/* * drivers/i2o/i2o_lan.c * * I2O LAN CLASS OSM May 26th 2000 * * (C) Copyright 1999, 2000 University of Helsinki, * Department of Computer Science * * This code is still under development / test. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version * 2 of the License, or (at your option) any later version. * * Authors: Auvo H„kkinen * Fixes: Juha Siev„nen * Taneli V„h„kangas * Deepak Saxena * * Tested: in FDDI environment (using SysKonnect's DDM) * in Gigabit Eth environment (using SysKonnect's DDM) * in Fast Ethernet environment (using Intel 82558 DDM) * * TODO: tests for other LAN classes (Token Ring, Fibre Channel) */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "i2o_lan.h" //#define DRIVERDEBUG #ifdef DRIVERDEBUG #define dprintk(s, args...) printk(s, ## args) #else #define dprintk(s, args...) #endif /* The following module parameters are used as default values * for per interface values located in the net_device private area. * Private values are changed via /proc filesystem. */ static u32 max_buckets_out = I2O_LAN_MAX_BUCKETS_OUT; static u32 bucket_thresh = I2O_LAN_BUCKET_THRESH; static u32 rx_copybreak = I2O_LAN_RX_COPYBREAK; static u8 tx_batch_mode = I2O_LAN_TX_BATCH_MODE; static u32 i2o_event_mask = I2O_LAN_EVENT_MASK; #define MAX_LAN_CARDS 16 static struct net_device *i2o_landevs[MAX_LAN_CARDS+1]; static int unit = -1; /* device unit number */ static void i2o_lan_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m); static void i2o_lan_send_post_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m); static int i2o_lan_receive_post(struct net_device *dev); static void i2o_lan_receive_post_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m); static void i2o_lan_release_buckets(struct net_device *dev, u32 *msg); static int i2o_lan_reset(struct net_device *dev); static void i2o_lan_handle_event(struct net_device *dev, u32 *msg); /* Structures to register handlers for the incoming replies. */ static struct i2o_handler i2o_lan_send_handler = { i2o_lan_send_post_reply, // For send replies NULL, NULL, NULL, "I2O LAN OSM send", -1, I2O_CLASS_LAN }; static int lan_send_context; static struct i2o_handler i2o_lan_receive_handler = { i2o_lan_receive_post_reply, // For receive replies NULL, NULL, NULL, "I2O LAN OSM receive", -1, I2O_CLASS_LAN }; static int lan_receive_context; static struct i2o_handler i2o_lan_handler = { i2o_lan_reply, // For other replies NULL, NULL, NULL, "I2O LAN OSM", -1, I2O_CLASS_LAN }; static int lan_context; DECLARE_TASK_QUEUE(i2o_post_buckets_task); struct tq_struct run_i2o_post_buckets_task = { routine: (void (*)(void *)) run_task_queue, data: (void *) 0 }; /* Functions to handle message failures and transaction errors: ==============================================================*/ /* * i2o_lan_handle_failure(): Fail bit has been set since IOP's message * layer cannot deliver the request to the target, or the target cannot * process the request. */ static void i2o_lan_handle_failure(struct net_device *dev, u32 *msg) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 *preserved_msg = (u32*)(iop->mem_offset + msg[7]); u32 *sgl_elem = &preserved_msg[4]; struct sk_buff *skb = NULL; u8 le_flag; i2o_report_status(KERN_INFO, dev->name, msg); /* If PacketSend failed, free sk_buffs reserved by upper layers */ if (msg[1] >> 24 == LAN_PACKET_SEND) { do { skb = (struct sk_buff *)(sgl_elem[1]); dev_kfree_skb_irq(skb); atomic_dec(&priv->tx_out); le_flag = *sgl_elem >> 31; sgl_elem +=3; } while (le_flag == 0); /* Last element flag not set */ if (netif_queue_stopped(dev)) netif_wake_queue(dev); } /* If ReceivePost failed, free sk_buffs we have reserved */ if (msg[1] >> 24 == LAN_RECEIVE_POST) { do { skb = (struct sk_buff *)(sgl_elem[1]); dev_kfree_skb_irq(skb); atomic_dec(&priv->buckets_out); le_flag = *sgl_elem >> 31; sgl_elem +=3; } while (le_flag == 0); /* Last element flag not set */ } /* Release the