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2622 2623 2624 2625 2626 2627 2628 2629 2630 2631 2632 2633 2634 2635 2636 2637 2638 2639 2640 2641 2642 2643 2644 2645 2646 2647 2648 2649 2650 2651 2652 2653 2654 2655 2656 2657 2658 2659 2660 2661 2662 2663 2664 2665 2666 2667 2668 2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679 2680 2681 2682 2683 2684 2685 2686 2687 2688 2689 2690 2691 2692 2693 2694 2695 2696 2697 2698 2699 2700 2701 2702 2703 | /* * sktr.c: A network driver for the SysKonnect Token Ring ISA/PCI Adapters. * * Written 1997 by Christoph Goos * * A fine result of the Linux Systems Network Architecture Project. * http://samba.anu.edu.au/linux-sna/ * * This software may be used and distributed according to the terms * of the GNU Public License, incorporated herein by reference. * * This device driver works with the following SysKonnect adapters: * - SysKonnect TR4/16(+) ISA (SK-4190) * - SysKonnect TR4/16(+) PCI (SK-4590) * - SysKonnect TR4/16 PCI (SK-4591) * * Sources: * - The hardware related parts of this driver are take from * the SysKonnect Token Ring driver for Windows NT. * - I used the IBM Token Ring driver 'ibmtr.c' as a base for this * driver, as well as the 'skeleton.c' driver by Donald Becker. * - Also various other drivers in the linux source tree were taken * as samples for some tasks. * * Maintainer(s): * JS Jay Schulist jschlst@samba.anu.edu.au * CG Christoph Goos cgoos@syskonnect.de * * Modification History: * 29-Aug-97 CG Created * 04-Apr-98 CG Fixed problems caused by tok_timer_check * 10-Apr-98 CG Fixed lockups at cable disconnection * 27-May-98 JS Formated to Linux Kernel Format * 31-May-98 JS Hacked in PCI support * 16-Jun-98 JS Modulized for multiple cards with one driver * * To do: * 1. Selectable 16 Mbps or 4Mbps * 2. Multi/Broadcast packet handling * */ static const char *version = "sktr.c: v1.01 08/29/97 by Christoph Goos\n"; #ifdef MODULE #include <linux/module.h> #include <linux/version.h> #endif #include <linux/kernel.h> #include <linux/sched.h> #include <linux/types.h> #include <linux/fcntl.h> #include <linux/interrupt.h> #include <linux/ptrace.h> #include <linux/ioport.h> #include <linux/in.h> #include <linux/malloc.h> #include <linux/string.h> #include <linux/time.h> #include <asm/system.h> #include <asm/bitops.h> #include <asm/io.h> #include <asm/dma.h> #include <asm/irq.h> #include <linux/errno.h> #include <linux/init.h> #include <linux/pci.h> #include <linux/netdevice.h> #include <linux/etherdevice.h> #include <linux/skbuff.h> #include <linux/trdevice.h> #include "sktr.h" /* Our Stuff */ #include "sktr_firmware.h" /* SysKonnect adapter firmware */ /* A zero-terminated list of I/O addresses to be probed. */ static unsigned int sktr_portlist[] __initdata = { 0x0A20, 0x1A20, 0x0B20, 0x1B20, 0x0980, 0x1980, 0x0900, 0x1900, 0 }; /* A zero-terminated list of IRQs to be probed. * Used again after initial probe for sktr_chipset_init, called from sktr_open. */ static unsigned short sktr_irqlist[] = { 3, 5, 9, 10, 11, 12, 15, 0 }; /* A zero-terminated list of DMAs to be probed. */ static int sktr_dmalist[] __initdata = { 5, 6, 7, 0 }; /* Card names */ static char *pci_cardname = "SK NET TR 4/16 PCI\0"; static char *isa_cardname = "SK NET TR 4/16 ISA\0"; static char *AdapterName; /* Use 0 for production, 1 for verification, 2 for debug, and * 3 for very verbose debug. */ #ifndef SKTR_DEBUG #define SKTR_DEBUG 1 #endif static unsigned int sktr_debug = SKTR_DEBUG; /* The number of low I/O ports used by the tokencard. */ #define SKTR_IO_EXTENT 32 /* Index to functions, as function prototypes. * Alphabetical by function name. */ /* "B" */ static int sktr_bringup_diags(struct device *dev); /* "C" */ static void sktr_cancel_tx_queue(struct net_local* tp); static int sktr_chipset_init(struct device *dev); static void sktr_chk_irq(struct device *dev); static unsigned char sktr_chk_frame(struct device *dev, unsigned char *Addr); static void sktr_chk_outstanding_cmds(struct device *dev); static void sktr_chk_src_addr(unsigned char *frame, unsigned char *hw_addr); static unsigned char sktr_chk_ssb(struct net_local *tp, unsigned short IrqType); static int sktr_close(struct device *dev); static void sktr_cmd_status_irq(struct device *dev); /* "D" */ static void sktr_disable_interrupts(struct device *dev); static void sktr_dump(unsigned char *Data, int length); /* "E" */ static void sktr_enable_interrupts(struct device *dev); static void sktr_exec_cmd(struct device *dev, unsigned short Command); static void sktr_exec_sifcmd(struct device *dev, unsigned int WriteValue); /* "F" */ static unsigned char *sktr_fix_srouting(unsigned char *buf, short *FrameLen); /* "G" */ static struct enet_statistics *sktr_get_stats(struct device *dev); /* "H" */ static void sktr_hardware_send_packet(struct device *dev, struct net_local* tp); /* "I" */ static int sktr_init_adapter(struct device *dev); static int sktr_init_card(struct device *dev); static void sktr_init_ipb(struct net_local *tp); static void sktr_init_net_local(struct device *dev); static void sktr_init_opb(struct net_local *tp); static void sktr_interrupt(int irq, void *dev_id, struct pt_regs *regs); static int sktr_isa_chk_card(struct device *dev, int ioaddr); static int sktr_isa_chk_ioaddr(int ioaddr); /* "O" */ static int sktr_open(struct device *dev); static void sktr_open_adapter(struct device *dev); /* "P" */ static int sktr_pci_chk_card(struct device *dev); int sktr_probe(struct device *dev); static int sktr_probe1(struct device *dev, int ioaddr); /* "R" */ static void sktr_rcv_status_irq(struct device *dev); static void sktr_read_addr(struct device *dev, unsigned char *Address); static void sktr_read_ptr(struct device *dev); static void sktr_read_ram(struct device *dev, unsigned char *Data, unsigned short Address, int Length); static int sktr_reset_adapter(struct device *dev); static void sktr_reset_interrupt(struct device *dev); static void sktr_ring_status_irq(struct device *dev); /* "S" */ static int sktr_send_packet(struct sk_buff *skb, struct device *dev); static void sktr_set_multicast_list(struct device *dev); /* "T" */ static void sktr_timer_chk(unsigned long data); static void sktr_timer_end_wait(unsigned long data); static void sktr_tx_status_irq(struct device *dev); /* "U" */ static void sktr_update_rcv_stats(struct net_local *tp, unsigned char DataPtr[], unsigned int Length); /* "W" */ static void sktr_wait(unsigned long time); static void sktr_write_rpl_status(RPL *rpl, unsigned int Status); static void sktr_write_tpl_status(TPL *tpl, unsigned int Status); /* * Check for a network adapter of this type, and return '0' if one exists. * If dev->base_addr == 0, probe all likely locations. * If dev->base_addr == 1, always return failure. */ __initfunc(int sktr_probe(struct device *dev)) { int i; int base_addr = dev ? dev->base_addr : 0; if(base_addr > 0x1ff) /* Check a single specified location. */ return (sktr_probe1(dev, base_addr)); else if(base_addr != 0) /* Don't probe at all. */ return (-ENXIO); for(i = 0; sktr_portlist[i]; i++) { int ioaddr = sktr_portlist[i]; if(check_region(ioaddr, SKTR_IO_EXTENT)) continue; if(sktr_probe1(dev, ioaddr)) { #ifndef MODULE tr_freedev(dev); #endif } else return (0); } return (-ENODEV); } /* * Detect and setup the PCI SysKonnect TR cards in slot order. */ __initfunc(static int sktr_pci_chk_card(struct device *dev)) { static int pci_index = 0; unsigned char pci_bus, pci_device_fn; if(!pci_present()) return (-1); /* No PCI present. */ for(; pci_index < 0xff; pci_index++) { unsigned int pci_irq_line; struct pci_dev *pdev; unsigned short pci_command, new_command, vendor, device; unsigned int pci_ioaddr; if(pcibios_find_class(PCI_CLASS_NETWORK_TOKEN_RING << 8, pci_index, &pci_bus, &pci_device_fn) != PCIBIOS_SUCCESSFUL) { 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); pdev = pci_find_slot(pci_bus, pci_device_fn); pci_irq_line = pdev->irq; pci_ioaddr = pdev->base_address[0]; pcibios_read_config_word(pci_bus, pci_device_fn, PCI_COMMAND, &pci_command); /* Remove I/O space marker in bit 0. */ pci_ioaddr &= ~3; if(vendor != PCI_VENDOR_ID_SK) continue; if(device != PCI_DEVICE_ID_SK_TR) continue; if(check_region(pci_ioaddr, SKTR_IO_EXTENT)) continue; request_region(pci_ioaddr, SKTR_IO_EXTENT, pci_cardname); if(request_irq(pdev->irq, sktr_interrupt, SA_SHIRQ, pci_cardname, dev)) return (-ENODEV); /* continue; ?? */ AdapterName = pci_cardname; new_command = (pci_command|PCI_COMMAND_MASTER|PCI_COMMAND_IO); if(pci_command != new_command) { printk("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); } /* At this point we have found a valid PCI TR card. */ dev->base_addr = pci_ioaddr; dev->irq = pci_irq_line; dev->dma = 0; printk("%s: %s found at %#4x, using IRQ %d.