/* tulip.c: A DEC 21040-family ethernet driver for Linux. */ /* Written 1994-1998 by Donald Becker. This software may be used and distributed according to the terms of the GNU Public License, incorporated herein by reference. This driver is for the Digital "Tulip" ethernet adapter interface. It should work with most DEC 21*4*-based chips/ethercards, as well as PNIC and MXIC chips. The author may be reached as becker@CESDIS.gsfc.nasa.gov, or C/O Center of Excellence in Space Data and Information Sciences Code 930.5, Goddard Space Flight Center, Greenbelt MD 20771 Support and updates available at http://cesdis.gsfc.nasa.gov/linux/drivers/tulip.html */ #define SMP_CHECK static const char version[] = "tulip.c:v0.89H 5/23/98 becker@cesdis.gsfc.nasa.gov\n"; /* A few user-configurable values. */ /* Maximum events (Rx packets, etc.) to handle at each interrupt. */ static int max_interrupt_work = 25; #define MAX_UNITS 8 /* Used to pass the full-duplex flag, etc. */ static int full_duplex[MAX_UNITS] = {0, }; static int options[MAX_UNITS] = {0, }; static int mtu[MAX_UNITS] = {0, }; /* Jumbo MTU for interfaces. */ /* The possible media types that can be set in options[] are: */ static const char * const medianame[] = { "10baseT", "10base2", "AUI", "100baseTx", "10baseT-FD", "100baseTx-FD", "100baseT4", "100baseFx", "100baseFx-FD", "MII 10baseT", "MII 10baseT-FD", "MII", "10baseT(forced)", "MII 100baseTx", "MII 100baseTx-FD", "MII 100baseT4", }; /* Set if the PCI BIOS detects the chips on a multiport board backwards. */ #ifdef REVERSE_PROBE_ORDER static int reverse_probe = 1; #else static int reverse_probe = 0; #endif /* Keep the ring sizes a power of two for efficiency. Making the Tx ring too large decreases the effectiveness of channel bonding and packet priority. There are no ill effects from too-large receive rings. */ #define TX_RING_SIZE 16 #define RX_RING_SIZE 32 /* Set the copy breakpoint for the copy-only-tiny-buffer Rx structure. */ #ifdef __alpha__ static int rx_copybreak = 1518; #else static int rx_copybreak = 100; #endif /* Operational parameters that usually are not changed. */ /* Time in jiffies before concluding the transmitter is hung. */ #define TX_TIMEOUT (4*HZ) #include #include #include #include #include #include #include #include #include #include #include #include /* Processor type for cache alignment. */ #include #include #include #include #include #include /* Kernel compatibility defines, common to David Hind's PCMCIA package. This is only in the support-all-kernels source code. */ #include /* Evil, but neccessary */ #if defined (LINUX_VERSION_CODE) && LINUX_VERSION_CODE < 0x10300 #define RUN_AT(x) (x) /* What to put in timer->expires. */ #define DEV_ALLOC_SKB(len) alloc_skb(len, GFP_ATOMIC) #define virt_to_bus(addr) ((unsigned long)addr) #define bus_to_virt(addr) ((void*)addr) #else /* 1.3.0 and later */ #define RUN_AT(x) (jiffies + (x)) #define DEV_ALLOC_SKB(len) dev_alloc_skb(len + 2) #endif #if (LINUX_VERSION_CODE >= 0x10344) #define NEW_MULTICAST #include #endif #ifdef SA_SHIRQ #define IRQ(irq, dev_id, pt_regs) (irq, dev_id, pt_regs) #else #define IRQ(irq, dev_id, pt_regs) (irq, pt_regs) #endif #if (LINUX_VERSION_CODE < 0x20123) #define hard_smp_processor_id() smp_processor_id() #define test_and_set_bit(val, addr) set_bit(val, addr) #endif /* This my implementation of shared IRQs, now only used for 1.2.13. */ #ifdef HAVE_SHARED_IRQ #define USE_SHARED_IRQ #include #endif /* The total size is unusually large: The 21040 aligns each of its 16 longword-wide registers on a quadword boundary. */ #define TULIP_TOTAL_SIZE 0x80 #ifdef HAVE_DEVLIST struct netdev_entry tulip_drv = {"Tulip", tulip_pci_probe, TULIP_TOTAL_SIZE, NULL}; #endif #ifdef TULIP_DEBUG int tulip_debug = TULIP_DEBUG; #else int tulip_debug = 1; #endif /* Theory of Operation I. Board Compatibility This device driver is designed for the DECchip "Tulip", Digital's single-chip ethernet controllers for PCI. Supported members of the family are the 21040, 21041, 21140, 21140A, 21142, and 21143. These chips are used on many PCI boards including the SMC EtherPower series. II. Board-specific settings PCI bus devices are configured by the system at boot time, so no jumpers need to be set on the board. The system BIOS preferably should assign the PCI INTA signal to an otherwise unused system IRQ line. Note: Kernel versions earlier than 1.3.73 do not support shared PCI interrupt lines. III. Driver operation IIIa. Ring buffers The Tulip can use either ring buffers or lists of Tx and Rx descriptors. This driver uses statically allocated rings of Rx and Tx descriptors, set at compile time by RX/TX_RING_SIZE. This version of the driver allocates skbuffs for the Rx ring buffers at open() time and passes the skb->data field to the Tulip as receive data buffers. When an incoming frame is less than RX_COPYBREAK bytes long, a fresh skbuff is allocated and the frame is copied to the new skbuff. When the incoming frame is larger, the skbuff is passed directly up the protocol stack and replaced by a newly allocated skbuff. The RX_COPYBREAK value is chosen to trade-off the memory wasted by using a full-sized skbuff for small frames vs. the copying costs of larger frames. For small frames the copying cost is negligible (esp. considering that we are pre-loading the cache with immediately useful header information). For large frames the copying cost is non-trivial, and the larger copy might flush the cache of useful data. A subtle aspect of this choice is that the Tulip only receives into longword aligned buffers, thus the IP header at offset 14 isn't longword aligned for further processing. Copied frames are put into the new skbuff at an offset of "+2", thus copying has the beneficial effect of aligning the IP header and preloading the cache. IIIC. Synchronization The driver runs as two independent, single-threaded flows of control. One is the send-packet routine, which enforces single-threaded use by the dev->tbusy flag. The other thread is the interrupt handler, which is single threaded by the hardware and other software. The send packet thread has partial control over the Tx ring and 'dev->tbusy' flag. It sets the tbusy flag whenever it's queuing a Tx packet. If the next queue slot is empty, it clears the tbusy flag when finished otherwise it sets the 'tp->tx_full' flag. The interrupt handler has exclusive control over the Rx ring and records stats from the Tx ring. (The Tx-done interrupt can't be selectively turned off, so we can't avoid the interrupt overhead by having the Tx routine reap the Tx stats.) After reaping the stats, it marks the queue entry as empty by setting the 'base' to zero. Iff the 'tp->tx_full' flag is set, it clears both the tx_full and tbusy flags. IV. Notes Thanks to Duke Kamstra of SMC for providing an EtherPower board. IVb. References http://cesdis.gsfc.nasa.gov/linux/misc/NWay.html http://www.digital.com (search for current 21*4* datasheets and "21X4 SROM") http://www.national.com/pf/DP/DP83840.html IVc. Errata The DEC databook doesn't document which Rx filter settings accept broadcast packets. Nor does it document how to configure the part to configure the serial subsystem for normal (vs. loopback) operation or how to have it autoswitch between internal 10baseT, SIA and AUI transceivers. The 21040 databook claims that CSR13, CSR14, and CSR15 should each be the last register of the set CSR12-15 written. Hmmm, now how is that possible? */ /* A few values that may be tweaked. */ #define PKT_BUF_SZ 1536 /* Size of each temporary Rx buffer.*/ /* This is a mysterious value that can be written to CSR11 in the 21040 (only) to support a pre-NWay full-duplex signaling mechanism using short frames. No one knows what it should be, but if left at its default value some 10base2(!) packets trigger a full-duplex-request interrupt. */ #define FULL_DUPLEX_MAGIC 0x6969 #ifndef PCI_VENDOR_ID_DEC /* Now defined in linux/pci.h */ #define PCI_VENDOR_ID_DEC 0x1011 #define PCI_DEVICE_ID_TULIP 0x0002 /* 21040. */ #define PCI_DEVICE_ID_TULIP_FAST 0x0009 /* 21140. */ #endif #ifndef PCI_DEVICE_ID_DEC_TULIP_PLUS #define PCI_DEVICE_ID_DEC_TULIP_PLUS 0x0014 /* 21041. */ #endif #ifndef PCI_DEVICE_ID_DEC_TULIP_21142 #define PCI_DEVICE_ID_DEC_TULIP_21142 0x0019 #endif #ifndef PCI_VENDOR_ID_LITEON #define PCI_VENDOR_ID_LITEON 0x11AD #endif #ifndef PCI_VENDOR_ID_MXIC #define PCI_VENDOR_ID_MXIC 0x10d9 #define PCI_DEVICE_ID_MX98713 0x0512 #define PCI_DEVICE_ID_MX98715 0x0531 #define PCI_DEVICE_ID_MX98725 0x0531 #endif /* The rest of these values should never change. */ static void tulip_timer(unsigned long data); static void t21142_timer(unsigned long data); static void mxic_timer(unsigned long data); static void pnic_timer(unsigned long data); /* A table describing the chip types. */ enum tbl_flag { HAS_MII=1, HAS_MEDIA_TABLE = 2, CSR12_IN_SROM = 4,}; static struct tulip_chip_table { int vendor_id, device_id; char *chip_name; int io_size; int valid_intrs; /* CSR7 interrupt enable settings */ int flags; void (*media_timer)(unsigned long data); } tulip_tbl[] = { { PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_TULIP, "Digital DC21040 Tulip", 128, 0x0001ebef, 0, tulip_timer }, { PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_TULIP_PLUS, "Digital DC21041 Tulip", 128, 0x0001ebef, HAS_MEDIA_TABLE, tulip_timer }, { PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_TULIP_FAST, "Digital DS21140 Tulip", 128, 0x0001ebef, HAS_MII | HAS_MEDIA_TABLE | CSR12_IN_SROM, tulip_timer }, { PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_TULIP_21142, "Digital DS21142/3 Tulip", 128, 0x0801fbff, HAS_MII | HAS_MEDIA_TABLE, t21142_timer }, { PCI_VENDOR_ID_LITEON, 0x0002, "Lite-On 82c168 PNIC", 256, 0x0001ebef, HAS_MII, pnic_timer }, { PCI_VENDOR_ID_MXIC, PCI_DEVICE_ID_MX98713, "Macronix 98713 PMAC", 128, 0x0001ebef, HAS_MII | HAS_MEDIA_TABLE | CSR12_IN_SROM, tulip_timer /* Tulip-like! */ }, { PCI_VENDOR_ID_MXIC, PCI_DEVICE_ID_MX98715, "Macronix 98715 PMAC", 256, 0x0001ebef, HAS_MEDIA_TABLE, mxic_timer }, { PCI_VENDOR_ID_MXIC, PCI_DEVICE_ID_MX98725, "Macronix 98725 PMAC", 256, 0x0001ebef, HAS_MEDIA_TABLE, mxic_timer }, { 0x125B, 0x1400, "ASIX AX88140", 128, 0x0001fbff, HAS_MII | HAS_MEDIA_TABLE | CSR12_IN_SROM, tulip_timer }, {0, 0, 0, 0}, }; /* This matches the table above. */ enum chips { DC21040=0, DC21041=1, DC21140=2, DC21142=3, DC21143=3, LC82C168, MX98713, MX98715, MX98725}; /* A full-duplex map for media types. */ enum MediaIs {MediaIsFD = 