preserved msg frame by resubmitting it as a NOP */ preserved_msg[0] = THREE_WORD_MSG_SIZE | SGL_OFFSET_0; preserved_msg[1] = I2O_CMD_UTIL_NOP << 24 | HOST_TID << 12 | 0; preserved_msg[2] = 0; i2o_post_message(iop, msg[7]); } /* * i2o_lan_handle_transaction_error(): IOP or DDM has rejected the request * for general cause (format error, bad function code, insufficient resources, * etc.). We get one transaction_error for each failed transaction. */ static void i2o_lan_handle_transaction_error(struct net_device *dev, u32 *msg) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct sk_buff *skb; i2o_report_status(KERN_INFO, dev->name, msg); /* If PacketSend was rejected, free sk_buff reserved by upper layers */ if (msg[1] >> 24 == LAN_PACKET_SEND) { skb = (struct sk_buff *)(msg[3]); // TransactionContext dev_kfree_skb_irq(skb); atomic_dec(&priv->tx_out); if (netif_queue_stopped(dev)) netif_wake_queue(dev); } /* If ReceivePost was rejected, free sk_buff we have reserved */ if (msg[1] >> 24 == LAN_RECEIVE_POST) { skb = (struct sk_buff *)(msg[3]); dev_kfree_skb_irq(skb); atomic_dec(&priv->buckets_out); } } /* * i2o_lan_handle_status(): Common parts of handling a not succeeded request * (status != SUCCESS). */ static int i2o_lan_handle_status(struct net_device *dev, u32 *msg) { /* Fail bit set? */ if (msg[0] & MSG_FAIL) { i2o_lan_handle_failure(dev, msg); return -1; } /* Message rejected for general cause? */ if ((msg[4]>>24) == I2O_REPLY_STATUS_TRANSACTION_ERROR) { i2o_lan_handle_transaction_error(dev, msg); return -1; } /* Else have to handle it in the callback function */ return 0; } /* Callback functions called from the interrupt routine: =======================================================*/ /* * i2o_lan_send_post_reply(): Callback function to handle PostSend replies. */ static void i2o_lan_send_post_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m) { u32 *msg = (u32 *)m; u8 unit = (u8)(msg[2]>>16); // InitiatorContext struct net_device *dev = i2o_landevs[unit]; struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; u8 trl_count = msg[3] & 0x000000FF; if ((msg[4] >> 24) != I2O_REPLY_STATUS_SUCCESS) { if (i2o_lan_handle_status(dev, msg)) return; } #ifdef DRIVERDEBUG i2o_report_status(KERN_INFO, dev->name, msg); #endif /* DDM has handled transmit request(s), free sk_buffs. * We get similar single transaction reply also in error cases * (except if msg failure or transaction error). */ while (trl_count) { dev_kfree_skb_irq((struct sk_buff *)msg[4 + trl_count]); dprintk(KERN_INFO "%s: tx skb freed (trl_count=%d).\n", dev->name, trl_count); atomic_dec(&priv->tx_out); trl_count--; } /* If priv->tx_out had reached tx_max_out, the queue was stopped */ if (netif_queue_stopped(dev)) netif_wake_queue(dev); } /* * i2o_lan_receive_post_reply(): Callback function to process incoming packets. */ static void i2o_lan_receive_post_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m) { u32 *msg = (u32 *)m; u8 unit = (u8)(msg[2]>>16); // InitiatorContext struct net_device *dev = i2o_landevs[unit]; struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_bucket_descriptor *bucket = (struct i2o_bucket_descriptor *)&msg[6]; struct i2o_packet_info *packet; u8 trl_count = msg[3] & 0x000000FF; struct sk_buff *skb, *old_skb; unsigned long flags = 0; if ((msg[4] >> 24) != I2O_REPLY_STATUS_SUCCESS) { if (i2o_lan_handle_status(dev, msg)) return; i2o_lan_release_buckets(dev, msg); return; } #ifdef DRIVERDEBUG i2o_report_status(KERN_INFO, dev->name, msg); #endif /* Else we are receiving incoming post. */ while (trl_count--) { skb = (struct sk_buff *)bucket->context; packet = (struct i2o_packet_info *)bucket->packet_info; atomic_dec(&priv->buckets_out); /* Sanity checks: Any weird characteristics in bucket? */ if (packet->flags & 0x0f || ! packet->flags & 0x40) { if (packet->flags & 0x01) printk(KERN_WARNING "%s: packet with errors, error code=0x%02x.