\n", dev->name, AdapterName, pci_ioaddr, dev->irq); return (0); } return (-1); } /* * Detect and setup the ISA SysKonnect TR cards. */ __initfunc(static int sktr_isa_chk_card(struct device *dev, int ioaddr)) { int i, err; unsigned long flags; err = sktr_isa_chk_ioaddr(ioaddr); if(err < 0) return (-ENODEV); if(virt_to_bus((void*)((unsigned long)dev->priv+sizeof(struct net_local))) > ISA_MAX_ADDRESS) { printk("%s: Memory not accessible for DMA\n", dev->name); kfree(dev->priv); return (-EAGAIN); } AdapterName = isa_cardname; /* Grab the region so that no one else tries to probe our ioports. */ request_region(ioaddr, SKTR_IO_EXTENT, AdapterName); dev->base_addr = ioaddr; /* Autoselect IRQ and DMA if dev->irq == 0 */ if(dev->irq == 0) { for(i = 0; sktr_irqlist[i] != 0; i++) { dev->irq = sktr_irqlist[i]; err = request_irq(dev->irq, &sktr_interrupt, 0, AdapterName, dev); if(!err) break; } if(sktr_irqlist[i] == 0) { printk("%s: AutoSelect no IRQ available\n", dev->name); return (-EAGAIN); } } else { err = request_irq(dev->irq, &sktr_interrupt, 0, AdapterName, dev); if(err) { printk("%s: Selected IRQ not available\n", dev->name); return (-EAGAIN); } } /* Always allocate the DMA channel after IRQ and clean up on failure */ if(dev->dma == 0) { for(i = 0; sktr_dmalist[i] != 0; i++) { dev->dma = sktr_dmalist[i]; err = request_dma(dev->dma, AdapterName); if(!err) break; } if(dev->dma == 0) { printk("%s: AutoSelect no DMA available\n", dev->name); free_irq(dev->irq, NULL); return (-EAGAIN); } } else { err = request_dma(dev->dma, AdapterName); if(err) { printk("%s: Selected DMA not available\n", dev->name); free_irq(dev->irq, NULL); return (-EAGAIN); } } flags=claim_dma_lock(); disable_dma(dev->dma); set_dma_mode(dev->dma, DMA_MODE_CASCADE); enable_dma(dev->dma); release_dma_lock(flags); printk("%s: %s found at %#4x, using IRQ %d and DMA %d.\n", dev->name, AdapterName, ioaddr, dev->irq, dev->dma); return (0); } __initfunc(static int sktr_probe1(struct device *dev, int ioaddr)) { static unsigned version_printed = 0; struct net_local *tp; int err; if(sktr_debug && version_printed++ == 0) printk("%s", version); #ifndef MODULE dev = init_trdev(dev, 0); if(dev == NULL) return (-ENOMEM); #endif err = sktr_pci_chk_card(dev); if(err < 0) { err = sktr_isa_chk_card(dev, ioaddr); if(err < 0) return (-ENODEV); } /* Setup this devices private information structure */ tp = (struct net_local *)kmalloc(sizeof(struct net_local), GFP_KERNEL | GFP_DMA); if(tp == NULL) return (-ENOMEM); memset(tp, 0, sizeof(struct net_local)); init_waitqueue_head(&tp->wait_for_tok_int); dev->priv = tp; dev->init = sktr_init_card; dev->open = sktr_open; dev->stop = sktr_close; dev->hard_start_xmit = sktr_send_packet; dev->get_stats = sktr_get_stats; dev->set_multicast_list = &sktr_set_multicast_list; return (0); } /* Dummy function */ __initfunc(static int sktr_init_card(struct device *dev)) { if(sktr_debug > 3) printk("%s: sktr_init_card\n", dev->name); return (0); } /* * This function tests if an adapter is really installed at the * given I/O address. Return negative if no adapter at IO addr. */ __initfunc(static int sktr_isa_chk_ioaddr(int ioaddr)) { unsigned char old, chk1, chk2; old = inb(ioaddr + SIFADR); /* Get the old SIFADR value */ chk1 = 0; /* Begin with check value 0 */ do { /* Write new SIFADR value */ outb(chk1, ioaddr + SIFADR); /* Read, invert and write */ chk2 = inb(ioaddr + SIFADD); chk2 ^= 0x0FE; outb(chk2, ioaddr + SIFADR); /* Read, invert and compare */ chk2 = inb(ioaddr + SIFADD); chk2 ^= 0x0FE; if(chk1 != chk2) return (-1); /* No adapter */ chk1 -= 2; } while(chk1 != 0); /* Repeat 128 times (all byte values) */ /* Restore the SIFADR value */ outb(old, ioaddr + SIFADR); return (0); } /* * Open/initialize the board. This is called sometime after * booting when the 'ifconfig' program is run. * * This routine should set everything up anew at each open, even * registers that "should" only need to be set once at boot, so that * there is non-reboot way to recover if something goes wrong. */ static int sktr_open(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; int err; /* Reset the hardware here. Don't forget to set the station address. */ err = sktr_chipset_init(dev); if(err) { printk(KERN_INFO "%s: Chipset initialization error\n", dev->name); return (-1); } dev->addr_len = 6; sktr_read_addr(dev, (unsigned char*)dev->dev_addr); init_timer(&tp->timer); tp->timer.expires = jiffies + 30*HZ; tp->timer.function = sktr_timer_end_wait; tp->timer.data = (unsigned long)dev; tp->timer.next = NULL; tp->timer.prev = NULL; add_timer(&tp->timer); sktr_read_ptr(dev); sktr_enable_interrupts(dev); sktr_open_adapter(dev); dev->tbusy = 0; dev->interrupt = 0; dev->start = 0; /* Wait for interrupt from hardware. If interrupt does not come, * there will be a timeout from the timer. */ tp->Sleeping = 1; interruptible_sleep_on(&tp->wait_for_tok_int); del_timer(&tp->timer); /* If AdapterVirtOpenFlag is 1, the adapter is now open for use */ if(tp->AdapterVirtOpenFlag == 0) { sktr_disable_interrupts(dev); return (-1); } dev->start = 1; tp->StartTime = jiffies; /* Start function control timer */ tp->timer.expires = jiffies + 2*HZ; tp->timer.function = sktr_timer_chk; tp->timer.data = (unsigned long)dev; add_timer(&tp->timer); #ifdef MODULE MOD_INC_USE_COUNT; #endif return (0); } /* * Timeout function while waiting for event */ static void sktr_timer_end_wait(unsigned long data) { struct device *dev = (struct device*)data; struct net_local *tp = (struct net_local *)dev->priv; if(tp->Sleeping) { tp->Sleeping = 0; wake_up_interruptible(&tp->wait_for_tok_int); } return; } /* * Initialize the chipset */ static int sktr_chipset_init(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned char PosReg, Tmp; int i, err; sktr_init_ipb(tp); sktr_init_opb(tp); sktr_init_net_local(dev); /* Set pos register: selects irq and dma channel. * Only for ISA bus adapters. */ if(dev->dma > 0) { PosReg = 0; for(i = 0; sktr_irqlist[i] != 0; i++) { if(sktr_irqlist[i] == dev->irq) break; } /* Choose default cycle time, 500 nsec */ PosReg |= CYCLE_TIME << 2; PosReg |= i << 4; i = dev->dma - 5; PosReg |= i; if(tp->DataRate == SPEED_4) PosReg |= LINE_SPEED_BIT; else PosReg &= ~LINE_SPEED_BIT; outb(PosReg, dev->base_addr + POSREG); Tmp = inb(dev->base_addr + POSREG); if((Tmp & ~CYCLE_TIME) != (PosReg & ~CYCLE_TIME)) printk(KERN_INFO "%s: POSREG error\n", dev->name); } err = sktr_reset_adapter(dev); if(err < 0) return (-1); err = sktr_bringup_diags(dev); if(err < 0) return (-1); err = sktr_init_adapter(dev); if(err < 0) return (-1); return (0); } /* * Initializes the net_local structure. */ static void