1, MediaAlwaysFD=2, MediaIsMII=4, MediaIsFx=8, MediaIs100=16}; static const char media_cap[] = {0,0,0,16, 3,19,16,24, 27,4,7,5, 0,20,23,20 }; /* 21041 transceiver register settings: 10-T, 10-2, AUI, 10-T, 10T-FD*/ static u16 t21041_csr13[] = { 0xEF05, 0xEF09, 0xEF09, 0xEF01, 0xEF09, }; static u16 t21041_csr14[] = { 0x7F3F, 0xF7FD, 0xF7FD, 0x7F3F, 0x7F3D, }; static u16 t21041_csr15[] = { 0x0008, 0x0006, 0x000E, 0x0008, 0x0008, }; static u16 t21142_csr13[] = { 0x0001, 0x0009, 0x0009, 0x0000, 0x0001, }; static u16 t21142_csr14[] = { 0xFFFF, 0x0705, 0x0705, 0x0000, 0x7F3D, }; static u16 t21142_csr15[] = { 0x0008, 0x0006, 0x000E, 0x0008, 0x0008, }; /* Offsets to the Command and Status Registers, "CSRs". All accesses must be longword instructions and quadword aligned. */ enum tulip_offsets { CSR0=0, CSR1=0x08, CSR2=0x10, CSR3=0x18, CSR4=0x20, CSR5=0x28, CSR6=0x30, CSR7=0x38, CSR8=0x40, CSR9=0x48, CSR10=0x50, CSR11=0x58, CSR12=0x60, CSR13=0x68, CSR14=0x70, CSR15=0x78 }; /* The bits in the CSR5 status registers, mostly interrupt sources. */ enum status_bits { TimerInt=0x800, TPLnkFail=0x1000, TPLnkPass=0x10, NormalIntr=0x10000, AbnormalIntr=0x8000, RxJabber=0x200, RxDied=0x100, RxNoBuf=0x80, RxIntr=0x40, TxFIFOUnderflow=0x20, TxJabber=0x08, TxNoBuf=0x04, TxDied=0x02, TxIntr=0x01, }; /* The Tulip Rx and Tx buffer descriptors. */ struct tulip_rx_desc { s32 status; s32 length; u32 buffer1, buffer2; }; struct tulip_tx_desc { s32 status; s32 length; u32 buffer1, buffer2; /* We use only buffer 1. */ }; struct medialeaf { u8 type; u8 media; unsigned char *leafdata; }; struct mediatable { u16 defaultmedia; u8 leafcount, csr12dir; /* General purpose pin directions. */ unsigned has_mii:1, has_nonmii:1; struct medialeaf mleaf[0]; }; struct mediainfo { struct mediainfo *next; int info_type; int index; unsigned char *info; }; struct tulip_private { char devname[8]; /* Used only for kernel debugging. */ const char *product_name; struct device *next_module; struct tulip_rx_desc rx_ring[RX_RING_SIZE]; struct tulip_tx_desc tx_ring[TX_RING_SIZE]; /* The saved address of a sent-in-place packet/buffer, for skfree(). */ struct sk_buff* tx_skbuff[TX_RING_SIZE]; /* The addresses of receive-in-place skbuffs. */ struct sk_buff* rx_skbuff[RX_RING_SIZE]; char *rx_buffs; /* Address of temporary Rx buffers. */ u32 setup_frame[48]; /* Pseudo-Tx frame to init address table. */ int chip_id; int revision; #if LINUX_VERSION_CODE > 0x20139 struct net_device_stats stats; #else struct enet_statistics stats; #endif struct timer_list timer; /* Media selection timer. */ int interrupt; /* In-interrupt flag. */ #ifdef SMP_CHECK int smp_proc_id; /* Which processor in IRQ handler. */ #endif unsigned int cur_rx, cur_tx; /* The next free ring entry */ unsigned int dirty_rx, dirty_tx; /* The ring entries to be free()ed. */ unsigned int tx_full:1; /* The Tx queue is full. */ unsigned int full_duplex:1; /* Full-duplex operation requested. */ unsigned int full_duplex_lock:1; unsigned int fake_addr:1; /* Multiport board faked address. */ unsigned int default_port:4; /* Last dev->if_port value. */ unsigned int media2:4; /* Secondary monitored media port. */ unsigned int medialock:1; /* Don't sense media type. */ unsigned int mediasense:1; /* Media sensing in progress. */ unsigned int csr6; /* Current CSR6 control settings. */ unsigned char eeprom[128]; /* Serial EEPROM contents. */ u16 to_advertise; /* NWay capabilities advertised. */ u16 advertising[4]; signed char phys[4], mii_cnt; /* MII device addresses. */ struct mediatable *mtable; int cur_index; /* Current media index. */ unsigned char pci_bus, pci_dev_fn; int pad0, pad1; /* Used for 8-byte alignment */ }; static struct device *tulip_probe1(int pci_bus, int pci_devfn, struct device *dev, int chip_id, int options); static void parse_eeprom(struct device *dev); static int read_eeprom(long ioaddr, int location); static int mdio_read(struct device *dev, int phy_id, int location); static void mdio_write(struct device *dev, int phy_id, int location, int value); static void select_media(struct device *dev, int startup); static int tulip_open(struct device *dev); static void tulip_timer(unsigned long data); static void tulip_tx_timeout(struct device *dev); static void tulip_init_ring(struct device *dev); static int tulip_start_xmit(struct sk_buff *skb, struct device *dev); static int tulip_rx(struct device *dev); static void tulip_interrupt IRQ(int irq, void *dev_instance, struct pt_regs *regs); static int tulip_close(struct device *dev); static struct enet_statistics *tulip_get_stats(struct device *dev); #ifdef HAVE_PRIVATE_IOCTL static int private_ioctl(struct device *dev, struct ifreq *rq, int cmd); #endif #ifdef NEW_MULTICAST static void set_rx_mode(struct device *dev); #else static void set_rx_mode(struct device *dev, int num_addrs, void *addrs); #endif /* A list of all installed Tulip devices, for removing the driver module. */ static struct device *root_tulip_dev = NULL; /* This 21040 probe no longer uses a large fixed contiguous Rx buffer region, but now receives directly into full-sized skbuffs that are allocated at open() time. This allows the probe routine to use the old driver initialization interface. */ int tulip_probe(struct device *dev) { int cards_found = 0; static int pci_index = 0; /* Static, for multiple probe calls. */ unsigned char pci_bus, pci_device_fn; /* Ideally we would detect all network cards in slot order. That would be best done a central PCI probe dispatch, which wouldn't work well with the current structure. So instead we detect just the Tulip cards in slot order. */ #if LINUX_VERSION_CODE >= 0x20155 if (! pci_present()) return -ENODEV; #else if (! pcibios_present()) return -ENODEV; #endif for (;pci_index < 0xff; pci_index++) { u16 vendor, device, pci_command, new_command; unsigned long pci_ioaddr = 0; int chip_idx = 0; if (pcibios_find_class (PCI_CLASS_NETWORK_ETHERNET << 8, reverse_probe ? 0xfe - pci_index : pci_index, &pci_bus, &pci_device_fn) != PCIBIOS_SUCCESSFUL) if (reverse_probe) continue; else break; pcibios_read_config_word(pci_bus, pci_device_fn, PCI_VENDOR_ID, &vendor); pcibios_read_config_word(pci_bus, pci_device_fn, PCI_DEVICE_ID, &device); for (chip_idx = 0; tulip_tbl[chip_idx].chip_name; chip_idx++) if (vendor == tulip_tbl[chip_idx].vendor_id && device == tulip_tbl[chip_idx].device_id) break; if (tulip_tbl[chip_idx].chip_name == 0) { if (vendor == PCI_VENDOR_ID_DEC || vendor == PCI_VENDOR_ID_LITEON) printk(KERN_INFO "Unknown Tulip-style PCI ethernet chip type" " %4.4x %4.4x"" detected: not configured.\n", vendor, device); continue; } #if LINUX_VERSION_CODE >= 0x20155 pci_ioaddr = pci_find_slot(pci_bus, pci_device_fn)->base_address[0]; #else pcibios_read_config_dword(pci_bus, pci_device_fn, PCI_BASE_ADDRESS_0, &pci_ioaddr); #endif /* Remove I/O space marker in bit 0. */ pci_ioaddr &= ~3; if (tulip_debug > 2) printk(KERN_DEBUG "Found %s at I/O %#lx.\n", tulip_tbl[chip_idx].chip_name, pci_ioaddr); if (check_region(pci_ioaddr, tulip_tbl[chip_idx].io_size)) continue; pcibios_read_config_word(pci_bus, pci_device_fn, PCI_COMMAND, &pci_command); new_command = pci_command | PCI_COMMAND_MASTER|PCI_COMMAND_IO; if (pci_command != new_command) { printk(KERN_INFO " The PCI BIOS has not enabled this" " device! Updating PCI command %4.4x->%4.4x.\n", pci_command, new_command); pcibios_write_config_word(pci_bus, pci_device_fn, PCI_COMMAND, new_command); } dev = tulip_probe1(pci_bus, pci_device_fn, dev, chip_idx, cards_found); /* Get and check the bus-master and latency values. */ if (dev) { unsigned char pci_latency; pcibios_read_config_byte(pci_bus, pci_device_fn, PCI_LATENCY_TIMER, &pci_latency); if (pci_latency < 10) { printk(KERN_INFO " PCI latency timer (CFLT) is " "unreasonably low at %d. Setting to 64 clocks.\n", pci_latency); pcibios_write_config_byte(pci_bus, pci_device_fn, PCI_LATENCY_TIMER, 64); } else if (tulip_debug > 1) printk(KERN_INFO " PCI latency timer (CFLT) is %#x, " " PCI command is %4.4x.\n", pci_latency, new_command); /* Bring the 21143 out power-down mode. */ if (device == PCI_DEVICE_ID_DEC_TULIP_21142) pcibios_write_config_dword(pci_bus, pci_device_fn, 0x40, 0x40000000); dev = 0; cards_found++; } } return cards_found ? 0 : -ENODEV; } static struct device *tulip_probe1(int pci_bus, int pci_device_fn, struct device *dev, int chip_id, int board_idx) { static int did_version = 0; /* Already printed version info. */ struct tulip_private *tp; long ioaddr; int irq; /* See note below on the multiport cards. */ static unsigned char last_phys_addr[6] = {0x00, 'L', 'i', 'n', 'u', 'x'}; static int last_irq = 0; static int multiport_cnt = 0; /* For four-port boards w/one EEPROM */ int i; unsigned short sum; if (tulip_debug > 0 && did_version++ == 0) printk(KERN_INFO "%s", version); dev = init_etherdev(dev, 0); #if LINUX_VERSION_CODE >= 0x20155 irq = pci_find_slot(pci_bus, pci_device_fn)->irq; ioaddr = pci_find_slot(pci_bus, pci_device_fn)->base_address[0]; #else { u8 pci_irq_line; u32 pci_ioaddr; pcibios_read_config_byte(pci_bus, pci_device_fn, PCI_INTERRUPT_LINE, &pci_irq_line); pcibios_read_config_dword(pci_bus, pci_device_fn, PCI_BASE_ADDRESS_0, &pci_ioaddr); irq = pci_irq_line; ioaddr = pci_ioaddr; } #endif /* Remove I/O space marker in bit 0. */ ioaddr &= ~3; printk(KERN_INFO "%s: %s at %#3lx,", dev->name, tulip_tbl[chip_id].chip_name, ioaddr); /* Stop the chip's Tx and Rx processes. */ outl(inl(ioaddr + CSR6) & ~0x2002, ioaddr + CSR6); /* Clear the missed-packet counter. */ (volatile int)inl(ioaddr + CSR8); if (chip_id == DC21041) { if (inl(ioaddr + CSR9) & 0x8000) { printk(" 21040 compatible mode,"); chip_id = DC21040; } else { printk(" 21041 mode,"); } } /* The station address ROM is read byte serially. The register must be polled, waiting for the value to be read bit serially from the EEPROM. */ sum = 0; if (chip_id == DC21040) { outl(0, ioaddr + CSR9); /* Reset the pointer with a dummy write. */ for (i = 0; i < 6; i++) { int value, boguscnt = 100000; do value = inl(ioaddr + CSR9); while (value < 0 && --boguscnt > 0); dev->dev_addr[i] = value; sum += value & 0xff; } } else if (chip_id == LC82C168) { for (i = 0; i < 3; i++) { int value, boguscnt = 100000; outl(0x600 | i, ioaddr + 0x98); do value = inl(ioaddr + CSR9); while (value < 0 && --boguscnt > 0); ((u16*)dev->dev_addr)[i] = value; sum += value & 0xffff; } } else { /* Must be a new chip, with a serial EEPROM interface. */ /* We read the whole EEPROM, and sort it out later. DEC has a specification _Digital Semiconductor 21X4 Serial ROM Format_ but early vendor boards just put the address in the first six EEPROM locations. */ unsigned char ee_data[128]; int sa_offset = 0; for (i = 0; i < sizeof(ee_data)/2; i++) ((u16 *)ee_data)[i] = read_eeprom(ioaddr, i); /* Detect the simple EEPROM format by the duplicated station addr. */ for (i = 0; i < 8; i ++) if (ee_data[i] != ee_data[16+i]) sa_offset = 20; if (ee_data[0] == 0xff && ee_data[1] == 0xff && ee_data[2] == 0) { sa_offset = 2; /* Grrr, damn Matrox boards. */ multiport_cnt = 4; } for (i = 0; i < 6; i ++) { dev->dev_addr[i] = ee_data[i + sa_offset]; sum += ee_data[i + sa_offset]; } } /* Lite-On boards have the address byte-swapped. */ if (dev->dev_addr[0] == 0xA0 && dev->dev_addr[1] == 0x00) for (i = 0; i < 6; i+=2) { char tmp = dev->dev_addr[i]; dev->dev_addr[i] = dev->dev_addr[i+1]; dev->dev_addr[i+1] = tmp; } /* On the Zynx 315 Etherarray and other multiport boards only the first Tulip has an EEPROM. The addresses of the subsequent ports are derived from the first. Many PCI BIOSes also incorrectly report the IRQ line, so we correct that here as well. */ if (sum == 0 || sum == 6*0xff) { printk(" EEPROM not present,"); for (i = 0; i < 5; i++) dev->dev_addr[i] = last_phys_addr[i]; dev->dev_addr[i] = last_phys_addr[i] + 1; #if defined(__i386__) /* This BIOS bug doesn't exist on Alphas. */ irq = last_irq; #endif } for (i = 0; i < 6; i++) printk(" %2.2x", last_phys_addr[i] = dev->dev_addr[i]); printk(", IRQ %d.