\n", dev->name, packet->status & 0xff); /* The following shouldn't happen, unless parameters in * LAN_OPERATION group are changed during the run time. */ if (packet->flags & 0x0c) printk(KERN_DEBUG "%s: multi-bucket packets not supported!\n", dev->name); if (! packet->flags & 0x40) printk(KERN_DEBUG "%s: multiple packets in a bucket not supported!\n", dev->name); dev_kfree_skb_irq(skb); bucket++; continue; } /* Copy short packet to a new skb */ if (packet->len < priv->rx_copybreak) { old_skb = skb; skb = (struct sk_buff *)dev_alloc_skb(packet->len+2); if (skb == NULL) { printk(KERN_ERR "%s: Can't allocate skb.\n", dev->name); return; } skb_reserve(skb, 2); memcpy(skb_put(skb, packet->len), old_skb->data, packet->len); spin_lock_irqsave(&priv->fbl_lock, flags); if (priv->i2o_fbl_tail < I2O_LAN_MAX_BUCKETS_OUT) priv->i2o_fbl[++priv->i2o_fbl_tail] = old_skb; else dev_kfree_skb_irq(old_skb); spin_unlock_irqrestore(&priv->fbl_lock, flags); } else skb_put(skb, packet->len); /* Deliver to upper layers */ skb->dev = dev; skb->protocol = priv->type_trans(skb, dev); netif_rx(skb); dev->last_rx = jiffies; dprintk(KERN_INFO "%s: Incoming packet (%d bytes) delivered " "to upper level.\n", dev->name, packet->len); bucket++; // to next Packet Descriptor Block } #ifdef DRIVERDEBUG if (msg[5] == 0) printk(KERN_INFO "%s: DDM out of buckets (priv->count = %d)!\n", dev->name, atomic_read(&priv->buckets_out)); #endif /* If DDM has already consumed bucket_thresh buckets, post new ones */ if (atomic_read(&priv->buckets_out) <= priv->max_buckets_out - priv->bucket_thresh) { run_i2o_post_buckets_task.data = (void *)dev; queue_task(&run_i2o_post_buckets_task, &tq_immediate); mark_bh(IMMEDIATE_BH); } return; } /* * i2o_lan_reply(): Callback function to handle other incoming messages * except SendPost and ReceivePost. */ static void i2o_lan_reply(struct i2o_handler *h, struct i2o_controller *iop, struct i2o_message *m) { u32 *msg = (u32 *)m; u8 unit = (u8)(msg[2]>>16); // InitiatorContext struct net_device *dev = i2o_landevs[unit]; if ((msg[4] >> 24) != I2O_REPLY_STATUS_SUCCESS) { if (i2o_lan_handle_status(dev, msg)) return; /* In other error cases just report and continue */ i2o_report_status(KERN_INFO, dev->name, msg); } #ifdef DRIVERDEBUG i2o_report_status(KERN_INFO, dev->name, msg); #endif switch (msg[1] >> 24) { case LAN_RESET: case LAN_SUSPEND: /* default reply without payload */ break; case I2O_CMD_UTIL_EVT_REGISTER: case I2O_CMD_UTIL_EVT_ACK: i2o_lan_handle_event(dev, msg); break; case I2O_CMD_UTIL_PARAMS_SET: /* default reply, results in ReplyPayload (not examined) */ switch (msg[3] >> 16) { case 1: dprintk(KERN_INFO "%s: Reply to set MAC filter mask.\n", dev->name); break; case 2: dprintk(KERN_INFO "%s: Reply to set MAC table.\n", dev->name); break; default: printk(KERN_WARNING "%s: Bad group 0x%04X\n", dev->name,msg[3] >> 16); } break; default: printk(KERN_ERR "%s: No handler for the reply.\n", dev->name); i2o_report_status(KERN_INFO, dev->name, msg); } } /* Functions used by the above callback functions: =================================================*/ /* * i2o_lan_release_buckets(): Free unused buckets (sk_buffs). */ static void i2o_lan_release_buckets(struct net_device *dev, u32 *msg) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; u8 trl_elem_size = (u8)(msg[3]>>8 & 0x000000FF); u8 trl_count = (u8)(msg[3] & 0x000000FF); u32 *pskb = &msg[6]; while (trl_count--) { dprintk(KERN_DEBUG "%s: Releasing unused rx skb %p (trl_count=%d).\n", dev->name, (struct sk_buff*)(*pskb),trl_count+1); dev_kfree_skb_irq((struct sk_buff *)(*pskb)); pskb += 1 + trl_elem_size; atomic_dec(&priv->buckets_out); } } /* * i2o_lan_event_reply(): Handle events. */ static void i2o_lan_handle_event(struct net_device *dev, u32 *msg) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 max_evt_data_size =iop->status_block->inbound_frame_size-5; struct i2o_reply { u32 header[4]; u32 evt_indicator; u32 data[max_evt_data_size]; } *evt = (struct i2o_reply *)msg; int evt_data_len = ((msg[0]>>16) - 5) * 4; /* real size*/ printk(KERN_INFO "%s: I2O event - ", dev->name); if (msg[1]>>24 == I2O_CMD_UTIL_EVT_ACK) { printk("Event acknowledgement reply.