sktr_init_net_local(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; int i; tp->scb.CMD = 0; tp->scb.Parm[0] = 0; tp->scb.Parm[1] = 0; tp->ssb.STS = 0; tp->ssb.Parm[0] = 0; tp->ssb.Parm[1] = 0; tp->ssb.Parm[2] = 0; tp->CMDqueue = 0; tp->AdapterOpenFlag = 0; tp->AdapterVirtOpenFlag = 0; tp->ScbInUse = 0; tp->OpenCommandIssued = 0; tp->ReOpenInProgress = 0; tp->HaltInProgress = 0; tp->TransmitHaltScheduled = 0; tp->LobeWireFaultLogged = 0; tp->LastOpenStatus = 0; tp->MaxPacketSize = DEFAULT_PACKET_SIZE; skb_queue_head_init(&tp->SendSkbQueue); tp->QueueSkb = MAX_TX_QUEUE; /* Create circular chain of transmit lists */ for (i = 0; i < TPL_NUM; i++) { tp->Tpl[i].NextTPLAddr = htonl((unsigned long) virt_to_bus(&tp->Tpl[(i+1) % TPL_NUM])); tp->Tpl[i].Status = 0; tp->Tpl[i].FrameSize = 0; tp->Tpl[i].FragList[0].DataCount = 0; tp->Tpl[i].FragList[0].DataAddr = 0; tp->Tpl[i].NextTPLPtr = &tp->Tpl[(i+1) % TPL_NUM]; tp->Tpl[i].MData = NULL; tp->Tpl[i].TPLIndex = i; tp->Tpl[i].BusyFlag = 0; } tp->TplFree = tp->TplBusy = &tp->Tpl[0]; /* Create circular chain of receive lists */ for (i = 0; i < RPL_NUM; i++) { tp->Rpl[i].NextRPLAddr = htonl((unsigned long) virt_to_bus(&tp->Rpl[(i+1) % RPL_NUM])); tp->Rpl[i].Status = (RX_VALID | RX_START_FRAME | RX_END_FRAME | RX_FRAME_IRQ); tp->Rpl[i].FrameSize = 0; tp->Rpl[i].FragList[0].DataCount = SWAPB(tp->MaxPacketSize); /* Alloc skb and point adapter to data area */ tp->Rpl[i].Skb = dev_alloc_skb(tp->MaxPacketSize); /* skb == NULL ? then use local buffer */ if(tp->Rpl[i].Skb == NULL) { tp->Rpl[i].SkbStat = SKB_UNAVAILABLE; tp->Rpl[i].FragList[0].DataAddr = htonl(virt_to_bus(tp->LocalRxBuffers[i])); tp->Rpl[i].MData = tp->LocalRxBuffers[i]; } else /* SKB != NULL */ { tp->Rpl[i].Skb->dev = dev; skb_put(tp->Rpl[i].Skb, tp->MaxPacketSize); /* data unreachable for DMA ? then use local buffer */ if(virt_to_bus(tp->Rpl[i].Skb->data) + tp->MaxPacketSize > ISA_MAX_ADDRESS) { tp->Rpl[i].SkbStat = SKB_DATA_COPY; tp->Rpl[i].FragList[0].DataAddr = htonl(virt_to_bus(tp->LocalRxBuffers[i])); tp->Rpl[i].MData = tp->LocalRxBuffers[i]; } else /* DMA directly in skb->data */ { tp->Rpl[i].SkbStat = SKB_DMA_DIRECT; tp->Rpl[i].FragList[0].DataAddr = htonl(virt_to_bus(tp->Rpl[i].Skb->data)); tp->Rpl[i].MData = tp->Rpl[i].Skb->data; } } tp->Rpl[i].NextRPLPtr = &tp->Rpl[(i+1) % RPL_NUM]; tp->Rpl[i].RPLIndex = i; } tp->RplHead = &tp->Rpl[0]; tp->RplTail = &tp->Rpl[RPL_NUM-1]; tp->RplTail->Status = (RX_START_FRAME | RX_END_FRAME | RX_FRAME_IRQ); return; } /* * Initializes the initialisation parameter block. */ static void sktr_init_ipb(struct net_local *tp) { tp->ipb.Init_Options = BURST_MODE; tp->ipb.CMD_Status_IV = 0; tp->ipb.TX_IV = 0; tp->ipb.RX_IV = 0; tp->ipb.Ring_Status_IV = 0; tp->ipb.SCB_Clear_IV = 0; tp->ipb.Adapter_CHK_IV = 0; tp->ipb.RX_Burst_Size = BURST_SIZE; tp->ipb.TX_Burst_Size = BURST_SIZE; tp->ipb.DMA_Abort_Thrhld = DMA_RETRIES; tp->ipb.SCB_Addr = 0; tp->ipb.SSB_Addr = 0; return; } /* * Initializes the open parameter block. */ static void sktr_init_opb(struct net_local *tp) { unsigned long Addr; unsigned short RplSize = RPL_SIZE; unsigned short TplSize = TPL_SIZE; unsigned short BufferSize = BUFFER_SIZE; tp->ocpl.OPENOptions = 0; tp->ocpl.OPENOptions |= ENABLE_FULL_DUPLEX_SELECTION; tp->ocpl.OPENOptions |= PAD_ROUTING_FIELD; tp->ocpl.FullDuplex = 0; tp->ocpl.FullDuplex |= OPEN_FULL_DUPLEX_OFF; /* Fixme: If mac address setable: * for (i=0; i<LENGTH_OF_ADDRESS; i++) * mac->Vam->ocpl.NodeAddr[i] = mac->CurrentAddress[i]; */ tp->ocpl.GroupAddr = 0; tp->ocpl.FunctAddr = 0; tp->ocpl.RxListSize = SWAPB(RplSize); tp->ocpl.TxListSize = SWAPB(TplSize); tp->ocpl.BufSize = SWAPB(BufferSize); tp->ocpl.Reserved = 0; tp->ocpl.TXBufMin = TX_BUF_MIN; tp->ocpl.TXBufMax = TX_BUF_MAX; Addr = htonl(virt_to_bus(tp->ProductID)); tp->ocpl.ProdIDAddr[0] = LOWORD(Addr); tp->ocpl.ProdIDAddr[1] = HIWORD(Addr); return; } /* * Send OPEN command to adapter */ static void sktr_open_adapter(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; if(tp->OpenCommandIssued) return; tp->OpenCommandIssued = 1; sktr_exec_cmd(dev, OC_OPEN); return; } /* * Clear the adapter's interrupt flag. Clear system interrupt enable * (SINTEN): disable adapter to system interrupts. */ static void sktr_disable_interrupts(struct device *dev) { outb(0, dev->base_addr + SIFACL); return; } /* * Set the adapter's interrupt flag. Set system interrupt enable * (SINTEN): enable adapter to system interrupts. */ static void sktr_enable_interrupts(struct device *dev) { outb(ACL_SINTEN, dev->base_addr + SIFACL); return; } /* * Put command in command queue, try to execute it. */ static void sktr_exec_cmd(struct device *dev, unsigned short Command) { struct net_local *tp = (struct net_local *)dev->priv; tp->CMDqueue |= Command; sktr_chk_outstanding_cmds(dev); return; } /* * Linux always gives 18 byte of source routing information in the frame header. * But the length field can indicate shorter length. Then cut header * appropriate. */ static unsigned char *sktr_fix_srouting(unsigned char *buf, short *FrameLen) { struct trh_hdr *trh = (struct trh_hdr *)buf; int len; if(buf[8] & TR_RII) { trh->rcf &= ~SWAPB((unsigned short) TR_RCF_LONGEST_FRAME_MASK); trh->rcf |= SWAPB((unsigned short) TR_RCF_FRAME4K); len = (SWAPB(trh->rcf) & TR_RCF_LEN_MASK) >> 8; if(len < 18) { memcpy(&buf[18-len],buf,sizeof(struct trh_hdr)-18+len); *FrameLen -= (18 - len); } return (&buf[18-len]); } return (buf); } /* * Gets skb from system, queues it and checks if it can be sent */ static int sktr_send_packet(struct sk_buff *skb, struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; if(dev->tbusy) { /* * If we get here, some higher level has decided we are broken. * There should really be a "kick me" function call instead. * * Resetting the token ring adapter takes a long time so just * fake transmission time and go on trying. Our own timeout * routine is in sktr_timer_chk() */ dev->tbusy = 0; dev->trans_start = jiffies; return (1); } /* * If some higher layer thinks we've missed an tx-done interrupt we * are passed NULL. */ if(skb == NULL) return (0); /* * 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) { printk("%s: Transmitter access conflict.\n", dev->name); return (1); } if(tp->QueueSkb == 0) return (1); /* Return with tbusy set: queue full */ tp->QueueSkb--; skb_queue_tail(&tp->SendSkbQueue, skb); sktr_hardware_send_packet(dev, tp); if(tp->QueueSkb > 0) dev->tbusy = 0; return (0); } /* * Move frames from internal skb queue into adapter tx queue */ static void sktr_hardware_send_packet(struct device *dev, struct net_local* tp) { TPL *tpl; short length; unsigned char *buf, *newbuf; struct sk_buff *skb; int i; for(;;) { /* Try to get a free TPL from the chain. * * NOTE: We *must* always leave one unused TPL in the chain, * because otherwise the adapter might send frames twice. */ if(tp->TplFree->NextTPLPtr->BusyFlag) /* No free TPL */ { printk(KERN_INFO "%s: No free TPL\n", dev->name); return; } /* Send first buffer from queue */ skb = skb_dequeue(&tp->SendSkbQueue); if(skb == NULL) return; tp->QueueSkb++; /* Is buffer reachable for Busmaster-DMA? */ if(virt_to_bus((void*)(((long) skb->data) + skb->len)) > ISA_MAX_ADDRESS) { /* Copy frame to local buffer */ i = tp->TplFree->TPLIndex; length = skb->len; buf = tp->LocalTxBuffers[i]; memcpy(buf, skb->data, length); newbuf = sktr_fix_srouting(buf, &length); } else { /* Send direct from skb->data */ length = skb->len; newbuf = sktr_fix_srouting(skb->data, &length); } /* Source address in packet? */ sktr_chk_src_addr(newbuf, dev->dev_addr); tp->LastSendTime = jiffies; tpl = tp->TplFree; /* Get the "free" TPL */ tpl->BusyFlag = 1; /* Mark TPL as busy */ tp->TplFree = tpl->NextTPLPtr; /* Save the skb for delayed return of skb to system */ tpl->Skb = skb; tpl->FragList[0].DataCount = (unsigned short) SWAPB(length); tpl->FragList[0].DataAddr = htonl(virt_to_bus(newbuf)); /* Write the data length in the transmit list. */ tpl->FrameSize = (unsigned short) SWAPB(length); tpl->MData = newbuf; /* Transmit the frame and set the status values. */ sktr_write_tpl_status(tpl, TX_VALID | TX_START_FRAME | TX_END_FRAME | TX_PASS_SRC_ADDR | TX_FRAME_IRQ); /* Let adapter send the frame. */ sktr_exec_sifcmd(dev, CMD_TX_VALID); } return; } /* * Write the given value to the 'Status' field of the specified TPL. * NOTE: This function should be used whenever the status of any TPL must be * modified by the driver, because the compiler may otherwise change the * order of instructions such that writing the TPL status may be executed at * an undesireable time. When this function is used, the status is always * written when the function is called. */ static void sktr_write_tpl_status(TPL *tpl, unsigned int Status) { tpl->Status = Status; } static void sktr_chk_src_addr(unsigned char *frame, unsigned char *hw_addr) { unsigned char SRBit; if((((unsigned long)frame[8]) & ~0x80) != 0) /* Compare 4 bytes */ return; if((unsigned short)frame[12] != 0) /* Compare 2 bytes */ return; SRBit = frame[8] & 0x80; memcpy(&frame[8], hw_addr, 6); frame[8] |= SRBit; return; } /* * The timer routine: Check if adapter still open and working, reopen if not. */ static void sktr_timer_chk(unsigned long data) { struct device *dev = (struct device*)data; struct net_local *tp = (struct net_local*)dev->priv; if(tp->HaltInProgress) return; sktr_chk_outstanding_cmds(dev); if(time_before(tp->LastSendTime + SEND_TIMEOUT, jiffies) && (tp->QueueSkb < MAX_TX_QUEUE || tp->TplFree != tp->TplBusy)) { /* Anything to send, but stalled to long */ tp->LastSendTime = jiffies; sktr_exec_cmd(dev, OC_CLOSE); /* Does reopen automatically */ } tp->timer.expires = jiffies + 2*HZ; add_timer(&tp->timer); if(tp->AdapterOpenFlag || tp->ReOpenInProgress) return; tp->ReOpenInProgress = 1; sktr_open_adapter(dev); return; } /* * The typical workload of the driver: Handle the network interface interrupts. */ static void sktr_interrupt(int irq, void *dev_id, struct pt_regs *regs) { struct device *dev = dev_id; struct net_local *tp; int ioaddr; unsigned short irq_type; if(dev == NULL) { printk("%s: irq %d for unknown device.\n", dev->name, irq); return; } dev->interrupt = 1; ioaddr = dev->base_addr; tp = (struct net_local *)dev->priv; irq_type = inw(ioaddr + SIFSTS); while(irq_type & STS_SYSTEM_IRQ) { irq_type &= STS_IRQ_MASK; if(!sktr_chk_ssb(tp, irq_type)) { printk(KERN_INFO "%s: DATA LATE occurred\n", dev->name); break; } switch(irq_type) { case STS_IRQ_RECEIVE_STATUS: sktr_reset_interrupt(dev); sktr_rcv_status_irq(dev); break; case STS_IRQ_TRANSMIT_STATUS: /* Check if TRANSMIT.HALT command is complete */ if(tp->ssb.Parm[0] & COMMAND_COMPLETE) { tp->TransmitCommandActive = 0; tp->TransmitHaltScheduled = 0; /* Issue a new transmit command. */ sktr_exec_cmd(dev, OC_TRANSMIT); } sktr_reset_interrupt(dev); sktr_tx_status_irq(dev); break; case STS_IRQ_COMMAND_STATUS: /* The SSB contains status of last command * other than receive/transmit. */ sktr_cmd_status_irq(dev); break; case STS_IRQ_SCB_CLEAR: /* The SCB is free for another command. */ tp->ScbInUse = 0; sktr_chk_outstanding_cmds(dev); break; case STS_IRQ_RING_STATUS: sktr_ring_status_irq(dev); break; case STS_IRQ_ADAPTER_CHECK: sktr_chk_irq(dev); break; default: printk(KERN_INFO "Unknown Token Ring IRQ\n"); break; } /* Reset system interrupt if not already done. */ if(irq_type != STS_IRQ_TRANSMIT_STATUS && irq_type != STS_IRQ_RECEIVE_STATUS) { sktr_reset_interrupt(dev); } irq_type = inw(ioaddr + SIFSTS); } dev->interrupt = 0; return; } /* * Reset the INTERRUPT SYSTEM bit and issue SSB CLEAR command. */ static void sktr_reset_interrupt(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; SSB *ssb = &tp->ssb; /* * [Workaround for "Data Late"] * Set all fields of the SSB to well-defined values so we can * check if the adapter has written the SSB. */ ssb->STS = (unsigned short) -1; ssb->Parm[0] = (unsigned short) -1; ssb->Parm[1] = (unsigned short) -1; ssb->Parm[2] = (unsigned short) -1; /* Free SSB by issuing SSB_CLEAR command after reading IRQ code * and clear STS_SYSTEM_IRQ bit: enable adapter for further interrupts. */ sktr_exec_sifcmd(dev, CMD_SSB_CLEAR | CMD_CLEAR_SYSTEM_IRQ); return; } /* * Check if the SSB has actually been written by the adapter. */ static unsigned char sktr_chk_ssb(struct net_local *tp, unsigned short IrqType) { SSB *ssb = &tp->ssb; /* The address of the SSB. */ /* C 0 1 2 INTERRUPT CODE * - - - - -------------- * 1 1 1 1 TRANSMIT STATUS * 1 1 1 1 RECEIVE STATUS * 1 ? ? 0 COMMAND STATUS * 0 0 0 0 SCB CLEAR * 1 1 0 0 RING STATUS * 0 0 0 0 ADAPTER CHECK * * 0 = SSB field not affected by interrupt * 1 = SSB field is affected by interrupt * * C = SSB ADDRESS +0: COMMAND * 0 = SSB ADDRESS +2: STATUS 0 * 1 = SSB ADDRESS +4: STATUS 1 * 2 = SSB ADDRESS +6: STATUS 2 */ /* Check if this interrupt does use the SSB. */ if(IrqType != STS_IRQ_TRANSMIT_STATUS && IrqType != STS_IRQ_RECEIVE_STATUS && IrqType != STS_IRQ_COMMAND_STATUS && IrqType != STS_IRQ_RING_STATUS) { return (1); /* SSB not involved. */ } /* Note: All fields of the SSB have been set to all ones (-1) after it * has last been used by the software (see DriverIsr()). * * Check if the affected SSB fields are still unchanged. */ if(ssb->STS == (unsigned short) -1) return (0); /* Command field not yet available. */ if(IrqType == STS_IRQ_COMMAND_STATUS) return (1); /* Status fields not always affected. */ if(ssb->Parm[0] == (unsigned short) -1) return (0); /* Status 1 field not yet available. */ if(IrqType == STS_IRQ_RING_STATUS) return (1); /* Status 2 & 3 fields not affected. */ /* Note: At this point, the interrupt is either TRANSMIT or RECEIVE. */ if(ssb->Parm[1] == (unsigned short) -1) return (0); /* Status 2 field not yet available. */ if(ssb->Parm[2] == (unsigned short) -1) return (0); /* Status 3 field not yet available. */ return (1); /* All SSB fields have been written by the adapter. */ } /* * Evaluates the command results status in the SSB status field. */ static void sktr_cmd_status_irq(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned short ssb_cmd, ssb_parm_0; unsigned short ssb_parm_1; char *open_err = "Open error -"; char *code_err = "Open code -"; /* Copy the ssb values to local variables */ ssb_cmd = tp->ssb.STS; ssb_parm_0 = tp->ssb.Parm[0]; ssb_parm_1 = tp->ssb.Parm[1]; if(ssb_cmd == OPEN) { tp->Sleeping = 0; if(!tp->ReOpenInProgress) wake_up_interruptible(&tp->wait_for_tok_int); tp->OpenCommandIssued = 0; tp->ScbInUse = 0; if((ssb_parm_0 & 0x00FF) == GOOD_COMPLETION) { /* Success, the adapter is open. */ tp->LobeWireFaultLogged = 0; tp->AdapterOpenFlag = 1; tp->AdapterVirtOpenFlag = 1; tp->TransmitCommandActive = 0; sktr_exec_cmd(dev, OC_TRANSMIT); sktr_exec_cmd(dev, OC_RECEIVE); if(tp->ReOpenInProgress) tp->ReOpenInProgress = 0; return; } else /* The adapter did not open. */ { if(ssb_parm_0 & NODE_ADDR_ERROR) printk(KERN_INFO "%s: Node address error\n", dev->name); if(ssb_parm_0 & LIST_SIZE_ERROR) printk(KERN_INFO "%s: List size error\n", dev->name); if(ssb_parm_0 & BUF_SIZE_ERROR) printk(KERN_INFO "%s: Buffer size error\n", dev->name); if(ssb_parm_0 & TX_BUF_COUNT_ERROR) printk(KERN_INFO "%s: Tx buffer count error\n", dev->name); if(ssb_parm_0 & INVALID_OPEN_OPTION) printk(KERN_INFO "%s: Invalid open option\n", dev->name); if(ssb_parm_0 & OPEN_ERROR) { /* Show the open phase. */ switch(ssb_parm_0 & OPEN_PHASES_MASK) { case LOBE_MEDIA_TEST: if(!tp->LobeWireFaultLogged) { tp->LobeWireFaultLogged = 1; printk(KERN_INFO "%s: %s Lobe wire fault (check cable !).