\n", irq); last_irq = irq; /* We do a request_region() only to register /proc/ioports info. */ /* Note that proper size is tulip_tbl[chip_id].chip_name, but... */ request_region(ioaddr, TULIP_TOTAL_SIZE, dev->name); dev->base_addr = ioaddr; dev->irq = irq; /* Make certain the data structures are quadword aligned. */ tp = (void *)(((long)kmalloc(sizeof(*tp), GFP_KERNEL | GFP_DMA) + 7) & ~7); memset(tp, 0, sizeof(*tp)); dev->priv = tp; tp->next_module = root_tulip_dev; root_tulip_dev = dev; tp->pci_bus = pci_bus; tp->pci_dev_fn = pci_device_fn; tp->chip_id = chip_id; #ifdef TULIP_FULL_DUPLEX tp->full_duplex = 1; tp->full_duplex_lock = 1; #endif #ifdef TULIP_DEFAULT_MEDIA tp->default_port = TULIP_DEFAULT_MEDIA; #endif #ifdef TULIP_NO_MEDIA_SWITCH tp->medialock = 1; #endif /* The lower four bits are the media type. */ if (board_idx >= 0 && board_idx < MAX_UNITS) { tp->default_port = options[board_idx] & 15; if ((options[board_idx] & 0x90) || full_duplex[board_idx] > 0) tp->full_duplex = 1; if (mtu[board_idx] > 0) dev->mtu = mtu[board_idx]; } if (dev->mem_start) tp->default_port = dev->mem_start; if (tp->default_port) { tp->medialock = 1; if (media_cap[tp->default_port] & MediaAlwaysFD) tp->full_duplex = 1; } if (tp->full_duplex) tp->full_duplex_lock = 1; /* This is logically part of probe1(), but too complex to write inline. */ if (tulip_tbl[chip_id].flags & HAS_MEDIA_TABLE) parse_eeprom(dev); if (media_cap[tp->default_port] & MediaIsMII) { u16 media2advert[] = { 0x20, 0x40, 0x03e0, 0x60, 0x80, 0x100, 0x200 }; tp->to_advertise = media2advert[tp->default_port - 9]; } else tp->to_advertise = 0x03e1; if ((tp->mtable && tp->mtable->has_mii) || ( ! tp->mtable && (tulip_tbl[tp->chip_id].flags & HAS_MII))) { int phy, phy_idx; /* Find the connected MII xcvrs. Doing this in open() would allow detecting external xcvrs later, but takes much time. */ for (phy = 0, phy_idx = 0; phy < 32 && phy_idx < sizeof(tp->phys); phy++) { int mii_status = mdio_read(dev, phy, 1); if (mii_status != 0xffff && mii_status != 0x0000) { int mii_reg0 = mdio_read(dev, phy, 0); int reg4 = ((mii_status>>6) & tp->to_advertise) | 1; tp->phys[phy_idx] = phy; tp->advertising[phy_idx++] = reg4; printk(KERN_INFO "%s: MII transceiver found at MDIO address " "%d, config %4.4x status %4.4x.\n", dev->name, phy, mii_reg0, mii_status); if (1 || (media_cap[tp->default_port] & MediaIsMII)) { printk(KERN_DEBUG "%s: Advertising %4.4x on PHY %d," " previously advertising %4.4x.\n", dev->name, reg4, phy, mdio_read(dev, phy, 4)); mdio_write(dev, phy, 4, reg4); } /* Enable autonegotiation: some boards default to off. */ mdio_write(dev, phy, 0, mii_reg0 | (tp->full_duplex ? 0x1100 : 0x1000) | (media_cap[tp->default_port]&MediaIs100 ? 0x2000:0)); } } tp->mii_cnt = phy_idx; if (tp->mtable && tp->mtable->has_mii && phy_idx == 0) { printk(KERN_INFO "%s: ***WARNING***: No MII transceiver found!\n", dev->name); tp->phys[0] = 1; } } /* The Tulip-specific entries in the device structure. */ dev->open = &tulip_open; dev->hard_start_xmit = &tulip_start_xmit; dev->stop = &tulip_close; dev->get_stats = &tulip_get_stats; #ifdef HAVE_PRIVATE_IOCTL dev->do_ioctl = &private_ioctl; #endif #ifdef HAVE_MULTICAST dev->set_multicast_list = &set_rx_mode; #endif /* Reset the xcvr interface and turn on heartbeat. */ switch (chip_id) { case DC21041: outl(0x00000000, ioaddr + CSR13); outl(0xFFFFFFFF, ioaddr + CSR14); outl(0x00000008, ioaddr + CSR15); /* Listen on AUI also. */ outl(inl(ioaddr + CSR6) | 0x0200, ioaddr + CSR6); outl(0x0000EF05, ioaddr + CSR13); break; case DC21040: outl(0x00000000, ioaddr + CSR13); outl(0x00000004, ioaddr + CSR13); break; case DC21140: default: if (tp->mtable) outl(tp->mtable->csr12dir | 0x100, ioaddr + CSR12); break; case DC21142: outl(0x82420200, ioaddr + CSR6); outl(0x0001, ioaddr + CSR13); outl(0x0003FFFF, ioaddr + CSR14); outl(0x0008, ioaddr + CSR15); outl(0x0001, ioaddr + CSR13); outl(0x1301, ioaddr + CSR12); /* Start NWay. */ break; case LC82C168: if ( ! tp->mii_cnt) { outl(0x00420000, ioaddr + CSR6); outl(0x30, ioaddr + CSR12); outl(0x0001F078, ioaddr + 0xB8); outl(0x0201F078, ioaddr + 0xB8); /* Turn on autonegotiation. */ } break; case MX98713: case MX98715: case MX98725: outl(0x00000000, ioaddr + CSR6); outl(0x000711C0, ioaddr + CSR14); /* Turn on NWay. */ outl(0x00000001, ioaddr + CSR13); break; } return dev; } /* Serial EEPROM section. */ /* The main routine to parse the very complicated SROM structure. Search www.digital.com for "21X4 SROM" to get details. This code is very complex, and will require changes to support additional cards, so I'll be verbose about what is going on. */ /* Known cards that have old-style EEPROMs. */ static struct fixups { char *name; unsigned char addr0, addr1, addr2; u16 newtable[32]; /* Max length below. */ } eeprom_fixups[] = { {"Asante", 0, 0, 0x94, {0x1e00, 0x0000, 0x0800, 0x0100, 0x018c, 0x0000, 0x0000, 0xe078, 0x0001, 0x0050, 0x0018 }}, {"SMC9332DST", 0, 0, 0xC0, { 0x1e00, 0x0000, 0x0800, 0x021f, 0x0000, 0x009E, /* 10baseT */ 0x0903, 0x006D, /* 100baseTx */ }}, {"Cogent EM100", 0, 0, 0x92, { 0x1e00, 0x0000, 0x0800, 0x033f, 0x0107, 0x8021, /* 100baseFx */ 0x0108, 0x8021, /* 100baseFx-FD */ 0x0103, 0x006D, /* 100baseTx */ }}, {"Maxtech NX-110", 0, 0, 0xE8, { 0x1e00, 0x0000, 0x0800, 0x0313, 0x1001, 0x009E, /* 10base2, CSR12 0x10*/ 0x0000, 0x009E, /* 10baseT */ 0x0303, 0x006D, /* 100baseTx, CSR12 0x03 */ }}, {"Accton EN1207", 0, 0, 0xE8, { 0x1e00, 0x0000, 0x0800, 0x031F, 0x1B01, 0x0000, /* 10base2, CSR12 0x1B */ 0x1B03, 0x006D, /* 100baseTx, CSR12 0x1B */ 0x0B00, 0x009E, /* 10baseT, CSR12 0x0B */ }}, {0, 0, 0, 0, {}}}; static const char * block_name[] = {"21140 non-MII", "21140 MII PHY", "21142 Serial PHY", "21142 MII PHY", "21143 SYM PHY", "21143 reset method"}; #define EEPROM_SIZE 128 #if defined(__i386__) #define get_u16(ptr) (*(u16 *)(ptr)) #else #define get_u16(ptr) (((u8*)(ptr))[0] + (((u8*)(ptr))[1]<<8)) #endif static void parse_eeprom(struct device *dev) { /* The last media info list parsed, for multiport boards. */ static struct mediatable *last_mediatable = NULL; static unsigned char *last_ee_data = NULL; static int controller_index = 0; struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; unsigned char *ee_data = tp->eeprom; int i; tp->mtable = 0; for (i = 0; i < EEPROM_SIZE/2; i++) ((u16 *)ee_data)[i] = read_eeprom(ioaddr, i); /* Detect an old-style (SA only) EEPROM layout: memcmp(eedata, eedata+16, 8). */ for (i = 0; i < 8; i ++) if (ee_data[i] != ee_data[16+i]) break; if (i >= 8) { if (ee_data[0] == 0xff) { if (last_mediatable) { controller_index++; printk(KERN_INFO "%s: Controller %d of multiport board.\n", dev->name, controller_index); tp->mtable = last_mediatable; ee_data = last_ee_data; goto subsequent_board; } else printk(KERN_INFO "%s: Missing EEPROM, this interface may " "not work correctly!\n", dev->name); return; } /* Do a fix-up based on the vendor half of the station address prefix. */ for (i = 0; eeprom_fixups[i].name; i++) { if (dev->dev_addr[0] == eeprom_fixups[i].addr0 && dev->dev_addr[1] == eeprom_fixups[i].addr1 && dev->dev_addr[2] == eeprom_fixups[i].addr2) { if (dev->dev_addr[2] == 0xE8 && ee_data[0x1a] == 0x55) i++; /* An Accton EN1207, not an outlaw Maxtech. */ memcpy(ee_data + 26, eeprom_fixups[i].newtable, sizeof(eeprom_fixups[i].newtable)); printk(KERN_INFO "%s: Old format EEPROM on '%s' board. Using" " substitute media control info.\n", dev->name, eeprom_fixups[i].name); break; } } if (eeprom_fixups[i].name == NULL) { /* No fixup found. */ printk(KERN_INFO "%s: Old style EEPROM -- no media selection information.\n", dev->name); return; } } if (tulip_debug > 1) { printk(KERN_DEBUG "read_eeprom:"); for (i = 0; i < 64; i++) { printk("%s%4.4x", (i & 7) == 0 ? "\n" KERN_DEBUG : " ", read_eeprom(ioaddr, i)); } printk("\n"); } controller_index = 0; if (ee_data[19] > 1) { /* Multiport board. */ last_ee_data = ee_data; } subsequent_board: if (ee_data[27] == 0) { /* No valid media table. */ } else if (tp->chip_id == DC21041) { unsigned char *p = (void *)ee_data + ee_data[27 + controller_index*3]; short media; int count; media = get_u16(p); p += 2; count = *p++; printk(KERN_INFO "%s:21041 Media information at %d, default media " "%4.4x (%s).\n", dev->name, ee_data[27], media, media & 0x0800 ? "Autosense" : medianame[media & 15]); for (i = 0; i < count; i++) { unsigned char media_code = *p++; u16 csrvals[3]; int idx; for (idx = 0; idx < 3; idx++) { csrvals[idx] = get_u16(p); p += 2; } if (media_code & 0x40) { printk(KERN_INFO "%s: 21041 media %2.2x (%s)," " csr13 %4.4x csr14 %4.4x csr15 %4.4x.\n", dev->name, media_code & 15, medianame[media_code & 15], csrvals[0], csrvals[1], csrvals[2]); } else printk(KERN_INFO "%s: 21041 media #%d, %s.