\n"); return; } /* Else evt->function == I2O_CMD_UTIL_EVT_REGISTER) */ switch (evt->evt_indicator) { case I2O_EVT_IND_STATE_CHANGE: { struct state_data { u16 status; u8 state; u8 data; } *evt_data = (struct state_data *)(evt->data[0]); printk("State chance 0x%08x.\n", evt->data[0]); /* If the DDM is in error state, recovery may be * possible if status = Transmit or Receive Control * Unit Inoperable. */ if (evt_data->state==0x05 && evt_data->status==0x0003) i2o_lan_reset(dev); break; } case I2O_EVT_IND_FIELD_MODIFIED: { u16 *work16 = (u16 *)evt->data; printk("Group 0x%04x, field %d changed.\n", work16[0], work16[1]); break; } case I2O_EVT_IND_VENDOR_EVT: { int i; printk("Vendor event:\n"); for (i = 0; i < evt_data_len / 4; i++) printk(" 0x%08x\n", evt->data[i]); break; } case I2O_EVT_IND_DEVICE_RESET: /* Spec 2.0 p. 6-121: * The event of _DEVICE_RESET should also be responded */ printk("Device reset.\n"); if (i2o_event_ack(iop, msg) < 0) printk("%s: Event Acknowledge timeout.\n", dev->name); break; #if 0 case I2O_EVT_IND_EVT_MASK_MODIFIED: printk("Event mask modified, 0x%08x.\n", evt->data[0]); break; case I2O_EVT_IND_GENERAL_WARNING: printk("General warning 0x%04x.\n", evt->data[0]); break; case I2O_EVT_IND_CONFIGURATION_FLAG: printk("Configuration requested.\n"); break; case I2O_EVT_IND_CAPABILITY_CHANGE: printk("Capability change 0x%04x.\n", evt->data[0]); break; case I2O_EVT_IND_DEVICE_STATE: printk("Device state changed 0x%08x.\n", evt->data[0]); break; #endif case I2O_LAN_EVT_LINK_DOWN: netif_carrier_off(dev); printk("Link to the physical device is lost.\n"); break; case I2O_LAN_EVT_LINK_UP: netif_carrier_on(dev); printk("Link to the physical device is (re)established.\n"); break; case I2O_LAN_EVT_MEDIA_CHANGE: printk("Media change.\n"); break; default: printk("0x%08x. No handler.\n", evt->evt_indicator); } } /* * i2o_lan_receive_post(): Post buckets to receive packets. */ static int i2o_lan_receive_post(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; struct sk_buff *skb; u32 m, *msg; u32 bucket_len = (dev->mtu + dev->hard_header_len); u32 total = priv->max_buckets_out - atomic_read(&priv->buckets_out); u32 bucket_count; u32 *sgl_elem; unsigned long flags; /* Send (total/bucket_count) separate I2O requests */ while (total) { m = I2O_POST_READ32(iop); if (m == 0xFFFFFFFF) return -ETIMEDOUT; msg = (u32 *)(iop->mem_offset + m); bucket_count = (total >= priv->sgl_max) ? priv->sgl_max : total; total -= bucket_count; atomic_add(bucket_count, &priv->buckets_out); dprintk(KERN_INFO "%s: Sending %d buckets (size %d) to LAN DDM.\n", dev->name, bucket_count, bucket_len); /* Fill in the header */ __raw_writel(I2O_MESSAGE_SIZE(4 + 3 * bucket_count) | SGL_OFFSET_4, msg); __raw_writel(LAN_RECEIVE_POST<<24 | HOST_TID<<12 | i2o_dev->lct_data.tid, msg+1); __raw_writel(priv->unit << 16 | lan_receive_context, msg+2); __raw_writel(bucket_count, msg+3); sgl_elem = &msg[4]; /* Fill in the payload - contains bucket_count SGL elements */ while (bucket_count--) { spin_lock_irqsave(&priv->fbl_lock, flags); if (priv->i2o_fbl_tail >= 0) skb = priv->i2o_fbl[priv->i2o_fbl_tail--]; else { skb = dev_alloc_skb(bucket_len + 2); if (skb == NULL) { spin_unlock_irqrestore(&priv->fbl_lock, flags); return -ENOMEM; } skb_reserve(skb, 2); } spin_unlock_irqrestore(&priv->fbl_lock, flags); __raw_writel(0x51000000 | bucket_len, sgl_elem); __raw_writel((u32)skb, sgl_elem+1); __raw_writel(virt_to_bus(skb->data), sgl_elem+2); sgl_elem += 3; } /* set LE flag and post */ __raw_writel(__raw_readl(sgl_elem-3) | 0x80000000, (sgl_elem-3)); i2o_post_message(iop, m); } return 0; } /* Functions called from the network stack, and functions called by them: ========================================================================*/ /* * i2o_lan_reset(): Reset the LAN adapter into the operational state and * restore it to full operation. */ static int i2o_lan_reset(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 msg[5]; dprintk(KERN_INFO "%s: LAN RESET MESSAGE.