\n", dev->name, open_err); } tp->ReOpenInProgress = 1; tp->AdapterOpenFlag = 0; tp->AdapterVirtOpenFlag = 1; sktr_open_adapter(dev); return; case PHYSICAL_INSERTION: printk(KERN_INFO "%s: %s Physical insertion.\n", dev->name, open_err); break; case ADDRESS_VERIFICATION: printk(KERN_INFO "%s: %s Address verification.\n", dev->name, open_err); break; case PARTICIPATION_IN_RING_POLL: printk(KERN_INFO "%s: %s Participation in ring poll.\n", dev->name, open_err); break; case REQUEST_INITIALISATION: printk(KERN_INFO "%s: %s Request initialisation.\n", dev->name, open_err); break; case FULLDUPLEX_CHECK: printk(KERN_INFO "%s: %s Full duplex check.\n", dev->name, open_err); break; default: printk(KERN_INFO "%s: %s Unknown open phase\n", dev->name, open_err); break; } /* Show the open errors. */ switch(ssb_parm_0 & OPEN_ERROR_CODES_MASK) { case OPEN_FUNCTION_FAILURE: printk(KERN_INFO "%s: %s OPEN_FUNCTION_FAILURE", dev->name, code_err); tp->LastOpenStatus = OPEN_FUNCTION_FAILURE; break; case OPEN_SIGNAL_LOSS: printk(KERN_INFO "%s: %s OPEN_SIGNAL_LOSS\n", dev->name, code_err); tp->LastOpenStatus = OPEN_SIGNAL_LOSS; break; case OPEN_TIMEOUT: printk(KERN_INFO "%s: %s OPEN_TIMEOUT\n", dev->name, code_err); tp->LastOpenStatus = OPEN_TIMEOUT; break; case OPEN_RING_FAILURE: printk(KERN_INFO "%s: %s OPEN_RING_FAILURE\n", dev->name, code_err); tp->LastOpenStatus = OPEN_RING_FAILURE; break; case OPEN_RING_BEACONING: printk(KERN_INFO "%s: %s OPEN_RING_BEACONING\n", dev->name, code_err); tp->LastOpenStatus = OPEN_RING_BEACONING; break; case OPEN_DUPLICATE_NODEADDR: printk(KERN_INFO "%s: %s OPEN_DUPLICATE_NODEADDR\n", dev->name, code_err); tp->LastOpenStatus = OPEN_DUPLICATE_NODEADDR; break; case OPEN_REQUEST_INIT: printk(KERN_INFO "%s: %s OPEN_REQUEST_INIT\n", dev->name, code_err); tp->LastOpenStatus = OPEN_REQUEST_INIT; break; case OPEN_REMOVE_RECEIVED: printk(KERN_INFO "%s: %s OPEN_REMOVE_RECEIVED", dev->name, code_err); tp->LastOpenStatus = OPEN_REMOVE_RECEIVED; break; case OPEN_FULLDUPLEX_SET: printk(KERN_INFO "%s: %s OPEN_FULLDUPLEX_SET\n", dev->name, code_err); tp->LastOpenStatus = OPEN_FULLDUPLEX_SET; break; default: printk(KERN_INFO "%s: %s Unknown open err code", dev->name, code_err); tp->LastOpenStatus = OPEN_FUNCTION_FAILURE; break; } } tp->AdapterOpenFlag = 0; tp->AdapterVirtOpenFlag = 0; return; } } else { if(ssb_cmd != READ_ERROR_LOG) return; /* Add values from the error log table to the MAC * statistics counters and update the errorlogtable * memory. */ tp->MacStat.line_errors += tp->errorlogtable.Line_Error; tp->MacStat.burst_errors += tp->errorlogtable.Burst_Error; tp->MacStat.A_C_errors += tp->errorlogtable.ARI_FCI_Error; tp->MacStat.lost_frames += tp->errorlogtable.Lost_Frame_Error; tp->MacStat.recv_congest_count += tp->errorlogtable.Rx_Congest_Error; tp->MacStat.rx_errors += tp->errorlogtable.Rx_Congest_Error; tp->MacStat.frame_copied_errors += tp->errorlogtable.Frame_Copied_Error; tp->MacStat.token_errors += tp->errorlogtable.Token_Error; tp->MacStat.dummy1 += tp->errorlogtable.DMA_Bus_Error; tp->MacStat.dummy1 += tp->errorlogtable.DMA_Parity_Error; tp->MacStat.abort_delimiters += tp->errorlogtable.AbortDelimeters; tp->MacStat.frequency_errors += tp->errorlogtable.Frequency_Error; tp->MacStat.internal_errors += tp->errorlogtable.Internal_Error; } return; } /* * The inverse routine to sktr_open(). */ static int sktr_close(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; dev->tbusy = 1; dev->start = 0; del_timer(&tp->timer); /* Flush the Tx and disable Rx here. */ tp->HaltInProgress = 1; sktr_exec_cmd(dev, OC_CLOSE); tp->timer.expires = jiffies + 1*HZ; tp->timer.function = sktr_timer_end_wait; tp->timer.data = (unsigned long)dev; add_timer(&tp->timer); sktr_enable_interrupts(dev); tp->Sleeping = 1; interruptible_sleep_on(&tp->wait_for_tok_int); tp->TransmitCommandActive = 0; del_timer(&tp->timer); sktr_disable_interrupts(dev); if(dev->dma > 0) { unsigned long flags=claim_dma_lock(); disable_dma(dev->dma); release_dma_lock(flags); } outw(0xFF00, dev->base_addr + SIFCMD); if(dev->dma > 0) outb(0xff, dev->base_addr + POSREG); #ifdef MODULE MOD_DEC_USE_COUNT; #endif sktr_cancel_tx_queue(tp); return (0); } /* * Get the current statistics. This may be called with the card open * or closed. */ static struct enet_statistics *sktr_get_stats(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; return ((struct enet_statistics *)&tp->MacStat); } /* * Set or clear the multicast filter for this adapter. */ static void sktr_set_multicast_list(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned int OpenOptions; OpenOptions = tp->ocpl.OPENOptions & ~(PASS_ADAPTER_MAC_FRAMES | PASS_ATTENTION_FRAMES | PASS_BEACON_MAC_FRAMES | COPY_ALL_MAC_FRAMES | COPY_ALL_NON_MAC_FRAMES); if(dev->flags & IFF_PROMISC) /* Enable promiscuous mode */ OpenOptions |= COPY_ALL_NON_MAC_FRAMES | COPY_ALL_MAC_FRAMES; else { if(dev->flags & IFF_ALLMULTI) /* || dev->mc_count > HW_MAX_ADDRS) */ { /* Disable promiscuous mode, use normal mode. */ } else { if(dev->mc_count) { /* Walk the address list, and load the filter */ } } } tp->ocpl.OPENOptions = OpenOptions; sktr_exec_cmd(dev, OC_MODIFY_OPEN_PARMS); return; } /* * Wait for some time (microseconds) */ static void sktr_wait(unsigned long time) { long tmp; tmp = jiffies + time/(1000000/HZ); do { current->state = TASK_INTERRUPTIBLE; tmp = schedule_timeout(tmp); } while(time_after(tmp, jiffies)); return; } /* * Write a command value to the SIFCMD register */ static void sktr_exec_sifcmd(struct device *dev, unsigned int WriteValue) { int ioaddr = dev->base_addr; unsigned short cmd; unsigned short SifStsValue; unsigned long loop_counter; WriteValue = ((WriteValue ^ CMD_SYSTEM_IRQ) | CMD_INTERRUPT_ADAPTER); cmd = (unsigned short)WriteValue; loop_counter = 0,5 * 800000; do { SifStsValue = inw(ioaddr + SIFSTS); } while((SifStsValue & CMD_INTERRUPT_ADAPTER) && loop_counter--); outw(cmd, ioaddr + SIFCMD); return; } /* * Processes adapter hardware reset, halts adapter and downloads firmware, * clears the halt bit. */ static int sktr_reset_adapter(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned short *fw_ptr = (unsigned short *)&sktr_code; unsigned short count, c; int ioaddr = dev->base_addr; /* Hardware adapter reset */ outw(ACL_ARESET, ioaddr + SIFACL); sktr_wait(40); c = inw(ioaddr + SIFACL); sktr_wait(20); if(dev->dma == 0) /* For PCI adapters */ { c &= ~(ACL_SPEED4 | ACL_SPEED16); /* Clear bits */ if(tp->DataRate == SPEED_4) c |= ACL_SPEED4; /* Set 4Mbps */ else c |= ACL_SPEED16; /* Set 16Mbps */ } /* In case a command is pending - forget it */ tp->ScbInUse = 0; c &= ~ACL_ARESET; /* Clear adapter reset bit */ c |= ACL_CPHALT; /* Halt adapter CPU, allow download */ c &= ~ACL_PSDMAEN; /* Clear pseudo dma bit */ outw(c, ioaddr + SIFACL); sktr_wait(40); /* Download firmware via DIO interface: */ do { /* Download first address part */ outw(*fw_ptr, ioaddr + SIFADX); fw_ptr++; /* Download second address part */ outw(*fw_ptr, ioaddr + SIFADD); fw_ptr++; if((count = *fw_ptr) != 0) /* Load loop counter */ { fw_ptr++; /* Download block data */ for(; count > 0; count--) { outw(*fw_ptr, ioaddr + SIFINC); fw_ptr++; } } else /* Stop, if last block downloaded */ { c = inw(ioaddr + SIFACL); c &= (~ACL_CPHALT | ACL_SINTEN); /* Clear CPHALT and start BUD */ outw(c, ioaddr + SIFACL); return (1); } } while(count == 0); return (-1); } /* * Starts bring up diagnostics of token ring adapter and evaluates * diagnostic results. */ static int sktr_bringup_diags(struct device *dev) { int loop_cnt, retry_cnt; unsigned short Status; int ioaddr = dev->base_addr; sktr_wait(HALF_SECOND); sktr_exec_sifcmd(dev, EXEC_SOFT_RESET); sktr_wait(HALF_SECOND); retry_cnt = BUD_MAX_RETRIES; /* maximal number of retrys */ do { retry_cnt--; if(sktr_debug > 3) printk(KERN_INFO "BUD-Status: \n"); loop_cnt = BUD_MAX_LOOPCNT; /* maximum: three seconds*/ do { /* Inspect BUD results */ loop_cnt--; sktr_wait(HALF_SECOND); Status = inw(ioaddr + SIFSTS); Status &= STS_MASK; if(sktr_debug > 3) printk(KERN_INFO " %04X \n", Status); /* BUD successfully completed */ if(Status == STS_INITIALIZE) return (1); /* Unrecoverable hardware error, BUD not completed? */ } while((loop_cnt > 0) && ((Status & (STS_ERROR | STS_TEST)) != (STS_ERROR | STS_TEST))); /* Error preventing completion of BUD */ if(retry_cnt > 0) { printk(KERN_INFO "%s: Adapter Software Reset.