\n", dev->name, media_code & 15, medianame[media_code & 15]); } } else { unsigned char *p = (void *)ee_data + ee_data[27]; unsigned char csr12dir = 0; int count; struct mediatable *mtable; u16 media = get_u16(p); p += 2; if (tulip_tbl[tp->chip_id].flags & CSR12_IN_SROM) csr12dir = *p++; count = *p++; mtable = (struct mediatable *) kmalloc(sizeof(struct mediatable) + count*sizeof(struct medialeaf), GFP_KERNEL); if (mtable == NULL) return; /* Horrible, impossible failure. */ last_mediatable = tp->mtable = mtable; mtable->defaultmedia = media; mtable->leafcount = count; mtable->csr12dir = csr12dir; mtable->has_nonmii = mtable->has_mii = 0; printk(KERN_INFO "%s: EEPROM default media type %s.\n", dev->name, media & 0x0800 ? "Autosense" : medianame[media & 15]); for (i = 0; i < count; i++) { struct medialeaf *leaf = &mtable->mleaf[i]; if ((p[0] & 0x80) == 0) { /* 21140 Compact block. */ leaf->type = 0; leaf->media = p[0] & 0x3f; leaf->leafdata = p; if ((p[2] & 0x61) == 0x01) /* Bogus, but Znyx boards do it. */ mtable->has_mii = 1; p += 4; } else { leaf->type = p[1]; if (p[1] & 1) { mtable->has_mii = 1; leaf->media = 11; } else { mtable->has_nonmii = 1; leaf->media = p[2] & 0x0f; } leaf->leafdata = p + 2; p += (p[0] & 0x3f) + 1; } if (tulip_debug > 1 && leaf->media == 11) { unsigned char *bp = leaf->leafdata; printk(KERN_INFO "%s: MII interface PHY %d, setup/reset " "sequences %d/%d long, capabilities %2.2x %2.2x.\n", dev->name, bp[0], bp[1], bp[1 + bp[1]*2], bp[5 + bp[2 + bp[1]*2]*2], bp[4 + bp[2 + bp[1]*2]*2]); } printk(KERN_INFO "%s: Index #%d - Media %s (#%d) described " "by a %s (%d) block.\n", dev->name, i, medianame[leaf->media], leaf->media, block_name[leaf->type], leaf->type); } } } /* Reading a serial EEPROM is a "bit" grungy, but we work our way through:->.*/ /* EEPROM_Ctrl bits. */ #define EE_SHIFT_CLK 0x02 /* EEPROM shift clock. */ #define EE_CS 0x01 /* EEPROM chip select. */ #define EE_DATA_WRITE 0x04 /* EEPROM chip data in. */ #define EE_WRITE_0 0x01 #define EE_WRITE_1 0x05 #define EE_DATA_READ 0x08 /* EEPROM chip data out. */ #define EE_ENB (0x4800 | EE_CS) /* Delay between EEPROM clock transitions. The 1.2 code is a "nasty" timing loop, but PC compatible machines are *supposed* to delay an ISA-compatible period for the SLOW_DOWN_IO macro. */ #ifdef _LINUX_DELAY_H #define eeprom_delay(nanosec) udelay((nanosec + 999)/1000) #else #define eeprom_delay(nanosec) do { int _i = 3; while (--_i > 0) { __SLOW_DOWN_IO; }} while (0) #endif /* The EEPROM commands include the alway-set leading bit. */ #define EE_WRITE_CMD (5 << 6) #define EE_READ_CMD (6 << 6) #define EE_ERASE_CMD (7 << 6) static int read_eeprom(long ioaddr, int location) { int i; unsigned short retval = 0; long ee_addr = ioaddr + CSR9; int read_cmd = location | EE_READ_CMD; outl(EE_ENB & ~EE_CS, ee_addr); outl(EE_ENB, ee_addr); /* Shift the read command bits out. */ for (i = 10; i >= 0; i--) { short dataval = (read_cmd & (1 << i)) ? EE_DATA_WRITE : 0; outl(EE_ENB | dataval, ee_addr); eeprom_delay(100); outl(EE_ENB | dataval | EE_SHIFT_CLK, ee_addr); eeprom_delay(150); outl(EE_ENB | dataval, ee_addr); /* Finish EEPROM a clock tick. */ eeprom_delay(250); } outl(EE_ENB, ee_addr); for (i = 16; i > 0; i--) { outl(EE_ENB | EE_SHIFT_CLK, ee_addr); eeprom_delay(100); retval = (retval << 1) | ((inl(ee_addr) & EE_DATA_READ) ? 1 : 0); outl(EE_ENB, ee_addr); eeprom_delay(100); } /* Terminate the EEPROM access. */ outl(EE_ENB & ~EE_CS, ee_addr); return retval; } /* MII transceiver control section. Read and write the MII registers using software-generated serial MDIO protocol. See the MII specifications or DP83840A data sheet for details. */ /* The maximum data clock rate is 2.5 Mhz. The minimum timing is usually met by back-to-back PCI I/O cycles, but we insert a delay to avoid "overclocking" issues or future 66Mhz PCI. */ #define mdio_delay() inl(mdio_addr) /* Read and write the MII registers using software-generated serial MDIO protocol. It is just different enough from the EEPROM protocol to not share code. The maxium data clock rate is 2.5 Mhz. */ #define MDIO_SHIFT_CLK 0x10000 #define MDIO_DATA_WRITE0 0x00000 #define MDIO_DATA_WRITE1 0x20000 #define MDIO_ENB 0x00000 /* Ignore the 0x02000 databook setting. */ #define MDIO_ENB_IN 0x40000 #define MDIO_DATA_READ 0x80000 static int mdio_read(struct device *dev, int phy_id, int location) { struct tulip_private *tp = (struct tulip_private *)dev->priv; int i; int read_cmd = (0xf6 << 10) | (phy_id << 5) | location; int retval = 0; long mdio_addr = dev->base_addr + CSR9; if (tp->chip_id == LC82C168) { long ioaddr = dev->base_addr; int i = 1000; outl(0x60020000 + (phy_id<<23) + (location<<18), ioaddr + 0xA0); while (--i > 0) if ( ! ((retval = inl(ioaddr + 0xA0)) & 0x80000000)) return retval & 0xffff; return 0xffff; } /* Establish sync by sending at least 32 logic ones. */ for (i = 32; i >= 0; i--) { outl(MDIO_ENB | MDIO_DATA_WRITE1, mdio_addr); mdio_delay(); outl(MDIO_ENB | MDIO_DATA_WRITE1 | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } /* Shift the read command bits out. */ for (i = 15; i >= 0; i--) { int dataval = (read_cmd & (1 << i)) ? MDIO_DATA_WRITE1 : 0; outl(MDIO_ENB | dataval, mdio_addr); mdio_delay(); outl(MDIO_ENB | dataval | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } /* Read the two transition, 16 data, and wire-idle bits. */ for (i = 19; i > 0; i--) { outl(MDIO_ENB_IN, mdio_addr); mdio_delay(); retval = (retval << 1) | ((inl(mdio_addr) & MDIO_DATA_READ) ? 1 : 0); outl(MDIO_ENB_IN | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } return (retval>>1) & 0xffff; } static void mdio_write(struct device *dev, int phy_id, int location, int value) { struct tulip_private *tp = (struct tulip_private *)dev->priv; int i; int cmd = (0x5002 << 16) | (phy_id << 23) | (location<<18) | value; long mdio_addr = dev->base_addr + CSR9; if (tp->chip_id == LC82C168) { long ioaddr = dev->base_addr; int i = 1000; outl(cmd, ioaddr + 0xA0); do if ( ! (inl(ioaddr + 0xA0) & 0x80000000)) break; while (--i > 0); return; } /* Establish sync by sending 32 logic ones. */ for (i = 32; i >= 0; i--) { outl(MDIO_ENB | MDIO_DATA_WRITE1, mdio_addr); mdio_delay(); outl(MDIO_ENB | MDIO_DATA_WRITE1 | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } /* Shift the command bits out. */ for (i = 31; i >= 0; i--) { int dataval = (cmd & (1 << i)) ? MDIO_DATA_WRITE1 : 0; outl(MDIO_ENB | dataval, mdio_addr); mdio_delay(); outl(MDIO_ENB | dataval | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } /* Clear out extra bits. */ for (i = 2; i > 0; i--) { outl(MDIO_ENB_IN, mdio_addr); mdio_delay(); outl(MDIO_ENB_IN | MDIO_SHIFT_CLK, mdio_addr); mdio_delay(); } return; } static int tulip_open(struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; int i = 0; /* On some chip revs we must set the MII/SYM port before the reset!? */ if (tp->mii_cnt || (tp->mtable && tp->mtable->has_mii)) outl(0x00040000, ioaddr + CSR6); /* Reset the chip, holding bit 0 set at least 50 PCI cycles. */ outl(0x00000001, ioaddr + CSR0); #ifdef _LINUX_DELAY_H udelay(2); #else SLOW_DOWN_IO; #endif /* Deassert reset. 486: Set 8 longword cache alignment, 8 longword burst. 586: Set 16 longword cache alignment, no burst limit. Cache alignment bits 15:14 Burst length 13:8 0000 No alignment 0x00000000 unlimited 0800 8 longwords 4000 8 longwords 0100 1 longword 1000 16 longwords 8000 16 longwords 0200 2 longwords 2000 32 longwords C000 32 longwords 0400 4 longwords Wait the specified 50 PCI cycles after a reset by initializing Tx and Rx queues and the address filter list. */ #if defined(__alpha__) /* ToDo: Alpha setting could be better. */ outl(0x01A00000 | 0xE000, ioaddr + CSR0); #elif defined(__powerpc__) outl(0x01A00080 | 0x8000, ioaddr + CSR0); #elif defined(__i386__) #if defined(MODULE) /* When a module we don't have 'x86' to check. */ outl(0x01A00000 | 0x4800, ioaddr + CSR0); #else #if (LINUX_VERSION_CODE > 0x2014c) #define x86 boot_cpu_data.x86 #endif outl(0x01A00000 | (x86 <= 4 ? 0x4800 : 0x8000), ioaddr + CSR0); if (x86 <= 4) printk(KERN_INFO "%s: This is a 386/486 PCI system, setting cache " "alignment to %x.\n", dev->name, 0x01A00000 | (x86 <= 4 ? 0x4800 : 0x8000)); #endif #else outl(0x01A00000 | 0x4800, ioaddr + CSR0); #warning Processor architecture undefined! #endif #ifdef SA_SHIRQ if (request_irq(dev->irq, &tulip_interrupt, SA_SHIRQ, dev->name, dev)) { return -EAGAIN; } #else if (irq2dev_map[dev->irq] != NULL || (irq2dev_map[dev->irq] = dev) == NULL || dev->irq == 0 || request_irq(dev->irq, &tulip_interrupt, 0, tulip_tbl[tp->chip_id].chip_name)) { return -EAGAIN; } #endif if (tulip_debug > 1) printk(KERN_DEBUG "%s: tulip_open() irq %d.\n", dev->name, dev->irq); MOD_INC_USE_COUNT; tulip_init_ring(dev); /* This is set_rx_mode(), but without starting the transmitter. */ /* Fill the whole address filter table with our physical address. */ { u16 *eaddrs = (u16 *)dev->dev_addr; u32 *setup_frm = tp->setup_frame, i; /* You must add the broadcast address when doing perfect filtering! */ *setup_frm++ = 0xffff; *setup_frm++ = 0xffff; *setup_frm++ = 0xffff; /* Fill the rest of the accept table with our physical address. */ for (i = 1; i < 16; i++) { *setup_frm++ = eaddrs[0]; *setup_frm++ = eaddrs[1]; *setup_frm++ = eaddrs[2]; } /* Put the setup frame on the Tx list. */ tp->tx_ring[0].length = 0x08000000 | 192; tp->tx_ring[0].buffer1 = virt_to_bus(tp->setup_frame); tp->tx_ring[0].status = 0x80000000; tp->cur_tx++; } outl(virt_to_bus(tp->rx_ring), ioaddr + CSR3); outl(virt_to_bus(tp->tx_ring), ioaddr + CSR4); if (dev->if_port == 0) dev->if_port = tp->default_port; if (tp->chip_id == DC21041 && dev->if_port > 4) /* Invalid: Select initial TP, autosense, autonegotiate. */ dev->if_port = 4; /* Allow selecting a default media. */ if (tp->mtable == NULL) goto media_picked; if (dev->if_port) { int looking_for = media_cap[dev->if_port] & MediaIsMII ? 11 : (dev->if_port == 12 ? 0 : dev->if_port); for (i = 0; i < tp->mtable->leafcount; i++) if (tp->mtable->mleaf[i].media == looking_for) { printk(KERN_INFO "%s: Using user-specified media %s.\n", dev->name, medianame[dev->if_port]); goto media_picked; } } if ((tp->mtable->defaultmedia & 0x0800) == 0) for (i = 0; i < tp->mtable->leafcount; i++) if (tp->mtable->mleaf[i].media == (tp->mtable->defaultmedia & 15)) { printk(KERN_INFO "%s: Using EEPROM-set media %s.\n", dev->name, medianame[tp->mtable->mleaf[i].media]); goto media_picked; } /* Start sensing first non-full-duplex media. */ for (i = tp->mtable->leafcount - 1; (media_cap[tp->mtable->mleaf[i].media] & MediaAlwaysFD) && i > 0; i--) ; media_picked: tp->csr6 = 0; tp->cur_index = i; if (dev->if_port == 0 && tp->chip_id == DC21142) { tp->csr6 = 0x82420200; outl(0x0003FFFF, ioaddr + CSR14); outl(0x0008, ioaddr + CSR15); outl(0x0001, ioaddr + CSR13); outl(0x1301, ioaddr + CSR12); } else if (tp->chip_id == LC82C168 && tp->mii_cnt && ! tp->medialock) { dev->if_port = 11; tp->csr6 = 0x816C0000 | (tp->full_duplex ? 