\n", dev->name); msg[0] = FIVE_WORD_MSG_SIZE | SGL_OFFSET_0; msg[1] = LAN_RESET<<24 | HOST_TID<<12 | i2o_dev->lct_data.tid; msg[2] = priv->unit << 16 | lan_context; // InitiatorContext msg[3] = 0; // TransactionContext msg[4] = 0; // Keep posted buckets if (i2o_post_this(iop, msg, sizeof(msg)) < 0) return -ETIMEDOUT; return 0; } /* * i2o_lan_suspend(): Put LAN adapter into a safe, non-active state. * IOP replies to any LAN class message with status error_no_data_transfer * / suspended. */ static int i2o_lan_suspend(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 msg[5]; dprintk(KERN_INFO "%s: LAN SUSPEND MESSAGE.\n", dev->name); msg[0] = FIVE_WORD_MSG_SIZE | SGL_OFFSET_0; msg[1] = LAN_SUSPEND<<24 | HOST_TID<<12 | i2o_dev->lct_data.tid; msg[2] = priv->unit << 16 | lan_context; // InitiatorContext msg[3] = 0; // TransactionContext msg[4] = 1 << 16; // return posted buckets if (i2o_post_this(iop, msg, sizeof(msg)) < 0) return -ETIMEDOUT; return 0; } /* * i2o_set_ddm_parameters: * These settings are done to ensure proper initial values for DDM. * They can be changed via proc file system or vai configuration utility. */ static void i2o_set_ddm_parameters(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 val; /* * When PacketOrphanlimit is set to the maximum packet length, * the packets will never be split into two separate buckets */ val = dev->mtu + dev->hard_header_len; if (i2o_set_scalar(iop, i2o_dev->lct_data.tid, 0x0004, 2, &val, sizeof(val)) < 0) printk(KERN_WARNING "%s: Unable to set PacketOrphanLimit.\n", dev->name); else dprintk(KERN_INFO "%s: PacketOrphanLimit set to %d.\n", dev->name, val); /* When RxMaxPacketsBucket = 1, DDM puts only one packet into bucket */ val = 1; if (i2o_set_scalar(iop, i2o_dev->lct_data.tid, 0x0008, 4, &val, sizeof(val)) <0) printk(KERN_WARNING "%s: Unable to set RxMaxPacketsBucket.\n", dev->name); else dprintk(KERN_INFO "%s: RxMaxPacketsBucket set to %d.\n", dev->name, val); return; } /* Functions called from the network stack: ==========================================*/ /* * i2o_lan_open(): Open the device to send/receive packets via * the network device. */ static int i2o_lan_open(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 mc_addr_group[64]; MOD_INC_USE_COUNT; if (i2o_claim_device(i2o_dev, &i2o_lan_handler)) { printk(KERN_WARNING "%s: Unable to claim the I2O LAN device.\n", dev->name); MOD_DEC_USE_COUNT; return -EAGAIN; } dprintk(KERN_INFO "%s: I2O LAN device (tid=%d) claimed by LAN OSM.\n", dev->name, i2o_dev->lct_data.tid); if (i2o_event_register(iop, i2o_dev->lct_data.tid, priv->unit << 16 | lan_context, 0, priv->i2o_event_mask) < 0) printk(KERN_WARNING "%s: Unable to set the event mask.\n", dev->name); i2o_lan_reset(dev); /* Get the max number of multicast addresses */ if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0001, -1, &mc_addr_group, sizeof(mc_addr_group)) < 0 ) { printk(KERN_WARNING "%s: Unable to query LAN_MAC_ADDRESS group.\n", dev->name); MOD_DEC_USE_COUNT; return -EAGAIN; } priv->max_size_mc_table = mc_addr_group[8]; /* Malloc space for free bucket list to resuse reveive post buckets */ priv->i2o_fbl = kmalloc(priv->max_buckets_out * sizeof(struct sk_buff *), GFP_KERNEL); if (priv->i2o_fbl == NULL) { MOD_DEC_USE_COUNT; return -ENOMEM; } priv->i2o_fbl_tail = -1; priv->send_active = 0; i2o_set_ddm_parameters(dev); i2o_lan_receive_post(dev); netif_start_queue(dev); return 0; } /* * i2o_lan_close(): End the transfering. */ static int i2o_lan_close(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; int ret = 0; netif_stop_queue(dev); i2o_lan_suspend(dev); if (i2o_event_register(iop, i2o_dev->lct_data.tid, priv->unit << 16 | lan_context, 0, 0) < 0) printk(KERN_WARNING "%s: Unable to clear the event mask.