\n", dev->name); sktr_exec_sifcmd(dev, EXEC_SOFT_RESET); sktr_wait(HALF_SECOND); } } while(retry_cnt > 0); Status = inw(ioaddr + SIFSTS); Status &= STS_ERROR_MASK; /* Hardware error occurred! */ printk(KERN_INFO "%s: Bring Up Diagnostics Error (%04X) occurred\n", dev->name, Status); return (-1); } /* * Copy initialisation data to adapter memory, beginning at address * 1:0A00; Starting DMA test and evaluating result bits. */ static int sktr_init_adapter(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; const unsigned char SCB_Test[6] = {0x00, 0x00, 0xC1, 0xE2, 0xD4, 0x8B}; const unsigned char SSB_Test[8] = {0xFF, 0xFF, 0xD1, 0xD7, 0xC5, 0xD9, 0xC3, 0xD4}; void *ptr = (void *)&tp->ipb; unsigned short *ipb_ptr = (unsigned short *)ptr; unsigned char *cb_ptr = (unsigned char *) &tp->scb; unsigned char *sb_ptr = (unsigned char *) &tp->ssb; unsigned short Status; int i, loop_cnt, retry_cnt; int ioaddr = dev->base_addr; /* Normalize: byte order low/high, word order high/low! (only IPB!) */ tp->ipb.SCB_Addr = SWAPW(virt_to_bus(&tp->scb)); tp->ipb.SSB_Addr = SWAPW(virt_to_bus(&tp->ssb)); /* Maximum: three initialization retries */ retry_cnt = INIT_MAX_RETRIES; do { retry_cnt--; /* Transfer initialization block */ outw(0x0001, ioaddr + SIFADX); /* To address 0001:0A00 of adapter RAM */ outw(0x0A00, ioaddr + SIFADD); /* Write 11 words to adapter RAM */ for(i = 0; i < 11; i++) outw(ipb_ptr[i], ioaddr + SIFINC); /* Execute SCB adapter command */ sktr_exec_sifcmd(dev, CMD_EXECUTE); loop_cnt = INIT_MAX_LOOPCNT; /* Maximum: 11 seconds */ /* While remaining retries, no error and not completed */ do { Status = 0; loop_cnt--; sktr_wait(HALF_SECOND); /* Mask interesting status bits */ Status = inw(ioaddr + SIFSTS); Status &= STS_MASK; } while(((Status &(STS_INITIALIZE | STS_ERROR | STS_TEST)) != 0) && ((Status & STS_ERROR) == 0) && (loop_cnt != 0)); if((Status & (STS_INITIALIZE | STS_ERROR | STS_TEST)) == 0) { /* Initialization completed without error */ i = 0; do { /* Test if contents of SCB is valid */ if(SCB_Test[i] != *(cb_ptr + i)) /* DMA data error: wrong data in SCB */ return (-1); i++; } while(i < 6); i = 0; do { /* Test if contents of SSB is valid */ if(SSB_Test[i] != *(sb_ptr + i)) /* DMA data error: wrong data in SSB */ return (-1); i++; } while (i < 8); return (1); /* Adapter successfully initialized */ } else { if((Status & STS_ERROR) != 0) { /* Initialization error occurred */ Status = inw(ioaddr + SIFSTS); Status &= STS_ERROR_MASK; /* ShowInitialisationErrorCode(Status); */ return (-1); /* Unrecoverable error */ } else { if(retry_cnt > 0) { /* Reset adapter and try init again */ sktr_exec_sifcmd(dev, EXEC_SOFT_RESET); sktr_wait(HALF_SECOND); } } } } while(retry_cnt > 0); return (-1); } /* * Check for outstanding commands in command queue and tries to execute * command immediately. Corresponding command flag in command queue is cleared. */ static void sktr_chk_outstanding_cmds(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned long Addr = 0; unsigned char i = 0; if(tp->CMDqueue == 0) return; /* No command execution */ /* If SCB in use: no command */ if(tp->ScbInUse == 1) return; /* Check if adapter is opened, avoiding COMMAND_REJECT * interrupt by the adapter! */ if(tp->AdapterOpenFlag == 0) { if(tp->CMDqueue & OC_OPEN) { /* Execute OPEN command */ tp->CMDqueue ^= OC_OPEN; /* Copy the 18 bytes of the product ID */ while((AdapterName[i] != '\0') && (i < PROD_ID_SIZE)) { tp->ProductID[i] = AdapterName[i]; i++; } Addr = htonl(virt_to_bus(&tp->ocpl)); tp->scb.Parm[0] = LOWORD(Addr); tp->scb.Parm[1] = HIWORD(Addr); tp->scb.CMD = OPEN; } else /* No OPEN command queued, but adapter closed. Note: * We'll try to re-open the adapter in DriverPoll() */ return; /* No adapter command issued */ } else { /* Adapter is open; evaluate command queue: try to execute * outstanding commands (depending on priority!) CLOSE * command queued */ if(tp->CMDqueue & OC_CLOSE) { tp->CMDqueue ^= OC_CLOSE; tp->AdapterOpenFlag = 0; tp->scb.Parm[0] = 0; /* Parm[0], Parm[1] are ignored */ tp->scb.Parm[1] = 0; /* but should be set to zero! */ tp->scb.CMD = CLOSE; if(!tp->HaltInProgress) tp->CMDqueue |= OC_OPEN; /* re-open adapter */ else tp->CMDqueue = 0; /* no more commands */ } else { if(tp->CMDqueue & OC_RECEIVE) { tp->CMDqueue ^= OC_RECEIVE; Addr = htonl(virt_to_bus(tp->RplHead)); tp->scb.Parm[0] = LOWORD(Addr); tp->scb.Parm[1] = HIWORD(Addr); tp->scb.CMD = RECEIVE; } else { if(tp->CMDqueue & OC_TRANSMIT_HALT) { /* NOTE: TRANSMIT.HALT must be checked * before TRANSMIT. */ tp->CMDqueue ^= OC_TRANSMIT_HALT; tp->scb.CMD = TRANSMIT_HALT; /* Parm[0] and Parm[1] are ignored * but should be set to zero! */ tp->scb.Parm[0] = 0; tp->scb.Parm[1] = 0; } else { if(tp->CMDqueue & OC_TRANSMIT) { /* NOTE: TRANSMIT must be * checked after TRANSMIT.HALT */ if(tp->TransmitCommandActive) { if(!tp->TransmitHaltScheduled) { tp->TransmitHaltScheduled = 1; sktr_exec_cmd(dev, OC_TRANSMIT_HALT) ; } tp->TransmitCommandActive = 0; return; } tp->CMDqueue ^= OC_TRANSMIT; sktr_cancel_tx_queue(tp); Addr = htonl(virt_to_bus(tp->TplBusy)); tp->scb.Parm[0] = LOWORD(Addr); tp->scb.Parm[1] = HIWORD(Addr); tp->scb.CMD = TRANSMIT; tp->TransmitCommandActive = 1; } else { if(tp->CMDqueue & OC_MODIFY_OPEN_PARMS) { tp->CMDqueue ^= OC_MODIFY_OPEN_PARMS; tp->scb.Parm[0] = tp->ocpl.OPENOptions; /* new OPEN options*/ tp->scb.Parm[0] |= ENABLE_FULL_DUPLEX_SELECTION; tp->scb.Parm[1] = 0; /* is ignored but should be zero */ tp->scb.CMD = MODIFY_OPEN_PARMS; } else { if(tp->CMDqueue & OC_SET_FUNCT_ADDR) { tp->CMDqueue ^= OC_SET_FUNCT_ADDR; tp->scb.Parm[0] = LOWORD(tp->ocpl.FunctAddr); tp->scb.Parm[1] = HIWORD(tp->ocpl.FunctAddr); tp->scb.CMD = SET_FUNCT_ADDR; } else { if(tp->CMDqueue & OC_SET_GROUP_ADDR) { tp->CMDqueue ^= OC_SET_GROUP_ADDR; tp->scb.Parm[0] = LOWORD(tp->ocpl.GroupAddr); tp->scb.Parm[1] = HIWORD(tp->ocpl.GroupAddr); tp->scb.CMD = SET_GROUP_ADDR; } else { if(tp->CMDqueue & OC_READ_ERROR_LOG) { tp->CMDqueue ^= OC_READ_ERROR_LOG; Addr = htonl(virt_to_bus(&tp->errorlogtable)); tp->scb.Parm[0] = LOWORD(Addr); tp->scb.Parm[1] = HIWORD(Addr); tp->scb.CMD = READ_ERROR_LOG; } else { printk(KERN_WARNING "CheckForOutstandingCommand: unknown Command\n"); tp->CMDqueue = 0; return; } } } } } } } } } tp->ScbInUse = 1; /* Set semaphore: SCB in use. */ /* Execute SCB and generate IRQ when done. */ sktr_exec_sifcmd(dev, CMD_EXECUTE | CMD_SCB_REQUEST); return; } /* * IRQ conditions: signal loss on the ring, transmit or receive of beacon * frames (disabled if bit 1 of OPEN option is set); report error MAC * frame transmit (disabled if bit 2 of OPEN option is set); open or short * cirquit fault on the lobe is detected; remove MAC frame received; * error counter overflow (255); opened adapter is the only station in ring. * After some of the IRQs the adapter is closed! */ static void sktr_ring_status_irq(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; tp->CurrentRingStatus = SWAPB(tp->ssb.Parm[0]); /* First: fill up statistics */ if(tp->ssb.Parm[0] & SIGNAL_LOSS) { printk(KERN_INFO "%s: Signal Loss\n", dev->name); tp->MacStat.line_errors++; } /* Adapter is closed, but initialized */ if(tp->ssb.Parm[0] & LOBE_WIRE_FAULT) { printk(KERN_INFO "%s: Lobe Wire Fault, Reopen Adapter\n", dev->name); tp->MacStat.line_errors++; } if(tp->ssb.Parm[0] & RING_RECOVERY) printk(KERN_INFO "%s: Ring Recovery\n", dev->name); /* Counter overflow: read error log */ if(tp->ssb.Parm[0] & COUNTER_OVERFLOW) { printk(KERN_INFO "%s: Counter Overflow\n", dev->name); sktr_exec_cmd(dev, OC_READ_ERROR_LOG); } /* Adapter is closed, but initialized */ if(tp->ssb.Parm[0] & REMOVE_RECEIVED) printk(KERN_INFO "%s: Remove Received, Reopen Adapter\n", dev->name); /* Adapter is closed, but initialized */ if(tp->ssb.Parm[0] & AUTO_REMOVAL_ERROR) printk(KERN_INFO "%s: Auto Removal Error, Reopen Adapter\n", dev->name); if(tp->ssb.Parm[0] & HARD_ERROR) printk(KERN_INFO "%s: Hard Error\n", dev->name); if(tp->ssb.Parm[0] & SOFT_ERROR) printk(KERN_INFO "%s: Soft Error\n", dev->name); if(tp->ssb.Parm[0] & TRANSMIT_BEACON) printk(KERN_INFO "%s: Transmit Beacon\n", dev->name); if(tp->ssb.Parm[0] & SINGLE_STATION) printk(KERN_INFO "%s: Single Station\n", dev->name); /* Check if adapter has been closed */ if(tp->ssb.Parm[0] & ADAPTER_CLOSED) { printk(KERN_INFO "%s: Adapter closed (Reopening)," "QueueSkb %d, CurrentRingStat %x\n", dev->name, tp->QueueSkb, tp->CurrentRingStatus); tp->AdapterOpenFlag = 0; sktr_open_adapter(dev); } return; } /* * Issued if adapter has encountered an unrecoverable hardware * or software error. */ static void sktr_chk_irq(struct device *dev) { int i; unsigned short AdapterCheckBlock[4]; unsigned short ioaddr = dev->base_addr; struct net_local *tp = (struct net_local *)dev->priv; tp->AdapterOpenFlag = 0; /* Adapter closed now */ /* Page number of adapter memory */ outw(0x0001, ioaddr + SIFADX); /* Address offset */ outw(CHECKADDR, ioaddr + SIFADR); /* Reading 8 byte adapter check block. */ for(i = 0; i < 4; i++) AdapterCheckBlock[i] = inw(ioaddr + SIFINC); if(sktr_debug > 3) { printk("%s: AdapterCheckBlock: ", dev->name); for (i = 0; i < 4; i++) printk("%04X", AdapterCheckBlock[i]); printk("\n"); } switch(AdapterCheckBlock[0]) { case DIO_PARITY: printk(KERN_INFO "%s: DIO parity error\n", dev->name); break; case DMA_READ_ABORT: printk(KERN_INFO "%s DMA read operation aborted:\n", dev->name); switch (AdapterCheckBlock[1]) { case 0: printk(KERN_INFO "Timeout\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; case 1: printk(KERN_INFO "Parity error\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; case 2: printk(KERN_INFO "Bus error\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; default: printk(KERN_INFO "Unknown error.\n"); break; } break; case DMA_WRITE_ABORT: printk(KERN_INFO "%s: DMA write operation aborted: \n", dev->name); switch (AdapterCheckBlock[1]) { case 0: printk(KERN_INFO "Timeout\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; case 1: printk(KERN_INFO "Parity error\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; case 2: printk(KERN_INFO "Bus error\n"); printk(KERN_INFO "Address: %04X %04X\n", AdapterCheckBlock[2], AdapterCheckBlock[3]); break; default: printk(KERN_INFO "Unknown error.\n"); break; } break; case ILLEGAL_OP_CODE: printk("%s: Illegal operation code in firmware\n", dev->name); /* Parm[0-3]: adapter internal register R13-R15 */ break; case PARITY_ERRORS: printk("%s: Adapter internal bus parity error\n", dev->name); /* Parm[0-3]: adapter internal register R13-R15 */ break; case RAM_DATA_ERROR: printk("%s: RAM data error\n", dev->name); /* Parm[0-1]: MSW/LSW address of RAM location. */ break; case RAM_PARITY_ERROR: printk("%s: RAM parity error\n", dev->name); /* Parm[0-1]: MSW/LSW address of RAM location. */ break; case RING_UNDERRUN: printk("%s: Internal DMA underrun detected\n", dev->name); break; case INVALID_IRQ: printk("%s: Unrecognized interrupt detected\n", dev->name); /* Parm[0-3]: adapter internal register R13-R15 */ break; case INVALID_ERROR_IRQ: printk("%s: Unrecognized error interrupt detected\n", dev->name); /* Parm[0-3]: adapter internal register R13-R15 */ break; case INVALID_XOP: printk("%s: Unrecognized XOP request detected\n", dev->name); /* Parm[0-3]: adapter internal register R13-R15 */ break; default: printk("%s: Unknown status", dev->name); break; } if(sktr_chipset_init(dev) == 1) { /* Restart of firmware successful */ tp->AdapterOpenFlag = 1; } return; } /* * Internal adapter pointer to RAM data are copied from adapter into * host system. */ static void sktr_read_ptr(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned short adapterram; sktr_read_ram(dev, (unsigned char *)&tp->intptrs.BurnedInAddrPtr, ADAPTER_INT_PTRS, 16); sktr_read_ram(dev, (unsigned char *)&adapterram, (unsigned short)SWAPB(tp->intptrs.AdapterRAMPtr), 2); printk(KERN_INFO "%s: Adapter RAM size: %d K\n", dev->name, SWAPB(adapterram)); return; } /* * Reads a number of bytes from adapter to system memory. */ static void sktr_read_ram(struct device *dev, unsigned char *Data, unsigned short Address, int Length) { int i; unsigned short old_sifadx, old_sifadr, InWord; unsigned short ioaddr = dev->base_addr; /* Save the current values */ old_sifadx = inw(ioaddr + SIFADX); old_sifadr = inw(ioaddr + SIFADR); /* Page number of adapter memory */ outw(0x0001, ioaddr + SIFADX); /* Address offset in adapter RAM */ outw(Address, ioaddr + SIFADR); /* Copy len byte from adapter memory to system data area. */ i = 0; for(;;) { InWord = inw(ioaddr + SIFINC); *(Data + i) = HIBYTE(InWord); /* Write first byte */ if(++i == Length) /* All is done break */ break; *(Data + i) = LOBYTE(InWord); /* Write second byte */ if (++i == Length) /* All is done break */ break; } /* Restore original values */ outw(old_sifadx, ioaddr + SIFADX); outw(old_sifadr, ioaddr + SIFADR); return; } /* * Reads MAC address from adapter ROM. */ static void sktr_read_addr(struct device *dev, unsigned char *Address) { int i, In; unsigned short ioaddr = dev->base_addr; /* Address: 0000:0000 */ outw(0, ioaddr + SIFADX); outw(0, ioaddr + SIFADR); /* Read six byte MAC address data */ for(i = 0; i < 6; i++) { In = inw(ioaddr + SIFINC); *(Address + i) = (unsigned char)(In >> 8); } return; } /* * Cancel all queued packets in the transmission queue. */ static void sktr_cancel_tx_queue(struct net_local* tp) { TPL *tpl; struct sk_buff *skb; /* * NOTE: There must not be an active TRANSMIT command pending, when * this function is called. */ if(tp->TransmitCommandActive) return; for(;;) { tpl = tp->TplBusy; if(!tpl->BusyFlag) break; /* "Remove" TPL from busy list. */ tp->TplBusy = tpl->NextTPLPtr; sktr_write_tpl_status(tpl, 0); /* Clear VALID bit */ tpl->BusyFlag = 0; /* "free" TPL */ printk(KERN_INFO "Cancel tx (%08lXh).