0x0200 : 0); outl(0x0001, ioaddr + CSR15); } else select_media(dev, 1); /* Start the chip's Tx to process setup frame. */ outl(tp->csr6, ioaddr + CSR6); outl(tp->csr6 | 0x2000, ioaddr + CSR6); dev->tbusy = 0; tp->interrupt = 0; dev->start = 1; /* Enable interrupts by setting the interrupt mask. */ outl(tulip_tbl[tp->chip_id].valid_intrs, ioaddr + CSR5); outl(tulip_tbl[tp->chip_id].valid_intrs, ioaddr + CSR7); outl(tp->csr6 | 0x2002, ioaddr + CSR6); outl(0, ioaddr + CSR2); /* Rx poll demand */ if (tulip_debug > 2) { printk(KERN_DEBUG "%s: Done tulip_open(), CSR0 %8.8x, CSR5 %8.8x CSR6 %8.8x.\n", dev->name, inl(ioaddr + CSR0), inl(ioaddr + CSR5), inl(ioaddr + CSR6)); } /* Set the timer to switch to check for link beat and perhaps switch to an alternate media type. */ init_timer(&tp->timer); tp->timer.expires = RUN_AT(5*HZ); tp->timer.data = (unsigned long)dev; tp->timer.function = tulip_tbl[tp->chip_id].media_timer; add_timer(&tp->timer); return 0; } /* Set up the transceiver control registers for the selected media type. */ static void select_media(struct device *dev, int startup) { long ioaddr = dev->base_addr; struct tulip_private *tp = (struct tulip_private *)dev->priv; struct mediatable *mtable = tp->mtable; u32 new_csr6; int check_mii =0, i; if (mtable) { struct medialeaf *mleaf = &mtable->mleaf[tp->cur_index]; unsigned char *p = mleaf->leafdata; switch (mleaf->type) { case 0: /* 21140 non-MII xcvr. */ if (tulip_debug > 1) printk(KERN_DEBUG "%s: Using a 21140 non-MII transceiver" " with control setting %2.2x.\n", dev->name, p[1]); dev->if_port = p[0]; if (startup) outl(mtable->csr12dir | 0x100, ioaddr + CSR12); outl(p[1], ioaddr + CSR12); new_csr6 = 0x02000000 | ((p[2] & 0x71) << 18); break; case 2: case 4: { u16 setup[3]; for (i = 0; i < 3; i++) setup[i] = get_u16(&p[i*2 + 1]); dev->if_port = p[0] & 15; if (tulip_debug > 1) printk(KERN_DEBUG "%s: 21142 non-MII %s transceiver control %4.4x/%4.4x.\n", dev->name, medianame[dev->if_port], setup[0], setup[1]); if (p[0] & 0x40) { /* SIA (CSR13-15) setup values are provided. */ outl(0, ioaddr + CSR13); outl(setup[1], ioaddr + CSR14); outl(setup[2], ioaddr + CSR15); outl(setup[0], ioaddr + CSR13); for (i = 0; i < 3; i++) /* Re-fill setup[] */ setup[i] = get_u16(&p[i*2 + 7]); } else if (dev->if_port <= 4) { outl(0, ioaddr + CSR13); outl(t21142_csr14[dev->if_port], ioaddr + CSR14); outl(t21142_csr15[dev->if_port], ioaddr + CSR15); outl(t21142_csr13[dev->if_port], ioaddr + CSR13); } else { outl(0, ioaddr + CSR14); outl(8, ioaddr + CSR15); outl(0, ioaddr + CSR13); } outl(setup[0]<<16, ioaddr + CSR15); /* Direction */ outl(setup[1]<<16, ioaddr + CSR15); /* Data */ if (mleaf->type == 4) new_csr6 = 0x82020000 | ((setup[2] & 0x71) << 18); else new_csr6 = 0x82420000; break; } case 1: case 3: { int phy_num = p[0]; int init_length = p[1]; u16 *misc_info; u16 to_advertise; dev->if_port = 11; check_mii = 1; new_csr6 = 0x020E0000; if (mleaf->type == 3) { /* 21142 */ u16 *init_sequence = (u16*)(p+2); u16 *reset_sequence = &((u16*)(p+3))[init_length]; int reset_length = p[2 + init_length*2]; misc_info = reset_sequence + reset_length; if (startup) for (i = 0; i < reset_length; i++) outl(get_u16(&reset_sequence[i]) << 16, ioaddr + CSR15); for (i = 0; i < init_length; i++) outl(get_u16(&init_sequence[i]) << 16, ioaddr + CSR15); } else { u8 *init_sequence = p + 2; u8 *reset_sequence = p + 3 + init_length; int reset_length = p[2 + init_length]; misc_info = (u16*)(reset_sequence + reset_length); if (startup) { outl(mtable->csr12dir | 0x100, ioaddr + CSR12); for (i = 0; i < reset_length; i++) outl(reset_sequence[i], ioaddr + CSR12); } for (i = 0; i < init_length; i++) outl(init_sequence[i], ioaddr + CSR12); } to_advertise = (get_u16(&misc_info[1]) & tp->to_advertise) | 1; tp->advertising[phy_num] = to_advertise; if (tulip_debug > 1 || 1) printk(KERN_DEBUG "%s: Advertising %4.4x on PHY %d (%d).\n", dev->name, to_advertise, phy_num, tp->phys[phy_num]); /* Bogus: put in by a committee? */ mdio_write(dev, tp->phys[phy_num], 4, to_advertise); break; } default: new_csr6 = 0x020E0000; } if (tulip_debug > 1) printk(KERN_DEBUG "%s: Using media type %s, CSR12 is %2.2x.\n", dev->name, medianame[dev->if_port], inl(ioaddr + CSR12) & 0xff); } else if (tp->chip_id == DC21041) { if (tulip_debug > 1) printk(KERN_DEBUG "%s: 21041 using media %s, CSR12 is %4.4x.\n", dev->name, medianame[dev->if_port & 15], inl(ioaddr + CSR12) & 0xffff); outl(0x00000000, ioaddr + CSR13); /* Reset the serial interface */ outl(t21041_csr14[dev->if_port], ioaddr + CSR14); outl(t21041_csr15[dev->if_port], ioaddr + CSR15); outl(t21041_csr13[dev->if_port], ioaddr + CSR13); new_csr6 = 0x80020000; } else if (tp->chip_id == LC82C168) { if (startup && ! tp->medialock) dev->if_port = tp->mii_cnt ? 11 : 0; if (tulip_debug > 1) printk(KERN_DEBUG "%s: PNIC PHY status is %3.3x, CSR12 %4.4x," " media %s.\n", dev->name, inl(ioaddr + 0xB8), inl(ioaddr + CSR12), medianame[dev->if_port]); if (tp->mii_cnt) { new_csr6 = 0x812C0000; outl(0x0001, ioaddr + CSR15); outl(0x0201B07A, ioaddr + 0xB8); } else if (startup) { /* Start with 10mbps to do autonegotiation. */ outl(0x32, ioaddr + CSR12); new_csr6 = 0x00420000; outl(0x0001B078, ioaddr + 0xB8); outl(0x0201B078, ioaddr + 0xB8); } else if (dev->if_port == 3 || dev->if_port == 5) { outl(0x33, ioaddr + CSR12); new_csr6 = 0x01860000; if (startup) outl(0x0201F868, ioaddr + 0xB8); /* Trigger autonegotiation. */ else outl(0x1F868, ioaddr + 0xB8); } else { outl(0x32, ioaddr + CSR12); new_csr6 = 0x00420000; outl(0x1F078, ioaddr + 0xB8); } } else if (tp->chip_id == DC21040) { /* 21040 */ /* Turn on the xcvr interface. */ int csr12 = inl(ioaddr + CSR12); if (tulip_debug > 1) printk(KERN_DEBUG "%s: 21040 media type is %s, CSR12 is %2.2x.\n", dev->name, dev->if_port ? "AUI" : "10baseT", csr12); new_csr6 = (dev->if_port ? 0x01860000 : 0x00420000); /* Set the full duplux match frame. */ outl(FULL_DUPLEX_MAGIC, ioaddr + CSR11); outl(0x00000000, ioaddr + CSR13); /* Reset the serial interface */ outl(dev->if_port ? 0x0000000C : 0x00000004, ioaddr + CSR13); } else { /* Unknown chip type with no media table. */ if (tp->default_port == 0) if (tp->mii_cnt) { dev->if_port = 11; } else dev->if_port = 3; if (media_cap[dev->if_port] & MediaIsMII) { new_csr6 = 0x020E0000; } else if (media_cap[dev->if_port] & MediaIsFx) { new_csr6 = 0x028600000; } else new_csr6 = 0x038600000; if (tulip_debug > 1) printk(KERN_DEBUG "%s: No media description table, assuming " "%s transceiver, CSR12 %2.2x.\n", dev->name, medianame[dev->if_port], inl(ioaddr + CSR12)); } tp->csr6 = new_csr6 | (tp->csr6 & 0xfdff) | (tp->full_duplex ? 0x0200 : 0); return; } static void tulip_timer(unsigned long data) { struct device *dev = (struct device *)data; struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; u32 csr12 = inl(ioaddr + CSR12); int next_tick = 0; if (tulip_debug > 3) { printk(KERN_DEBUG "%s: Media selection tick, status %8.8x mode %8.8x " "SIA %8.8x %8.8x %8.8x %8.8x.\n", dev->name, inl(ioaddr + CSR5), inl(ioaddr + CSR6), csr12, inl(ioaddr + CSR13), inl(ioaddr + CSR14), inl(ioaddr + CSR15)); } switch (tp->chip_id) { case DC21040: if (csr12 & 0x0002) { /* Network error */ printk(KERN_INFO "%s: No 10baseT link beat found, switching to %s media.\n", dev->name, dev->if_port ? "10baseT" : "AUI"); dev->if_port ^= 1; outl(dev->if_port ? 0x0000000C : 0x00000004, ioaddr + CSR13); dev->trans_start = jiffies; } break; case DC21041: if (tulip_debug > 2) printk(KERN_DEBUG "%s: 21041 media tick CSR12 %8.8x.\n", dev->name, csr12); switch (dev->if_port) { case 0: case 3: case 4: if (csr12 & 0x0004) { /*LnkFail */ /* 10baseT is dead. Check for activity on alternate port. */ tp->mediasense = 1; if (csr12 & 0x0200) dev->if_port = 2; else dev->if_port = 1; printk(KERN_INFO "%s: No 21041 10baseT link beat, Media switched to %s.\n", dev->name, medianame[dev->if_port]); outl(0, ioaddr + CSR13); /* Reset */ outl(t21041_csr14[dev->if_port], ioaddr + CSR14); outl(t21041_csr15[dev->if_port], ioaddr + CSR15); outl(t21041_csr13[dev->if_port], ioaddr + CSR13); next_tick = 10*HZ; /* 2.4 sec. */ } else next_tick = 30*HZ; break; case 1: /* 10base2 */ case 2: /* AUI */ if (csr12 & 0x0100) { next_tick = (30*HZ); /* 30 sec. */ tp->mediasense = 0; } else if ((csr12 & 0x0004) == 0) { printk(KERN_INFO "%s: 21041 media switched to 10baseT.\n", dev->name); dev->if_port = 0; select_media(dev, 0); next_tick = (24*HZ)/10; /* 2.4 sec. */ } else if (tp->mediasense || (csr12 & 0x0002)) { dev->if_port = 3 - dev->if_port; /* Swap ports. */ select_media(dev, 0); next_tick = 20*HZ; } else { next_tick = 20*HZ; } break; } break; case DC21140: case DC21142: case MX98713: default: { struct medialeaf *mleaf; unsigned char *p; if (tp->mtable == NULL) { /* No EEPROM info, use generic code. */ /* Not much that can be done. Assume this a generic MII or SYM transceiver. */ next_tick = 60*HZ; if (tulip_debug > 2) printk(KERN_DEBUG "%s: network media monitor CSR6 %8.8x " "CSR12 0x%2.2x.\n", dev->name, inl(ioaddr + CSR6), csr12 & 0xff); break; } mleaf = &tp->mtable->mleaf[tp->cur_index]; p = mleaf->leafdata; switch (mleaf->type) { case 0: case 4: { /* Type 0 serial or 4 SYM transceiver. Check the link beat bit. */ int offset = mleaf->type == 4 ? 5 : 2; s8 bitnum = p[offset]; if (p[offset+1] & 0x80) { if (tulip_debug > 1) printk(KERN_DEBUG"%s: Transceiver monitor tick " "CSR12=%#2.2x, no media sense.\n", dev->name, csr12); if (mleaf->type == 4) { if (mleaf->media == 3 && (csr12 & 0x02)) goto select_next_media; } break; } if (tulip_debug > 2) printk(KERN_DEBUG "%s: Transceiver monitor tick: CSR12=%#2.2x" " bit %d is %d, expecting %d.\n", dev->name, csr12, (bitnum >> 1) & 7, (csr12 & (1 << ((bitnum >> 1) & 7))) != 0, (bitnum >= 0)); /* Check that the specified bit has the proper value. */ if ((bitnum < 0) != ((csr12 & (1 << ((bitnum >> 1) & 7))) != 0)) { if (tulip_debug > 1) printk(KERN_DEBUG "%s: Link beat detected for %s.\n", dev->name, medianame[mleaf->media]); if ((p[2] & 0x61) == 0x01) /* Bogus Znyx board. */ goto actually_mii; break; } if (tp->medialock) break; select_next_media: if (--tp->cur_index < 0) { /* We start again, but should instead look for default. */ tp->cur_index = tp->mtable->leafcount - 1; } dev->if_port = tp->mtable->mleaf[tp->cur_index].media; if (media_cap[dev->if_port] & MediaIsFD) goto select_next_media; /* Skip FD entries. */ if (tulip_debug > 1) printk(KERN_DEBUG "%s: No link beat on media %s," " trying transceiver type %s.