\n", dev->name); while (priv->i2o_fbl_tail >= 0) dev_kfree_skb(priv->i2o_fbl[priv->i2o_fbl_tail--]); kfree(priv->i2o_fbl); if (i2o_release_device(i2o_dev, &i2o_lan_handler)) { printk(KERN_WARNING "%s: Unable to unclaim I2O LAN device " "(tid=%d).\n", dev->name, i2o_dev->lct_data.tid); ret = -EBUSY; } MOD_DEC_USE_COUNT; return ret; } /* * i2o_lan_tx_timeout(): Tx timeout handler. */ static void i2o_lan_tx_timeout(struct net_device *dev) { if (!netif_queue_stopped(dev)) netif_start_queue(dev); } /* * i2o_lan_batch_send(): Send packets in batch. * Both i2o_lan_sdu_send and i2o_lan_packet_send use this. */ static void i2o_lan_batch_send(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_controller *iop = priv->i2o_dev->controller; spin_lock_irq(&priv->tx_lock); if (priv->tx_count != 0) { dev->trans_start = jiffies; i2o_post_message(iop, priv->m); dprintk(KERN_DEBUG "%s: %d packets sent.\n", dev->name, priv->tx_count); priv->tx_count = 0; } priv->send_active = 0; spin_unlock_irq(&priv->tx_lock); MOD_DEC_USE_COUNT; } #ifdef CONFIG_NET_FC /* * i2o_lan_sdu_send(): Send a packet, MAC header added by the DDM. * Must be supported by Fibre Channel, optional for Ethernet/802.3, * Token Ring, FDDI */ static int i2o_lan_sdu_send(struct sk_buff *skb, struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; int tickssofar = jiffies - dev->trans_start; u32 m, *msg; u32 *sgl_elem; spin_lock_irq(&priv->tx_lock); priv->tx_count++; atomic_inc(&priv->tx_out); /* * If tx_batch_mode = 0x00 forced to immediate mode * If tx_batch_mode = 0x01 forced to batch mode * If tx_batch_mode = 0x10 switch automatically, current mode immediate * If tx_batch_mode = 0x11 switch automatically, current mode batch * If gap between two packets is > 0 ticks, switch to immediate */ if (priv->tx_batch_mode >> 1) // switch automatically priv->tx_batch_mode = tickssofar ? 0x02 : 0x03; if (priv->tx_count == 1) { m = I2O_POST_READ32(iop); if (m == 0xFFFFFFFF) { spin_unlock_irq(&priv->tx_lock); return 1; } msg = (u32 *)(iop->mem_offset + m); priv->m = m; __raw_writel(NINE_WORD_MSG_SIZE | 1<<12 | SGL_OFFSET_4, msg); __raw_writel(LAN_PACKET_SEND<<24 | HOST_TID<<12 | i2o_dev->lct_data.tid, msg+1); __raw_writel(priv->unit << 16 | lan_send_context, msg+2); // InitiatorContext __raw_writel(1 << 30 | 1 << 3, msg+3); // TransmitControlWord __raw_writel(0xD7000000 | skb->len, msg+4); // MAC hdr included __raw_writel((u32)skb, msg+5); // TransactionContext __raw_writel(virt_to_bus(skb->data), msg+6); __raw_writel((u32)skb->mac.raw, msg+7); __raw_writel((u32)skb->mac.raw+4, msg+8); if ((priv->tx_batch_mode & 0x01) && !priv->send_active) { priv->send_active = 1; MOD_INC_USE_COUNT; if (schedule_task(&priv->i2o_batch_send_task) == 0) MOD_DEC_USE_COUNT; } } else { /* Add new SGL element to the previous message frame */ msg = (u32 *)(iop->mem_offset + priv->m); sgl_elem = &msg[priv->tx_count * 5 + 1]; __raw_writel(I2O_MESSAGE_SIZE((__raw_readl(msg)>>16) + 5) | 1<<12 | SGL_OFFSET_4, msg); __raw_writel(__raw_readl(sgl_elem-5) & 0x7FFFFFFF, sgl_elem-5); /* clear LE flag */ __raw_writel(0xD5000000 | skb->len, sgl_elem); __raw_writel((u32)skb, sgl_elem+1); __raw_writel(virt_to_bus(skb->data), sgl_elem+2); __raw_writel((u32)(skb->mac.raw), sgl_elem+3); __raw_writel((u32)(skb->mac.raw)+1, sgl_elem+4); } /* If tx not in batch mode or frame is full, send immediatelly */ if (!(priv->tx_batch_mode & 0x01) || priv->tx_count == priv->sgl_max) { dev->trans_start = jiffies; i2o_post_message(iop, priv->m); dprintk(KERN_DEBUG "%s: %d packets sent.