 u16 ext_status:1; // bit 8 u16 media_100BT2_HD:1; // bit 9 u16 media_100BT2_FD:1; // bit 10 u16 media_10BT_HD:1; // bit 11 u16 media_10BT_FD:1; // bit 12 u16 media_100BX_HD:1; // bit 13 u16 media_100BX_FD:1; // bit 14 u16 media_100BT4:1; // bit 15 } bits; } BMSR_t, *PBMSR_t; enum _mii_bmsr { MII_BMSR_100BT4 = 0x8000, MII_BMSR_100BX_FD = 0x4000, MII_BMSR_100BX_HD = 0x2000, MII_BMSR_10BT_FD = 0x1000, MII_BMSR_10BT_HD = 0x0800, MII_BMSR_100BT2_FD = 0x0400, MII_BMSR_100BT2_HD = 0x0200, MII_BMSR_EXT_STATUS = 0x0100, MII_BMSR_PREAMBLE_SUPP = 0x0040, MII_BMSR_AN_COMPLETE = 0x0020, MII_BMSR_REMOTE_FAULT = 0x0010, MII_BMSR_AN_ABILITY = 0x0008, MII_BMSR_LINK_STATUS = 0x0004, MII_BMSR_JABBER_DETECT = 0x0002, MII_BMSR_EXT_CAP = 0x0001, }; /* ANAR */ typedef union t_MII_ANAR { u16 image; struct { u16 selector:5; // bit 4:0 u16 media_10BT_HD:1; // bit 5 u16 media_10BT_FD:1; // bit 6 u16 media_100BX_HD:1; // bit 7 u16 media_100BX_FD:1; // bit 8 u16 media_100BT4:1; // bit 9 u16 pause:1; // bit 10 u16 asymmetric:1; // bit 11 u16 _bit12:1; // bit 12 u16 remote_fault:1; // bit 13 u16 _bit14:1; // bit 14 u16 next_page:1; // bit 15 } bits; } ANAR_t, *PANAR_t; enum _mii_anar { MII_ANAR_NEXT_PAGE = 0x8000, MII_ANAR_REMOTE_FAULT = 0x4000, MII_ANAR_ASYMMETRIC = 0x0800, MII_ANAR_PAUSE = 0x0400, MII_ANAR_100BT4 = 0x0200, MII_ANAR_100BX_FD = 0x0100, MII_ANAR_100BX_HD = 0x0080, MII_ANAR_10BT_FD = 0x0020, MII_ANAR_10BT_HD = 0x0010, MII_ANAR_SELECTOR = 0x001f, MII_IEEE8023_CSMACD = 0x0001, }; /* ANLPAR */ typedef union t_MII_ANLPAR { u16 image; struct { u16 selector:5; // bit 4:0 u16 media_10BT_HD:1; // bit 5 u16 media_10BT_FD:1; // bit 6 u16 media_100BX_HD:1; // bit 7 u16 media_100BX_FD:1; // bit 8 u16 media_100BT4:1; // bit 9 u16 pause:1; // bit 10 u16 asymmetric:1; // bit 11 u16 _bit12:1; // bit 12 u16 remote_fault:1; // bit 13 u16 _bit14:1; // bit 14 u16 next_page:1; // bit 15 } bits; } ANLPAR_t, *PANLPAR_t; enum _mii_anlpar { MII_ANLPAR_NEXT_PAGE = MII_ANAR_NEXT_PAGE, MII_ANLPAR_REMOTE_FAULT = MII_ANAR_REMOTE_FAULT, MII_ANLPAR_ASYMMETRIC = MII_ANAR_ASYMMETRIC, MII_ANLPAR_PAUSE = MII_ANAR_PAUSE, MII_ANLPAR_100BT4 = MII_ANAR_100BT4, MII_ANLPAR_100BX_FD = MII_ANAR_100BX_FD, MII_ANLPAR_100BX_HD = MII_ANAR_100BX_HD, MII_ANLPAR_10BT_FD = MII_ANAR_10BT_FD, MII_ANLPAR_10BT_HD = MII_ANAR_10BT_HD, MII_ANLPAR_SELECTOR = MII_ANAR_SELECTOR, }; /* Auto-Negotiation Expansion Register */ typedef union t_MII_ANER { u16 image; struct { u16 lp_negotiable:1; // bit 0 u16 page_received:1; // bit 1 u16 nextpagable:1; // bit 2 u16 lp_nextpagable:1; // bit 3 u16 pdetect_fault:1; // bit 4 u16 _bit15_5:11; // bit 15:5 } bits; } ANER_t, *PANER_t; enum _mii_aner { MII_ANER_PAR_DETECT_FAULT = 0x0010, MII_ANER_LP_NEXTPAGABLE = 0x0008, MII_ANER_NETXTPAGABLE = 0x0004, MII_ANER_PAGE_RECEIVED = 0x0002, MII_ANER_LP_NEGOTIABLE = 0x0001, }; /* MASTER-SLAVE Control Register */ typedef union t_MII_MSCR { u16 image; struct { u16 _bit_7_0:8; // bit 7:0 u16 media_1000BT_HD:1; // bit 8 u16 media_1000BT_FD:1; // bit 9 u16 port_type:1; // bit 10 u16 cfg_value:1; // bit 11 u16 cfg_enable:1; // bit 12 u16 test_mode:3; // bit 15:13 } bits; } MSCR_t, *PMSCR_t; enum _mii_mscr { MII_MSCR_TEST_MODE = 0xe000, MII_MSCR_CFG_ENABLE = 0x1000, MII_MSCR_CFG_VALUE = 0x0800, MII_MSCR_PORT_VALUE = 0x0400, MII_MSCR_1000BT_FD = 0x0200, MII_MSCR_1000BT_HD = 0X0100, }; /* MASTER-SLAVE Status Register */ typedef union t_MII_MSSR { u16 image; struct { u16 idle_err_count:8; // bit 7:0 u16 _bit_9_8:2; // bit 9:8 u16 lp_1000BT_HD:1; // bit 10 u16 lp_1000BT_FD:1; // bit 11 u16 remote_rcv_status:1; // bit 12 u16 local_rcv_status:1; // bit 13 u16 cfg_resolution:1; // bit 14 u16 cfg_fault:1; // bit 15 } bits; } MSSR_t, *PMSSR_t; enum _mii_mssr { MII_MSSR_CFG_FAULT = 0x8000, MII_MSSR_CFG_RES = 0x4000, MII_MSSR_LOCAL_RCV_STATUS = 0x2000, MII_MSSR_REMOTE_RCVR = 0x1000, MII_MSSR_LP_1000BT_HD = 0x0800, MII_MSSR_LP_1000BT_FD = 0x0400, MII_MSSR_IDLE_ERR_COUNT = 0x00ff, }; /* IEEE Extened Status Register */ typedef union t_MII_ESR { u16 image; struct { u16 _bit_11_0:12; // bit 11:0 u16 media_1000BT_HD:1; // bit 12 u16 media_1000BT_FD:1; // bit 13 u16 media_1000BX_HD:1; // bit 14 u16 media_1000BX_FD:1; // bit 15 } bits; } ESR_t, *PESR_t; enum _mii_esr { MII_ESR_1000BX_FD = 0x8000, MII_ESR_1000BX_HD = 0x4000, MII_ESR_1000BT_FD = 0x2000, MII_ESR_1000BT_HD = 0x1000, }; /* PHY Specific Control Register */ typedef union t_MII_PHY_SCR { u16 image; struct { u16 disable_jabber:1; // bit 0 u16 polarity_reversal:1; // bit 1 u16 SEQ_test:1; // bit 2 u16 _bit_3:1; // bit 3 u16 disable_CLK125:1; // bit 4 u16 mdi_crossover_mode:2; // bit 6:5 u16 enable_ext_dist:1; // bit 7 u16 _bit_8_9:2; // bit 9:8 u16 force_link:1; // bit 10 u16 assert_CRS:1; // bit 11 u16 rcv_fifo_depth:2; // bit 13:12 u16 xmit_fifo_depth:2; // bit 15:14 } bits; } PHY_SCR_t, *PPHY_SCR_t; typedef enum t_MII_ADMIN_STATUS { adm_reset, adm_operational, adm_loopback, adm_power_down, adm_isolate } MII_ADMIN_t, *PMII_ADMIN_t; /* Physical Coding Sublayer Management (PCS) */ /* PCS control and status registers bitmap as the same as MII */ /* PCS Extended Status register bitmap as the same as MII */ /* PCS ANAR */ typedef union t_PCS_ANAR { u16 image; struct { u16 _bit_4_0:5; // bit 4:0 u16 full_duplex:1; // bit 5 u16 half_duplex:1; // bit 6 u16 asymmetric:1; // bit 7 u16 pause:1; // bit 8 u16 _bit_11_9:3; // bit 11:9 u16 remote_fault:2; // bit 13:12 u16 _bit_14:1; // bit 14 u16 next_page:1; // bit 15 } bits; } ANAR_PCS_t, *PANAR_PCS_t; enum _pcs_anar { PCS_ANAR_NEXT_PAGE = 0x8000, PCS_ANAR_REMOTE_FAULT = 0x3000, PCS_ANAR_ASYMMETRIC = 0x0100, PCS_ANAR_PAUSE = 0x0080, PCS_ANAR_HALF_DUPLEX = 0x0040, PCS_ANAR_FULL_DUPLEX = 0x0020, }; /* PCS ANLPAR */ typedef union t_PCS_ANLPAR { u16 image; struct { u16 _bit_4_0:5; // bit 4:0 u16 full_duplex:1; // bit 5 u16 half_duplex:1; // bit 6 u16 asymmetric:1; // bit 7 u16 pause:1; // bit 8 u16 _bit_11_9:3; // bit 11:9 u16 remote_fault:2; // bit 13:12 u16 _bit_14:1; // bit 14 u16 next_page:1; // bit 15 } bits; } ANLPAR_PCS_t, *PANLPAR_PCS_t; enum _pcs_anlpar { PCS_ANLPAR_NEXT_PAGE = PCS_ANAR_NEXT_PAGE, PCS_ANLPAR_REMOTE_FAULT = PCS_ANAR_REMOTE_FAULT, PCS_ANLPAR_ASYMMETRIC = PCS_ANAR_ASYMMETRIC, PCS_ANLPAR_PAUSE = PCS_ANAR_PAUSE, PCS_ANLPAR_HALF_DUPLEX = PCS_ANAR_HALF_DUPLEX, PCS_ANLPAR_FULL_DUPLEX = PCS_ANAR_FULL_DUPLEX, }; typedef struct t_SROM { u16 config_param; /* 0x00 */ u16 asic_ctrl; /* 0x02 */ u16 sub_vendor_id; /* 0x04 */ u16 sub_system_id; /* 0x06 */ u16 reserved1[12]; /* 0x08-0x1f */ u8 mac_addr[6]; /* 0x20-0x25 */ u8 reserved2[10]; /* 0x26-0x2f */ u8 sib[204]; /* 0x30-0xfb */ u32 crc; /* 0xfc-0xff */ } SROM_t, *PSROM_t; /* Ioctl custom data */ struct ioctl_data { char signature[10]; int cmd; int len; char *data; }; struct mii_data { __u16 reserved; __u16 reg_num; __u16 in_value; __u16 out_value; }; /* The Rx and Tx buffer descriptors. */ struct netdev_desc { u64 next_desc; u64 status; u64 fraginfo; }; #define PRIV_ALIGN 15 /* Required alignment mask */ /* Use __attribute__((aligned (L1_CACHE_BYTES))) to maintain alignment within the structure. */ struct netdev_private { /* Descriptor rings first for alignment. */ struct netdev_desc *rx_ring; struct netdev_desc *tx_ring; struct sk_buff *rx_skbuff[RX_RING_SIZE]; struct sk_buff *tx_skbuff[TX_RING_SIZE]; dma_addr_t tx_ring_dma; dma_addr_t rx_ring_dma; struct pci_dev *pdev; spinlock_t tx_lock; spinlock_t rx_lock; struct net_device_stats stats; unsigned int rx_buf_sz; /* Based on MTU+slack. */ unsigned int speed; /* Operating speed */ struct tasklet_struct tx_tasklet; struct tasklet_struct rx_tasklet; unsigned int vlan; /* VLAN Id */ unsigned int chip_id; /* PCI table chip id */ unsigned int rx_coalesce; /* Maximum frames each RxDMAComplete intr */ unsigned int rx_timeout; /* Wait time between RxDMAComplete intr */ unsigned int tx_coalesce; /* Maximum frames each tx interrupt */ unsigned int full_duplex:1; /* Full-duplex operation requested. */ unsigned int an_enable:2; /* Auto-Negotiated Enable */ unsigned int jumbo:1; /* Jumbo frame enable */ unsigned int coalesce:1; /* Rx coalescing enable */ unsigned int tx_flow:1; /* Tx flow control enable */ unsigned int rx_flow:1; /* Rx flow control enable */ unsigned int phy_media:1; /* 1: fiber, 0: copper */ unsigned int link_status:1; /* Current link status */ unsigned char pci_rev_id; /* PCI revision ID */ struct netdev_desc *last_tx; /* Last Tx descriptor used. */ unsigned long cur_rx, old_rx; /* Producer/consumer ring indices */ unsigned long cur_tx, old_tx; unsigned long cur_task; atomic_t tx_desc_lock; int budget; struct timer_list timer; int wake_polarity; char name[256]; /* net device description */ u8 duplex_polarity; u16 mcast_filter[4]; u16 advertising; /* NWay media advertisement */ u16 negotiate; /* Negotiated media */ int phy_addr; /* PHY addresses. */ }; /* The station address location in the EEPROM. */ #ifdef MEM_MAPPING #define PCI_IOTYPE (PCI_USES_MASTER | PCI_USES_MEM | PCI_ADDR1) #else #define PCI_IOTYPE (PCI_USES_MASTER | PCI_USES_IO | PCI_ADDR0) #endif /* The struct pci_device_id consist of: vendor, device Vendor and device ID to match (or PCI_ANY_ID) subvendor, subdevice Subsystem vendor and device ID to match (or PCI_ANY_ID) class Device class to match. The class_mask tells which bits class_mask of the class are honored during the comparison. driver_data Data private to the driver. */ static struct pci_device_id rio_pci_tbl[] __devinitdata = { {0x1186, 0x4000, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0}, {0,} }; MODULE_DEVICE_TABLE (pci, rio_pci_tbl); #define TX_TIMEOUT (4*HZ) #define PACKET_SIZE 1536 #define MAX_JUMBO 8000 #define RIO_IO_SIZE 340 #define DEFAULT_RXC 5 #define DEFAULT_RXT 750 #define DEFAULT_TXC 1 #define MAX_TXC 8 #define RX_BUDGET RX_RING_SIZE/2 #endif /* __DL2K_H__ */