\n", dev->name, medianame[mleaf->media & 15], medianame[tp->mtable->mleaf[tp->cur_index].media]); select_media(dev, 0); /* Restart the transmit process. */ outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); next_tick = (24*HZ)/10; break; } case 1: case 3: { /* 21140, 21142 MII */ int mii_reg1, mii_reg5; actually_mii: mii_reg1 = mdio_read(dev, tp->phys[0], 1); mii_reg5 = mdio_read(dev, tp->phys[0], 5); if (tulip_debug > 1) printk(KERN_INFO "%s: MII status %4.4x, Link partner report " "%4.4x, CSR12 %2.2x, %cD.\n", dev->name, mii_reg1, mii_reg5, csr12, tp->full_duplex ? 'F' : 'H'); if (mii_reg1 != 0xffff && (mii_reg1 & 0x0004) == 0) { int new_reg1 = mdio_read(dev, tp->phys[0], 1); if ((new_reg1 & 0x0004) == 0) { printk(KERN_INFO "%s: No link beat on the MII interface," " status then %4.4x now %4.4x.\n", dev->name, mii_reg1, new_reg1); if (tp->mtable && tp->mtable->has_nonmii) goto select_next_media; } } if (mii_reg5 == 0xffff || mii_reg5 == 0x0000) ; /* No MII device or no link partner report */ else if (tp->full_duplex_lock) ; else { int negotiated = mii_reg5 & tp->advertising[0]; int duplex = ((negotiated & 0x0100) != 0 || (negotiated & 0x00C0) == 0x0040); /* 100baseTx-FD or 10T-FD, but not 100-HD */ if (tp->full_duplex != duplex) { tp->full_duplex = duplex; if (tp->full_duplex) tp->csr6 |= 0x0200; else tp->csr6 &= ~0x0200; outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); if (tulip_debug > 0) /* Gurppp, should be >1 */ printk(KERN_INFO "%s: Setting %s-duplex based on MII" " Xcvr #%d parter capability of %4.4x.\n", dev->name, tp->full_duplex ? "full" : "half", tp->phys[0], mii_reg5); } } next_tick = 60*HZ; break; } case 2: /* 21142 serial block has no link beat. */ default: break; } } break; } if (next_tick) { tp->timer.expires = RUN_AT(next_tick); add_timer(&tp->timer); } } /* Handle the 21143 uniquely: do autoselect with NWay, not the EEPROM list of available transceivers. */ static void t21142_timer(unsigned long data) { struct device *dev = (struct device *)data; struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; int csr12 = inl(ioaddr + CSR12); int next_tick = 60*HZ; int new_csr6 = 0; if (tulip_debug > 1) printk(KERN_INFO"%s: 21142 negotiation status %8.8x, %s.\n", dev->name, csr12, medianame[dev->if_port]); if (dev->if_port == 3) { if (csr12 & 2) { /* No 100mbps link beat, revert to 10mbps. */ new_csr6 = 0x82420200; outl(new_csr6, ioaddr + CSR6); outl(0x0000, ioaddr + CSR13); outl(0x0003FFFF, ioaddr + CSR14); outl(0x0008, ioaddr + CSR15); outl(0x0001, ioaddr + CSR13); outl(0x1301, ioaddr + CSR12); /* Start NWay. */ } } else if ((csr12 & 0x7000) != 0x5000) { /* Negotiation failed. Search media types. */ if (tulip_debug > 1) printk(KERN_INFO"%s: 21142 negotiation failed, status %8.8x.\n", dev->name, csr12); if (!(csr12 & 4)) { /* 10mbps link beat good. */ new_csr6 = 0x82420000; dev->if_port = 0; outl(0, ioaddr + CSR13); outl(0x0003FFFF, ioaddr + CSR14); outl(t21142_csr15[dev->if_port], ioaddr + CSR15); outl(t21142_csr13[dev->if_port], ioaddr + CSR13); } else if (csr12 & 0x100) { new_csr6 = 0x82420200; dev->if_port = 2; outl(0, ioaddr + CSR13); outl(0x0003FFFF, ioaddr + CSR14); outl(0x0008, ioaddr + CSR15); outl(0x0001, ioaddr + CSR13); } else { /* Select 100mbps port to check for link beat. */ new_csr6 = 0x83860000; dev->if_port = 3; outl(0, ioaddr + CSR13); outl(0x0003FF7F, ioaddr + CSR14); outl(8, ioaddr + CSR15); outl(1, ioaddr + CSR13); } if (tulip_debug > 1) printk(KERN_INFO"%s: Testing new 21142 media %s.\n", dev->name, medianame[dev->if_port]); if (new_csr6 != (tp->csr6 & ~0x00D5)) { tp->csr6 &= 0x00D5; tp->csr6 |= new_csr6; outl(0x0301, ioaddr + CSR12); outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); } } tp->timer.expires = RUN_AT(next_tick); add_timer(&tp->timer); } static void t21142_lnk_change( struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; int csr12 = inl(ioaddr + CSR12); if (tulip_debug > 1) printk(KERN_INFO"%s: 21142 link status interrupt %8.8x, CSR5 %x.\n", dev->name, csr12, inl(ioaddr + CSR5)); if ((csr12 & 0x7000) == 0x5000) { if (csr12 & 0x01800000) { /* Switch to 100mbps mode. */ outl(tp->csr6 | 0x0002, ioaddr + CSR6); if (csr12 & 0x01000000) { dev->if_port = 5; tp->csr6 = 0x83860200; } else { dev->if_port = 3; tp->csr6 = 0x83860000; } outl(tp->csr6 | 0x2002, ioaddr + CSR6); } /* Else 10baseT-FD is handled automatically. */ } else if (dev->if_port == 3) { if (!(csr12 & 2)) printk(KERN_INFO"%s: 21142 100baseTx link beat good.\n", dev->name); else dev->if_port = 0; } else if (dev->if_port == 0) { if (!(csr12 & 4)) printk(KERN_INFO"%s: 21142 10baseT link beat good.\n", dev->name); } else if (!(csr12 & 4)) { /* 10mbps link beat good. */ printk(KERN_INFO"%s: 21142 10mpbs sensed media.\n", dev->name); dev->if_port = 0; } else { /* 100mbps link beat good. */ printk(KERN_INFO"%s: 21142 100baseTx sensed media.\n", dev->name); dev->if_port = 3; tp->csr6 = 0x83860000; outl(0x0003FF7F, ioaddr + CSR14); outl(0x0301, ioaddr + CSR12); outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); } } static void mxic_timer(unsigned long data) { struct device *dev = (struct device *)data; struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; int next_tick = 60*HZ; if (tulip_debug > 3) { printk(KERN_INFO"%s: MXIC negotiation status %8.8x.\n", dev->name, inl(ioaddr + CSR12)); } if (next_tick) { tp->timer.expires = RUN_AT(next_tick); add_timer(&tp->timer); } } static void pnic_timer(unsigned long data) { struct device *dev = (struct device *)data; struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; int csr12 = inl(ioaddr + CSR12); int next_tick = 60*HZ; int new_csr6 = tp->csr6 & ~0x40C40200; if (media_cap[dev->if_port] & MediaIsMII) { int negotiated = mdio_read(dev, tp->phys[0], 5) & tp->advertising[0]; if (tulip_debug > 1) printk(KERN_DEBUG "%s: LC82C168 negotiated capability %8.8x, " "CSR5 %8.8x.\n", dev->name, negotiated, inl(ioaddr + CSR5)); if (negotiated & 0x0380) /* 10 vs 100mbps */ new_csr6 |= 0x812E0000; else new_csr6 |= 0x816E0000; if (((negotiated & 0x0300) == 0x0100) /* Duplex */ || (negotiated & 0x00C0) == 0x0040 || tp->full_duplex_lock) { tp->full_duplex = 1; new_csr6 |= 0x0200; } if (tulip_debug > 1) printk(KERN_DEBUG "%s: LC82C168 MII PHY status %4.4x, Link " "partner report %4.4x, csr6 %8.8x/%8.8x.\n", dev->name, mdio_read(dev, tp->phys[0], 1), negotiated, tp->csr6, inl(ioaddr + CSR6)); } else { int phy_reg = inl(ioaddr + 0xB8); int csr5 = inl(ioaddr + CSR5); if (tulip_debug > 1) printk(KERN_DEBUG "%s: LC82C168 phy status %8.8x, CSR5 %8.8x.\n", dev->name, phy_reg, csr5); if (phy_reg & 0x04000000) { /* Remote link fault */ /*outl(0x0201F078, ioaddr + 0xB8);*/ next_tick = 3*HZ; } if (inl(ioaddr + CSR5) & TPLnkFail) { /* 100baseTx link beat */ if (tulip_debug > 1) printk(KERN_DEBUG "%s: %s link beat failed, CSR12 %4.4x, " "CSR5 %8.8x, PHY %3.3x.\n", dev->name, medianame[dev->if_port], csr12, inl(ioaddr + CSR5), inl(ioaddr + 0xB8)); if (tp->medialock) { } else if (dev->if_port == 0) { dev->if_port = 3; outl(0x33, ioaddr + CSR12); new_csr6 = 0x01860000; outl(0x1F868, ioaddr + 0xB8); } else { dev->if_port = 0; outl(0x32, ioaddr + CSR12); new_csr6 = 0x00420000; outl(0x1F078, ioaddr + 0xB8); } new_csr6 |= (tp->csr6 & 0xfdff); next_tick = 3*HZ; } else new_csr6 = tp->csr6; if (tp->full_duplex_lock || (phy_reg & 0x30000000) != 0) { tp->full_duplex = 1; new_csr6 |= 0x00000200; } } if (tp->csr6 != new_csr6) { tp->csr6 = new_csr6; outl(tp->csr6 | 0x0002, ioaddr + CSR6); /* Restart Tx */ outl(tp->csr6 | 0x2002, ioaddr + CSR6); dev->trans_start = jiffies; if (tulip_debug > 0) /* Gurppp, should be >1 */ printk(KERN_INFO "%s: Changing PNIC configuration to %s-duplex, " "CSR6 %8.8x.\n", dev->name, tp->full_duplex ? "full" : "half", new_csr6); } tp->timer.expires = RUN_AT(next_tick); add_timer(&tp->timer); } static void tulip_tx_timeout(struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; if (media_cap[dev->if_port] & MediaIsMII) { /* Do nothing -- the media monitor should handle this. */ if (tulip_debug > 1) printk(KERN_WARNING "%s: Transmit timeout using MII device.\n", dev->name); dev->trans_start = jiffies; return; } else if (tp->chip_id == DC21040) { if (inl(ioaddr + CSR12) & 0x0002) { printk(KERN_INFO "%s: transmit timed out, switching to %s media.\n", dev->name, dev->if_port ? "10baseT" : "AUI"); dev->if_port ^= 1; outl(dev->if_port ? 0x0000000C : 0x00000004, ioaddr + CSR13); } dev->trans_start = jiffies; return; } else if (tp->chip_id == DC21041) { u32 csr12 = inl(ioaddr + CSR12); printk(KERN_WARNING "%s: 21041 transmit timed out, status %8.8x, CSR12 %8.8x," " CSR13 %8.8x, CSR14 %8.8x, resetting...\n", dev->name, inl(ioaddr + CSR5), csr12, inl(ioaddr + CSR13), inl(ioaddr + CSR14)); tp->mediasense = 1; if (dev->if_port == 1 || dev->if_port == 2) if (csr12 & 0x0004) { dev->if_port = 2 - dev->if_port; } else dev->if_port = 0; else dev->if_port = 1; select_media(dev, 0); tp->stats.tx_errors++; dev->trans_start = jiffies; return; } else if (tp->chip_id == DC21140 || tp->chip_id == DC21142 || tp->chip_id == MX98713) { /* Stop the transmit process. */ outl(tp->csr6 | 0x0002, ioaddr + CSR6); printk(KERN_WARNING "%s: 21140 transmit timed out, status %8.8x, " "SIA %8.8x %8.8x %8.8x %8.8x, resetting...\n", dev->name, inl(ioaddr + CSR5), inl(ioaddr + CSR12), inl(ioaddr + CSR13), inl(ioaddr + CSR14), inl(ioaddr + CSR15)); if (tp->mtable) { if (--tp->cur_index < 0) { /* We start again, but should instead look for default. */ tp->cur_index = tp->mtable->leafcount - 1; } select_media(dev, 0); printk(KERN_WARNING "%s: transmit timed out, switching to %s media.\n", dev->name, dev->if_port ? "100baseTx" : "10baseT"); } outl(tp->csr6 | 0x2002, ioaddr + CSR6); tp->stats.tx_errors++; dev->trans_start = jiffies; return; } else printk(KERN_WARNING "%s: transmit timed out, status %8.8x, CSR12 %8.8x," " resetting...