\n", dev->name, priv->tx_count); priv->tx_count = 0; } /* If DDMs TxMaxPktOut reached, stop queueing layer to send more */ if (atomic_read(&priv->tx_out) >= priv->tx_max_out) netif_stop_queue(dev); spin_unlock_irq(&priv->tx_lock); return 0; } #endif /* CONFIG_NET_FC */ /* * i2o_lan_packet_send(): Send a packet as is, including the MAC header. * * Must be supported by Ethernet/802.3, Token Ring, FDDI, optional for * Fibre Channel */ static int i2o_lan_packet_send(struct sk_buff *skb, struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; int tickssofar = jiffies - dev->trans_start; u32 m, *msg; u32 *sgl_elem; spin_lock_irq(&priv->tx_lock); priv->tx_count++; atomic_inc(&priv->tx_out); /* * If tx_batch_mode = 0x00 forced to immediate mode * If tx_batch_mode = 0x01 forced to batch mode * If tx_batch_mode = 0x10 switch automatically, current mode immediate * If tx_batch_mode = 0x11 switch automatically, current mode batch * If gap between two packets is > 0 ticks, switch to immediate */ if (priv->tx_batch_mode >> 1) // switch automatically priv->tx_batch_mode = tickssofar ? 0x02 : 0x03; if (priv->tx_count == 1) { m = I2O_POST_READ32(iop); if (m == 0xFFFFFFFF) { spin_unlock_irq(&priv->tx_lock); return 1; } msg = (u32 *)(iop->mem_offset + m); priv->m = m; __raw_writel(SEVEN_WORD_MSG_SIZE | 1<<12 | SGL_OFFSET_4, msg); __raw_writel(LAN_PACKET_SEND<<24 | HOST_TID<<12 | i2o_dev->lct_data.tid, msg+1); __raw_writel(priv->unit << 16 | lan_send_context, msg+2); // InitiatorContext __raw_writel(1 << 30 | 1 << 3, msg+3); // TransmitControlWord // bit 30: reply as soon as transmission attempt is complete // bit 3: Suppress CRC generation __raw_writel(0xD5000000 | skb->len, msg+4); // MAC hdr included __raw_writel((u32)skb, msg+5); // TransactionContext __raw_writel(virt_to_bus(skb->data), msg+6); if ((priv->tx_batch_mode & 0x01) && !priv->send_active) { priv->send_active = 1; MOD_INC_USE_COUNT; if (schedule_task(&priv->i2o_batch_send_task) == 0) MOD_DEC_USE_COUNT; } } else { /* Add new SGL element to the previous message frame */ msg = (u32 *)(iop->mem_offset + priv->m); sgl_elem = &msg[priv->tx_count * 3 + 1]; __raw_writel(I2O_MESSAGE_SIZE((__raw_readl(msg)>>16) + 3) | 1<<12 | SGL_OFFSET_4, msg); __raw_writel(__raw_readl(sgl_elem-3) & 0x7FFFFFFF, sgl_elem-3); /* clear LE flag */ __raw_writel(0xD5000000 | skb->len, sgl_elem); __raw_writel((u32)skb, sgl_elem+1); __raw_writel(virt_to_bus(skb->data), sgl_elem+2); } /* If tx is in immediate mode or frame is full, send now */ if (!(priv->tx_batch_mode & 0x01) || priv->tx_count == priv->sgl_max) { dev->trans_start = jiffies; i2o_post_message(iop, priv->m); dprintk(KERN_DEBUG "%s: %d packets sent.\n", dev->name, priv->tx_count); priv->tx_count = 0; } /* If DDMs TxMaxPktOut reached, stop queueing layer to send more */ if (atomic_read(&priv->tx_out) >= priv->tx_max_out) netif_stop_queue(dev); spin_unlock_irq(&priv->tx_lock); return 0; } /* * i2o_lan_get_stats(): Fill in the statistics. */ static struct net_device_stats *i2o_lan_get_stats(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u64 val64[16]; u64 supported_group[4] = { 0, 0, 0, 0 }; if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0100, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_HISTORICAL_STATS.\n", dev->name); else { dprintk(KERN_DEBUG "%s: LAN_HISTORICAL_STATS queried.\n", dev->name); priv->stats.tx_packets = val64[0]; priv->stats.tx_bytes = val64[1]; priv->stats.rx_packets = val64[2]; priv->stats.rx_bytes = val64[3]; priv->stats.tx_errors = val64[4]; priv->stats.rx_errors = val64[5]; priv->stats.rx_dropped = val64[6]; } if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0180, -1, &supported_group, sizeof(supported_group)) < 0) printk(KERN_INFO "%s: Unable to query LAN_SUPPORTED_OPTIONAL_HISTORICAL_STATS.\n", dev->name); if (supported_group[2]) { if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0183, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_OPTIONAL_RX_HISTORICAL_STATS.\n", dev->name); else { dprintk(KERN_DEBUG "%s: LAN_OPTIONAL_RX_HISTORICAL_STATS queried.