\n", (unsigned long)tpl); dev_kfree_skb(tpl->Skb); } for(;;) { skb = skb_dequeue(&tp->SendSkbQueue); if(skb == NULL) break; tp->QueueSkb++; dev_kfree_skb(skb); } return; } /* * This function is called whenever a transmit interrupt is generated by the * adapter. For a command complete interrupt, it is checked if we have to * issue a new transmit command or not. */ static void sktr_tx_status_irq(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned char HighByte, HighAc, LowAc; TPL *tpl; /* NOTE: At this point the SSB from TRANSMIT STATUS is no longer * available, because the CLEAR SSB command has already been issued. * * Process all complete transmissions. */ for(;;) { tpl = tp->TplBusy; if(!tpl->BusyFlag || (tpl->Status & (TX_VALID | TX_FRAME_COMPLETE)) != TX_FRAME_COMPLETE) { break; } /* "Remove" TPL from busy list. */ tp->TplBusy = tpl->NextTPLPtr ; if(sktr_debug > 3) sktr_dump(tpl->MData, SWAPB(tpl->FrameSize)); /* Check the transmit status field only for directed frames*/ if(DIRECTED_FRAME(tpl) && (tpl->Status & TX_ERROR) == 0) { HighByte = GET_TRANSMIT_STATUS_HIGH_BYTE(tpl->Status); HighAc = GET_FRAME_STATUS_HIGH_AC(HighByte); LowAc = GET_FRAME_STATUS_LOW_AC(HighByte); if((HighAc != LowAc) || (HighAc == AC_NOT_RECOGNIZED)) { printk(KERN_INFO "%s: (DA=%08lX not recognized)", dev->name, *(unsigned long *)&tpl->MData[2+2]); } else { if(sktr_debug > 3) printk("%s: Directed frame tx'd\n", dev->name); } } else { if(!DIRECTED_FRAME(tpl)) { if(sktr_debug > 3) printk("%s: Broadcast frame tx'd\n", dev->name); } } tp->MacStat.tx_packets++; dev_kfree_skb(tpl->Skb); tpl->BusyFlag = 0; /* "free" TPL */ } dev->tbusy = 0; if(tp->QueueSkb < MAX_TX_QUEUE) sktr_hardware_send_packet(dev, tp); return; } /* * Called if a frame receive interrupt is generated by the adapter. * Check if the frame is valid and indicate it to system. */ static void sktr_rcv_status_irq(struct device *dev) { struct net_local *tp = (struct net_local *)dev->priv; unsigned char *ReceiveDataPtr; struct sk_buff *skb; unsigned int Length, Length2; RPL *rpl; RPL *SaveHead; /* NOTE: At this point the SSB from RECEIVE STATUS is no longer * available, because the CLEAR SSB command has already been issued. * * Process all complete receives. */ for(;;) { rpl = tp->RplHead; if(rpl->Status & RX_VALID) break; /* RPL still in use by adapter */ /* Forward RPLHead pointer to next list. */ SaveHead = tp->RplHead; tp->RplHead = rpl->NextRPLPtr; /* Get the frame size (Byte swap for Intel). * Do this early (see workaround comment below) */ Length = (unsigned short)SWAPB(rpl->FrameSize); /* Check if the Frame_Start, Frame_End and * Frame_Complete bits are set. */ if((rpl->Status & VALID_SINGLE_BUFFER_FRAME) == VALID_SINGLE_BUFFER_FRAME) { ReceiveDataPtr = rpl->MData; /* Workaround for delayed write of FrameSize on ISA * (FrameSize is false but valid-bit is reset) * Frame size is set to zero when the RPL is freed. * Length2 is there because there have also been * cases where the FrameSize was partially written */ Length2 = (unsigned short)SWAPB(rpl->FrameSize); if(Length == 0 || Length != Length2) { tp->RplHead = SaveHead; break; /* Return to sktr_interrupt */ } /* Drop frames sent by myself */ if(sktr_chk_frame(dev, rpl->MData)) { printk(KERN_INFO "%s: Received my own frame\n", dev->name); if(rpl->Skb != NULL) dev_kfree_skb(rpl->Skb); } else { sktr_update_rcv_stats(tp,ReceiveDataPtr,Length); if(sktr_debug > 3) printk("%s: Packet Length %04X (%d)\n", dev->name, Length, Length); /* Indicate the received frame to system the * adapter does the Source-Routing padding for * us. See: OpenOptions in sktr_init_opb() */ skb = rpl->Skb; if(rpl->SkbStat == SKB_UNAVAILABLE) { /* Try again to allocate skb */ skb = dev_alloc_skb(tp->MaxPacketSize); if(skb == NULL) { /* Update Stats ?? */ } else { skb->dev = dev; skb_put(skb, tp->MaxPacketSize); rpl->SkbStat = SKB_DATA_COPY; ReceiveDataPtr = rpl->MData; } } if(rpl->SkbStat == SKB_DATA_COPY || rpl->SkbStat == SKB_DMA_DIRECT) { if(rpl->SkbStat == SKB_DATA_COPY) { memmove(skb->data, ReceiveDataPtr, Length); } /* Deliver frame to system */ rpl->Skb = NULL; skb_trim(skb,Length); skb->protocol = tr_type_trans(skb,dev); netif_rx(skb); } } } else /* Invalid frame */ { if(rpl->Skb != NULL) dev_kfree_skb(rpl->Skb); /* Skip list. */ if(rpl->Status & RX_START_FRAME) /* Frame start bit is set -> overflow. */ tp->MacStat.rx_errors++; } /* Allocate new skb for rpl */ rpl->Skb = dev_alloc_skb(tp->MaxPacketSize); /* skb == NULL ? then use local buffer */ if(rpl->Skb == NULL) { rpl->SkbStat = SKB_UNAVAILABLE; rpl->FragList[0].DataAddr = htonl(virt_to_bus(tp->LocalRxBuffers[rpl->RPLIndex])); rpl->MData = tp->LocalRxBuffers[rpl->RPLIndex]; } else /* skb != NULL */ { rpl->Skb->dev = dev; skb_put(rpl->Skb, tp->MaxPacketSize); /* Data unreachable for DMA ? then use local buffer */ if(virt_to_bus(rpl->Skb->data) + tp->MaxPacketSize > ISA_MAX_ADDRESS) { rpl->SkbStat = SKB_DATA_COPY; rpl->FragList[0].DataAddr = htonl(virt_to_bus(tp->LocalRxBuffers[rpl->RPLIndex])); rpl->MData = tp->LocalRxBuffers[rpl->RPLIndex]; } else { /* DMA directly in skb->data */ rpl->SkbStat = SKB_DMA_DIRECT; rpl->FragList[0].DataAddr = htonl(virt_to_bus(rpl->Skb->data)); rpl->MData = rpl->Skb->data; } } rpl->FragList[0].DataCount = SWAPB(tp->MaxPacketSize); rpl->FrameSize = 0; /* Pass the last RPL back to the adapter */ tp->RplTail->FrameSize = 0; /* Reset the CSTAT field in the list. */ sktr_write_rpl_status(tp->RplTail, RX_VALID | RX_FRAME_IRQ); /* Current RPL becomes last one in list. */ tp->RplTail = tp->RplTail->NextRPLPtr; /* Inform adapter about RPL valid. */ sktr_exec_sifcmd(dev, CMD_RX_VALID); } return; } /* * This function should be used whenever the status of any RPL must be * modified by the driver, because the compiler may otherwise change the * order of instructions such that writing the RPL status may be executed * at an undesireable time. When this function is used, the status is * always written when the function is called. */ static void sktr_write_rpl_status(RPL *rpl, unsigned int Status) { rpl->Status = Status; return; } /* * The function updates the statistic counters in mac->MacStat. * It differtiates between directed and broadcast/multicast ( ==functional) * frames. */ static void sktr_update_rcv_stats(struct net_local *tp, unsigned char DataPtr[], unsigned int Length) { tp->MacStat.rx_packets++; /* Test functional bit */ if(DataPtr[2] & GROUP_BIT) tp->MacStat.multicast++; return; } /* * Check if it is a frame of myself. Compare source address with my current * address in reverse direction, and mask out the TR_RII. */ static unsigned char sktr_chk_frame(struct device *dev, unsigned char *Addr) { int i; for(i = 5; i > 0; i--) { if(Addr[8 + i] != dev->dev_addr[i]) return (0); } /* Mask out RIF bit. */ if((Addr[8] & ~TR_RII) != (unsigned char)(dev->dev_addr[0])) return (0); return (1); /* It is my frame. */ } /* * Dump Packet (data) */ static void sktr_dump(unsigned char *Data, int length) { int i, j; for (i = 0, j = 0; i < length / 8; i++, j += 8) { printk(KERN_DEBUG "%02x %02x %02x %02x %02x %02x %02x %02x\n", Data[j+0],Data[j+1],Data[j+2],Data[j+3], Data[j+4],Data[j+5],Data[j+6],Data[j+7]); } return; } #ifdef MODULE static struct device* dev_sktr[SKTR_MAX_ADAPTERS]; static int io[SKTR_MAX_ADAPTERS] = { 0, 0 }; static int irq[SKTR_MAX_ADAPTERS] = { 0, 0 }; static int mem[SKTR_MAX_ADAPTERS] = { 0, 0 }; MODULE_PARM(io, "1-" __MODULE_STRING(SKTR_MAX_ADAPTERS) "i"); MODULE_PARM(irq, "1-" __MODULE_STRING(SKTR_MAX_ADAPTERS) "i"); MODULE_PARM(mem, "1-" __MODULE_STRING(SKTR_MAX_ADAPTERS) "i"); int init_module(void) { int i; for(i = 0; i < SKTR_MAX_ADAPTERS; i++) { irq[i] = 0; mem[i] = 0; dev_sktr[i] = NULL; dev_sktr[i] = init_trdev(dev_sktr[i], 0); if(dev_sktr[i] == NULL) return (-ENOMEM); dev_sktr[i]->base_addr = io[i]; dev_sktr[i]->irq = irq[i]; dev_sktr[i]->mem_start = mem[i]; dev_sktr[i]->init = &sktr_probe; if(register_trdev(dev_sktr[i]) != 0) { kfree_s(dev_sktr[i], sizeof(struct device)); dev_sktr[i] = NULL; if(i == 0) { printk("sktr: register_trdev() returned non-zero.\n"); return (-EIO); } else return (0); } } return (0); } void cleanup_module(void) { int i; for(i = 0; i < SKTR_MAX_ADAPTERS; i++) { if(dev_sktr[i]) { unregister_trdev(dev_sktr[i]); release_region(dev_sktr[i]->base_addr, SKTR_IO_EXTENT); if(dev_sktr[i]->irq) free_irq(dev_sktr[i]->irq, dev_sktr[i]); if(dev_sktr[i]->dma > 0) free_dma(dev_sktr[i]->dma); if(dev_sktr[i]->priv) kfree_s(dev_sktr[i]->priv, sizeof(struct net_local)); kfree_s(dev_sktr[i], sizeof(struct device)); dev_sktr[i] = NULL; } } } #endif /* MODULE */ |