\n", dev->name, inl(ioaddr + CSR5), inl(ioaddr + CSR12)); #ifdef way_too_many_messages printk(" Rx ring %8.8x: ", (int)tp->rx_ring); for (i = 0; i < RX_RING_SIZE; i++) printk(" %8.8x", (unsigned int)tp->rx_ring[i].status); printk("\n Tx ring %8.8x: ", (int)tp->tx_ring); for (i = 0; i < TX_RING_SIZE; i++) printk(" %8.8x", (unsigned int)tp->tx_ring[i].status); printk("\n"); #endif /* Perhaps we should reinitialize the hardware here. */ dev->if_port = 0; /* Stop and restart the chip's Tx processes . */ outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); /* Trigger an immediate transmit demand. */ outl(0, ioaddr + CSR1); dev->trans_start = jiffies; tp->stats.tx_errors++; return; } /* Initialize the Rx and Tx rings, along with various 'dev' bits. */ static void tulip_init_ring(struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; int i; tp->tx_full = 0; tp->cur_rx = tp->cur_tx = 0; tp->dirty_rx = tp->dirty_tx = 0; for (i = 0; i < RX_RING_SIZE; i++) { tp->rx_ring[i].status = 0x80000000; /* Owned by Tulip chip */ tp->rx_ring[i].length = PKT_BUF_SZ; { /* Note the receive buffer must be longword aligned. dev_alloc_skb() provides 16 byte alignment. But do *not* use skb_reserve() to align the IP header! */ struct sk_buff *skb; skb = DEV_ALLOC_SKB(PKT_BUF_SZ); tp->rx_skbuff[i] = skb; if (skb == NULL) break; /* Bad news! */ skb->dev = dev; /* Mark as being used by this device. */ #if LINUX_VERSION_CODE > 0x10300 tp->rx_ring[i].buffer1 = virt_to_bus(skb->tail); #else tp->rx_ring[i].buffer1 = virt_to_bus(skb->data); #endif } tp->rx_ring[i].buffer2 = virt_to_bus(&tp->rx_ring[i+1]); } /* Mark the last entry as wrapping the ring. */ tp->rx_ring[i-1].length = PKT_BUF_SZ | 0x02000000; tp->rx_ring[i-1].buffer2 = virt_to_bus(&tp->rx_ring[0]); /* The Tx buffer descriptor is filled in as needed, but we do need to clear the ownership bit. */ for (i = 0; i < TX_RING_SIZE; i++) { tp->tx_skbuff[i] = 0; tp->tx_ring[i].status = 0x00000000; tp->tx_ring[i].buffer2 = virt_to_bus(&tp->tx_ring[i+1]); } tp->tx_ring[i-1].buffer2 = virt_to_bus(&tp->tx_ring[0]); } static int tulip_start_xmit(struct sk_buff *skb, struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; int entry; u32 flag; /* Block a timer-based transmit from overlapping. This could better be done with atomic_swap(1, dev->tbusy), but set_bit() works as well. */ if (test_and_set_bit(0, (void*)&dev->tbusy) != 0) { if (jiffies - dev->trans_start < TX_TIMEOUT) return 1; tulip_tx_timeout(dev); return 1; } /* Caution: the write order is important here, set the base address with the "ownership" bits last. */ /* Calculate the next Tx descriptor entry. */ entry = tp->cur_tx % TX_RING_SIZE; tp->tx_skbuff[entry] = skb; tp->tx_ring[entry].buffer1 = virt_to_bus(skb->data); if (tp->cur_tx - tp->dirty_tx < TX_RING_SIZE/2) {/* Typical path */ flag = 0x60000000; /* No interrupt */ dev->tbusy = 0; } else if (tp->cur_tx - tp->dirty_tx == TX_RING_SIZE/2) { flag = 0xe0000000; /* Tx-done intr. */ dev->tbusy = 0; } else if (tp->cur_tx - tp->dirty_tx < TX_RING_SIZE - 2) { flag = 0x60000000; /* No Tx-done intr. */ dev->tbusy = 0; } else { /* Leave room for set_rx_mode() to fill entries. */ flag = 0xe0000000; /* Tx-done intr. */ tp->tx_full = 1; } if (entry == TX_RING_SIZE-1) flag |= 0xe2000000; tp->tx_ring[entry].length = skb->len | flag; tp->tx_ring[entry].status = 0x80000000; /* Pass ownership to the chip. */ tp->cur_tx++; /* Trigger an immediate transmit demand. */ outl(0, dev->base_addr + CSR1); dev->trans_start = jiffies; return 0; } /* The interrupt handler does all of the Rx thread work and cleans up after the Tx thread. */ static void tulip_interrupt IRQ(int irq, void *dev_instance, struct pt_regs *regs) { #ifdef SA_SHIRQ /* Use the now-standard shared IRQ implementation. */ struct device *dev = (struct device *)dev_instance; #else struct device *dev = (struct device *)(irq2dev_map[irq]); #endif struct tulip_private *tp; long ioaddr; int csr5, work_budget = max_interrupt_work; if (dev == NULL) { printk (KERN_ERR" tulip_interrupt(): irq %d for unknown device.\n", irq); return; } ioaddr = dev->base_addr; tp = (struct tulip_private *)dev->priv; if (test_and_set_bit(0, (void*)&tp->interrupt)) { #ifdef SMP_CHECK printk(KERN_ERR "%s: Re-entering the interrupt handler with proc %d," " proc %d already handling.\n", dev->name, tp->smp_proc_id, hard_smp_processor_id()); #else printk(KERN_ERR "%s: Re-entering the interrupt handler.\n", dev->name); #endif return; } dev->interrupt = 1; #ifdef SMP_CHECK tp->smp_proc_id = hard_smp_processor_id(); #endif do { csr5 = inl(ioaddr + CSR5); /* Acknowledge all of the current interrupt sources ASAP. */ outl(csr5 & 0x0001ffff, ioaddr + CSR5); if (tulip_debug > 4) printk(KERN_DEBUG "%s: interrupt csr5=%#8.8x new csr5=%#8.8x.\n", dev->name, csr5, inl(dev->base_addr + CSR5)); if ((csr5 & (NormalIntr|AbnormalIntr)) == 0) break; if (csr5 & (RxIntr | RxNoBuf)) work_budget -= tulip_rx(dev); if (csr5 & (TxNoBuf | TxDied | TxIntr)) { unsigned int dirty_tx; for (dirty_tx = tp->dirty_tx; tp->cur_tx - dirty_tx > 0; dirty_tx++) { int entry = dirty_tx % TX_RING_SIZE; int status = tp->tx_ring[entry].status; if (status < 0) break; /* It still hasn't been Txed */ /* Check for Rx filter setup frames. */ if (tp->tx_skbuff[entry] == NULL) continue; if (status & 0x8000) { /* There was an major error, log it. */ #ifndef final_version if (tulip_debug > 1) printk(KERN_DEBUG "%s: Transmit error, Tx status %8.8x.\n", dev->name, status); #endif tp->stats.tx_errors++; if (status & 0x4104) tp->stats.tx_aborted_errors++; if (status & 0x0C00) tp->stats.tx_carrier_errors++; if (status & 0x0200) tp->stats.tx_window_errors++; if (status & 0x0002) tp->stats.tx_fifo_errors++; if ((status & 0x0080) && tp->full_duplex == 0) tp->stats.tx_heartbeat_errors++; #ifdef ETHER_STATS if (status & 0x0100) tp->stats.collisions16++; #endif } else { #ifdef ETHER_STATS if (status & 0x0001) tp->stats.tx_deferred++; #endif #if LINUX_VERSION_CODE > 0x20127 tp->stats.tx_bytes += tp->tx_ring[entry].length & 0x7ff; #endif tp->stats.collisions += (status >> 3) & 15; tp->stats.tx_packets++; } /* Free the original skb. */ #if (LINUX_VERSION_CODE > 0x20155) dev_kfree_skb(tp->tx_skbuff[entry]); #else dev_kfree_skb(tp->tx_skbuff[entry], FREE_WRITE); #endif tp->tx_skbuff[entry] = 0; } #ifndef final_version if (tp->cur_tx - dirty_tx > TX_RING_SIZE) { printk(KERN_ERR "%s: Out-of-sync dirty pointer, %d vs. %d, full=%d.\n", dev->name, dirty_tx, tp->cur_tx, tp->tx_full); dirty_tx += TX_RING_SIZE; } #endif if (tp->tx_full && dev->tbusy && tp->cur_tx - dirty_tx < TX_RING_SIZE - 2) { /* The ring is no longer full, clear tbusy. */ tp->tx_full = 0; dev->tbusy = 0; mark_bh(NET_BH); } tp->dirty_tx = dirty_tx; if (csr5 & TxDied) { if (tulip_debug > 1) printk(KERN_WARNING "%s: The transmitter stopped!" " CSR5 is %x, CSR6 %x.\n", dev->name, csr5, inl(ioaddr + CSR6)); outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); } } /* Log errors. */ if (csr5 & AbnormalIntr) { /* Abnormal error summary bit. */ if (csr5 & TxJabber) tp->stats.tx_errors++; if (csr5 & TxFIFOUnderflow) { if ((tp->csr6 & 0xC000) != 0xC000) tp->csr6 += 0x4000; /* Bump up the Tx threshold */ else tp->csr6 |= 0x00200000; /* Store-n-forward. */ /* Restart the transmit process. */ outl(tp->csr6 | 0x0002, ioaddr + CSR6); outl(tp->csr6 | 0x2002, ioaddr + CSR6); } if (csr5 & RxDied) { /* Missed a Rx frame. */ tp->stats.rx_errors++; tp->stats.rx_missed_errors += inl(ioaddr + CSR8) & 0xffff; } if (csr5 & TimerInt) { printk(KERN_ERR "%s: Something Wicked happened! %8.8x.\n", dev->name, csr5); /* Hmmmmm, it's not clear what to do here. */ } if (csr5 & (TPLnkPass | TPLnkFail | 0x08000000) && tp->chip_id == DC21142) { if (tulip_debug > 1) printk(KERN_INFO"%s: 21142 link change, CSR5 = %8.8x.\n", dev->name, csr5); t21142_lnk_change(dev); } /* Clear all error sources, included undocumented ones! */ outl(0x0800f7ba, ioaddr + CSR5); } if (--work_budget < 0) { if (tulip_debug > 1) printk(KERN_WARNING "%s: Too much work at interrupt, " "csr5=0x%8.8x.\n", dev->name, csr5); /* Acknowledge all interrupt sources. */ outl(0x8001ffff, ioaddr + CSR5); #ifdef notdef /* Clear all but standard interrupt sources. */ outl((~csr5) & 0x0001ebef, ioaddr + CSR7); #endif break; } } while (1); if (tulip_debug > 3) printk(KERN_DEBUG "%s: exiting interrupt, csr5=%#4.4x.\n", dev->name, inl(ioaddr + CSR5)); dev->interrupt = 0; clear_bit(0, (void*)&tp->interrupt); return; } static int tulip_rx(struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; int entry = tp->cur_rx % RX_RING_SIZE; int rx_work_limit = tp->dirty_rx + RX_RING_SIZE - tp->cur_rx; int work_done = 0; if (tulip_debug > 4) printk(KERN_DEBUG " In tulip_rx(), entry %d %8.8x.\n", entry, tp->rx_ring[entry].status); /* If we own the next entry, it's a new packet. Send it up. */ while (tp->rx_ring[entry].status >= 0) { s32 status = tp->rx_ring[entry].status; if (--rx_work_limit < 0) break; if ((status & 0x0300) != 0x0300) { if ((status & 0xffff) != 0x7fff) { /* Ingore earlier buffers. */ if (tulip_debug > 1) printk(KERN_WARNING "%s: Oversized Ethernet frame spanned " "multiple buffers, status %8.8x!\n", dev->name, status); tp->stats.rx_length_errors++; } } else if (status & 0x8000) { /* There was a fatal error. */ if (tulip_debug > 2) printk(KERN_DEBUG "%s: Receive error, Rx status %8.8x.\n", dev->name, status); tp->stats.rx_errors++; /* end of a packet.*/ if (status & 0x0890) tp->stats.rx_length_errors++; if (status & 0x0004) tp->stats.rx_frame_errors++; if (status & 0x0002) tp->stats.rx_crc_errors++; if (status & 0x0001) tp->stats.rx_fifo_errors++; } else { /* Omit the four octet CRC from the length. */ short pkt_len = (status >> 16) - 4; struct sk_buff *skb; /* Check if the packet is long enough to just accept without copying to a properly sized skbuff. */ if (pkt_len < rx_copybreak && (skb = DEV_ALLOC_SKB(pkt_len+2)) != NULL) { skb->dev = dev; skb_reserve(skb, 2); /* 16 byte align the IP header */ #if LINUX_VERSION_CODE < 0x10300 memcpy(skb->data, tp->rx_ring[entry].buffer1, pkt_len); #elif LINUX_VERSION_CODE < 0x20200 || defined(__alpha__) memcpy(skb_put(skb, pkt_len), bus_to_virt(tp->rx_ring[entry].buffer1), pkt_len); #else eth_copy_and_sum(skb, bus_to_virt(tp->rx_ring[entry].buffer1), pkt_len, 0); skb_put(skb, pkt_len); #endif work_done++; } else { /* Pass up the skb already on the Rx ring. */ skb = tp->rx_skbuff[entry]; tp->rx_skbuff[entry] = NULL; #ifndef final_version { void *temp = skb_put(skb, pkt_len); if (bus_to_virt(tp->rx_ring[entry].buffer1) != temp) printk(KERN_ERR "%s: Internal consistency error! The " "skbuff addresses do not match in tulip_rx:" " %p vs. %p / %p.\n", dev->name, bus_to_virt(tp->rx_ring[entry].buffer1), skb->head, temp); } #else skb_put(skb, pkt_len); #endif } #if LINUX_VERSION_CODE > 0x10300 skb->protocol = eth_type_trans(skb, dev); #else skb->len = pkt_len; #endif netif_rx(skb); dev->last_rx = jiffies; tp->stats.rx_packets++; #if LINUX_VERSION_CODE > 0x20127 tp->stats.rx_bytes += pkt_len; #endif } entry = (++tp->cur_rx) % RX_RING_SIZE; } /* Refill the Rx ring buffers. */ for (; tp->cur_rx - tp->dirty_rx > 0; tp->dirty_rx++) { entry = tp->dirty_rx % RX_RING_SIZE; if (tp->rx_skbuff[entry] == NULL) { struct sk_buff *skb; skb = tp->rx_skbuff[entry] = DEV_ALLOC_SKB(PKT_BUF_SZ); if (skb == NULL) break; skb->dev = dev; /* Mark as being used by this device. */ #if LINUX_VERSION_CODE > 0x10300 tp->rx_ring[entry].buffer1 = virt_to_bus(skb->tail); #else tp->rx_ring[entry].buffer1 = virt_to_bus(skb->data); #endif work_done++; } tp->rx_ring[entry].status = 0x80000000; } return work_done; } static int tulip_close(struct device *dev) { long ioaddr = dev->base_addr; struct tulip_private *tp = (struct tulip_private *)dev->priv; int i; dev->start = 0; dev->tbusy = 1; if (tulip_debug > 1) printk(KERN_DEBUG "%s: Shutting down ethercard, status was %2.2x.\n", dev->name, inl(ioaddr + CSR5)); /* Disable interrupts by clearing the interrupt mask. */ outl(0x00000000, ioaddr + CSR7); /* Stop the chip's Tx and Rx processes. */ outl(inl(ioaddr + CSR6) & ~0x2002, ioaddr + CSR6); /* 21040 -- Leave the card in 10baseT state. */ if (tp->chip_id == DC21040) outl(0x00000004, ioaddr + CSR13); tp->stats.rx_missed_errors += inl(ioaddr + CSR8) & 0xffff; del_timer(&tp->timer); #ifdef SA_SHIRQ free_irq(dev->irq, dev); #else free_irq(dev->irq); irq2dev_map[dev->irq] = 0; #endif /* Free all the skbuffs in the Rx queue. */ for (i = 0; i < RX_RING_SIZE; i++) { struct sk_buff *skb = tp->rx_skbuff[i]; tp->rx_skbuff[i] = 0; tp->rx_ring[i].status = 0; /* Not owned by Tulip chip. */ tp->rx_ring[i].length = 0; tp->rx_ring[i].buffer1 = 0xBADF00D0; /* An invalid address. */ if (skb) { #if LINUX_VERSION_CODE < 0x20100 skb->free = 1; #endif #if (LINUX_VERSION_CODE > 0x20155) dev_kfree_skb(skb); #else dev_kfree_skb(skb, FREE_WRITE); #endif } } for (i = 0; i < TX_RING_SIZE; i++) { if (tp->tx_skbuff[i]) #if (LINUX_VERSION_CODE > 0x20155) dev_kfree_skb(tp->tx_skbuff[i]); #else dev_kfree_skb(tp->tx_skbuff[i], FREE_WRITE); #endif tp->tx_skbuff[i] = 0; } MOD_DEC_USE_COUNT; return 0; } static struct enet_statistics * tulip_get_stats(struct device *dev) { struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; if (dev->start) tp->stats.rx_missed_errors += inl(ioaddr + CSR8) & 0xffff; return &tp->stats; } #ifdef HAVE_PRIVATE_IOCTL /* Provide ioctl() calls to examine the MII xcvr state. */ static int private_ioctl(struct device *dev, struct ifreq *rq, int cmd) { struct tulip_private *tp = (struct tulip_private *)dev->priv; long ioaddr = dev->base_addr; u16 *data = (u16 *)&rq->ifr_data; int phy = tp->phys[0] & 0x1f; long flags; switch(cmd) { case SIOCDEVPRIVATE: /* Get the address of the PHY in use. */ if (tp->mtable && tp->mtable->has_mii) data[0] = phy; else if (tp->chip_id == DC21142) data[0] = 32; else return -ENODEV; return 0; case SIOCDEVPRIVATE+1: /* Read the specified MII register. */ if (data[0] == 32) { /* 21142 pseudo-MII */ int csr12 = inl(ioaddr + CSR12); int csr14 = inl(ioaddr + CSR14); switch (data[1]) { case 0: { data[3] = ((csr14<<13)&0x4000) + ((csr14<<5)&0x1000); break; } case 1: data[3] = 0x7848 + ((csr12&0x7000) == 0x5000 ? 0x20 : 0) + (csr12&0x06 ? 0x04 : 0); break; case 4: { int csr14 = inl(ioaddr + CSR14); data[3] = ((csr14>>9)&0x0380) + ((csr14>>1)&0x20) + 1; break; } case 5: data[3] = inl(ioaddr + CSR12) >> 16; break; default: data[3] = 0; break; } } else { save_flags(flags); cli(); data[3] = mdio_read(dev, data[0] & 0x1f, data[1] & 0x1f); restore_flags(flags); } return 0; case SIOCDEVPRIVATE+2: /* Write the specified MII register */ if (!suser()) return -EPERM; if (data[0] == 32) { /* 21142 pseudo-MII */ } else { save_flags(flags); cli(); mdio_write(dev, data[0] & 0x1f, data[1] & 0x1f, data[2]); restore_flags(flags); } return 0; default: return -EOPNOTSUPP; } return -EOPNOTSUPP; } #endif /* HAVE_PRIVATE_IOCTL */ /* Set or clear the multicast filter for this adaptor. Note that we only use exclusion around actually queueing the new frame, not around filling tp->setup_frame. This is non-deterministic when re-entered but still correct. */ /* The little-endian AUTODIN32 ethernet CRC calculation. N.B. Do not use for bulk data, use a table-based routine instead. This is common code and should be moved to net/core/crc.c */ static unsigned const ethernet_polynomial_le = 0xedb88320U; static inline unsigned ether_crc_le(int length, unsigned char *data) { unsigned int crc = 0xffffffff; /* Initial value. */ while(--length >= 0) { unsigned char current_octet = *data++; int bit; for (bit = 8; --bit >= 0; current_octet >>= 1) { if ((crc ^ current_octet) & 1) { crc >>= 1; crc ^= ethernet_polynomial_le; } else crc >>= 1; } } return crc; } #ifdef NEW_MULTICAST static void set_rx_mode(struct device *dev) #else static void set_rx_mode(struct device *dev, int num_addrs, void *addrs) #endif { long ioaddr = dev->base_addr; int csr6 = inl(ioaddr + CSR6) & ~0x00D5; struct tulip_private *tp = (struct tulip_private *)dev->priv; tp->csr6 &= ~0x00D5; if (dev->flags & IFF_PROMISC) { /* Set promiscuous. */ outl(csr6 | 0x00C0, ioaddr + CSR6); /* Unconditionally log net taps. */ printk(KERN_INFO "%s: Promiscuous mode enabled.\n", dev->name); tp->csr6 |= 0xC0; } else if ((dev->mc_count > 1000) || (dev->flags & IFF_ALLMULTI)) { /* Too many to filter perfectly -- accept all multicasts. */ outl(csr6 | 0x0080, ioaddr + CSR6); tp->csr6 |= 0x80; } else { u32 *setup_frm = tp->setup_frame; struct dev_mc_list *mclist; u16 *eaddrs; u32 tx_flags; int i; if (dev->mc_count > 14) { /* Must use a multicast hash table. */ u16 hash_table[32]; memset(hash_table, 0, sizeof(hash_table)); /* This should work on big-endian machines as well. */ for (i = 0, mclist = dev->mc_list; mclist && i < dev->mc_count; i++, mclist = mclist->next) set_bit(ether_crc_le(ETH_ALEN, mclist->dmi_addr) & 0x1ff, hash_table); /* Copy the hash table to the setup frame. NOTE that only the LOW SHORTWORD of setup_frame[] is valid! */ for (i = 0; i < 32; i++) *setup_frm++ = hash_table[i]; setup_frm += 7; tx_flags = 0x08400000 | 192; /* Too clever: i > 15 for fall-though. */ } else { /* We have <= 15 addresses so we can use the wonderful 16 address perfect filtering of the Tulip. */ for (i = 0, mclist = dev->mc_list; i < dev->mc_count; i++, mclist = mclist->next) { /* Note that only the low shortword of setup_frame[] is valid! This code may require tweaking for non-x86 architectures! */ eaddrs = (u16 *)mclist->dmi_addr; *setup_frm++ = *eaddrs++; *setup_frm++ = *eaddrs++; *setup_frm++ = *eaddrs++; } /* Fill the rest of the table with our physical address. Once again, only the low shortword or setup_frame[] is valid! */ *setup_frm++ = 0xffff; *setup_frm++ = 0xffff; *setup_frm++ = 0xffff; tx_flags = 0x08000000 | 192; } eaddrs = (u16 *)dev->dev_addr; do { *setup_frm++ = eaddrs[0]; *setup_frm++ = eaddrs[1]; *setup_frm++ = eaddrs[2]; } while (++i < 15); /* Now add this frame to the Tx list. */ if (tp->cur_tx - tp->dirty_tx > TX_RING_SIZE - 2) { /* Same setup recently queued, we need not add it. */ } else { unsigned long flags; unsigned int entry; save_flags(flags); cli(); entry = tp->cur_tx++ % TX_RING_SIZE; if (entry != 0) { /* Avoid a chip errata by prefixing a dummy entry. */ tp->tx_skbuff[entry] = 0; tp->tx_ring[entry].length = (entry == TX_RING_SIZE-1) ? 0x02000000 : 0; tp->tx_ring[entry].buffer1 = 0; tp->tx_ring[entry].status = 0x80000000; entry = tp->cur_tx++ % TX_RING_SIZE; } tp->tx_skbuff[entry] = 0; /* Put the setup frame on the Tx list. */ if (entry == TX_RING_SIZE-1) tx_flags |= 0x02000000; /* Wrap ring. */ tp->tx_ring[entry].length = tx_flags; tp->tx_ring[entry].buffer1 = virt_to_bus(tp->setup_frame); tp->tx_ring[entry].status = 0x80000000; if (tp->cur_tx - tp->dirty_tx >= TX_RING_SIZE - 2) { dev->tbusy = 1; tp->tx_full = 1; } restore_flags(flags); /* Trigger an immediate transmit demand. */ outl(0, ioaddr + CSR1); } outl(csr6 | 0x0000, ioaddr + CSR6); } } #ifdef CARDBUS #include static dev_node_t *tulip_attach(dev_locator_t *loc) { u16 dev_id; u32 io; u8 bus, devfn; struct device *dev; if (loc->bus != LOC_PCI) return NULL; bus = loc->b.pci.bus; devfn = loc->b.pci.devfn; printk(KERN_INFO "tulip_attach(bus %d, function %d)\n", bus, devfn); pcibios_read_config_dword(bus, devfn, PCI_BASE_ADDRESS_0, &io); pcibios_read_config_word(bus, devfn, PCI_DEVICE_ID, &dev_id); io &= ~3; dev = tulip_probe1(bus, devfn, NULL, DC21142, -1); if (dev) { dev_node_t *node = kmalloc(sizeof(dev_node_t), GFP_KERNEL); strcpy(node->dev_name, dev->name); node->major = node->minor = 0; node->next = NULL; MOD_INC_USE_COUNT; return node; } return NULL; } static void tulip_detach(dev_node_t *node) { struct device **devp, **next; printk(KERN_INFO "tulip_detach(%s)\n", node->dev_name); for (devp = &root_tulip_dev; *devp; devp = next) { next = &((struct tulip_private *)(*devp)->priv)->next_module; if (strcmp((*devp)->name, node->dev_name) == 0) break; } if (*devp) { unregister_netdev(*devp); kfree(*devp); *devp = *next; kfree(node); MOD_DEC_USE_COUNT; } } struct driver_operations tulip_ops = { "tulip_cb", tulip_attach, NULL, NULL, tulip_detach }; #endif /* Cardbus support */ #ifdef MODULE #if LINUX_VERSION_CODE > 0x20118 MODULE_AUTHOR("Donald Becker "); MODULE_DESCRIPTION("Digital 21*4* Tulip ethernet driver"); MODULE_PARM(debug, "i"); MODULE_PARM(max_interrupt_work, "i"); MODULE_PARM(reverse_probe, "i"); MODULE_PARM(rx_copybreak, "i"); MODULE_PARM(options, "1-" __MODULE_STRING(MAX_UNITS) "i"); MODULE_PARM(full_duplex, "1-" __MODULE_STRING(MAX_UNITS) "i"); #endif /* An additional parameter that may be passed in... */ static int debug = -1; int init_module(void) { if (debug >= 0) tulip_debug = debug; #ifdef CARDBUS register_driver(&tulip_ops); return 0; #else return tulip_probe(NULL); #endif } void cleanup_module(void) { struct device *next_dev; #ifdef CARDBUS unregister_driver(&tulip_ops); #endif /* No need to check MOD_IN_USE, as sys_delete_module() checks. */ while (root_tulip_dev) { next_dev = ((struct tulip_private *)root_tulip_dev->priv)->next_module; unregister_netdev(root_tulip_dev); release_region(root_tulip_dev->base_addr, TULIP_TOTAL_SIZE); kfree(root_tulip_dev); root_tulip_dev = next_dev; } } #endif /* MODULE */ /* * Local variables: * SMP-compile-command: "gcc -D__SMP__ -DMODULE -D__KERNEL__ -I/usr/src/linux/net/inet -Wall -Wstrict-prototypes -O6 -c tulip.c `[ -f /usr/include/linux/modversions.h ] && echo -DMODVERSIONS`" * compile-command: "gcc -DMODULE -D__KERNEL__ -I/usr/src/linux/net/inet -Wall -Wstrict-prototypes -O6 -c tulip.c `[ -f /usr/include/linux/modversions.h ] && echo -DMODVERSIONS`" * c-indent-level: 4 * c-basic-offset: 4 * tab-width: 4 * End: */