\n", dev->name); priv->stats.multicast = val64[4]; priv->stats.rx_length_errors = val64[10]; priv->stats.rx_crc_errors = val64[0]; } } if (i2o_dev->lct_data.sub_class == I2O_LAN_ETHERNET) { u64 supported_stats = 0; if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0200, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_802_3_HISTORICAL_STATS.\n", dev->name); else { dprintk(KERN_DEBUG "%s: LAN_802_3_HISTORICAL_STATS queried.\n", dev->name); priv->stats.transmit_collision = val64[1] + val64[2]; priv->stats.rx_frame_errors = val64[0]; priv->stats.tx_carrier_errors = val64[6]; } if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0280, -1, &supported_stats, sizeof(supported_stats)) < 0) printk(KERN_INFO "%s: Unable to query LAN_SUPPORTED_802_3_HISTORICAL_STATS.\n", dev->name); if (supported_stats != 0) { if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0281, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_OPTIONAL_802_3_HISTORICAL_STATS.\n", dev->name); else { dprintk(KERN_DEBUG "%s: LAN_OPTIONAL_802_3_HISTORICAL_STATS queried.\n", dev->name); if (supported_stats & 0x1) priv->stats.rx_over_errors = val64[0]; if (supported_stats & 0x4) priv->stats.tx_heartbeat_errors = val64[2]; } } } #ifdef CONFIG_TR if (i2o_dev->lct_data.sub_class == I2O_LAN_TR) { if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0300, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_802_5_HISTORICAL_STATS.\n", dev->name); else { struct tr_statistics *stats = (struct tr_statistics *)&priv->stats; dprintk(KERN_DEBUG "%s: LAN_802_5_HISTORICAL_STATS queried.\n", dev->name); stats->line_errors = val64[0]; stats->internal_errors = val64[7]; stats->burst_errors = val64[4]; stats->A_C_errors = val64[2]; stats->abort_delimiters = val64[3]; stats->lost_frames = val64[1]; /* stats->recv_congest_count = ?; FIXME ??*/ stats->frame_copied_errors = val64[5]; stats->frequency_errors = val64[6]; stats->token_errors = val64[9]; } /* Token Ring optional stats not yet defined */ } #endif #ifdef CONFIG_FDDI if (i2o_dev->lct_data.sub_class == I2O_LAN_FDDI) { if (i2o_query_scalar(iop, i2o_dev->lct_data.tid, 0x0400, -1, val64, sizeof(val64)) < 0) printk(KERN_INFO "%s: Unable to query LAN_FDDI_HISTORICAL_STATS.\n", dev->name); else { dprintk(KERN_DEBUG "%s: LAN_FDDI_HISTORICAL_STATS queried.\n", dev->name); priv->stats.smt_cf_state = val64[0]; memcpy(priv->stats.mac_upstream_nbr, &val64[1], FDDI_K_ALEN); memcpy(priv->stats.mac_downstream_nbr, &val64[2], FDDI_K_ALEN); priv->stats.mac_error_cts = val64[3]; priv->stats.mac_lost_cts = val64[4]; priv->stats.mac_rmt_state = val64[5]; memcpy(priv->stats.port_lct_fail_cts, &val64[6], 8); memcpy(priv->stats.port_lem_reject_cts, &val64[7], 8); memcpy(priv->stats.port_lem_cts, &val64[8], 8); memcpy(priv->stats.port_pcm_state, &val64[9], 8); } /* FDDI optional stats not yet defined */ } #endif #ifdef CONFIG_NET_FC /* Fibre Channel Statistics not yet defined in 1.53 nor 2.0 */ #endif return (struct net_device_stats *)&priv->stats; } /* * i2o_lan_set_mc_filter(): Post a request to set multicast filter. */ int i2o_lan_set_mc_filter(struct net_device *dev, u32 filter_mask) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; u32 msg[10]; msg[0] = TEN_WORD_MSG_SIZE | SGL_OFFSET_5; msg[1] = I2O_CMD_UTIL_PARAMS_SET << 24 | HOST_TID << 12 | i2o_dev->lct_data.tid; msg[2] = priv->unit << 16 | lan_context; msg[3] = 0x0001 << 16 | 3 ; // TransactionContext: group&field msg[4] = 0; msg[5] = 0xCC000000 | 16; // Immediate data SGL msg[6] = 1; // OperationCount msg[7] = 0x0001<<16 | I2O_PARAMS_FIELD_SET; // Group, Operation msg[8] = 3 << 16 | 1; // FieldIndex, FieldCount msg[9] = filter_mask; // Value return i2o_post_this(iop, msg, sizeof(msg)); } /* * i2o_lan_set_mc_table(): Post a request to set LAN_MULTICAST_MAC_ADDRESS table. */ int i2o_lan_set_mc_table(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; struct i2o_controller *iop = i2o_dev->controller; struct dev_mc_list *mc; u32 msg[10 + 2 * dev->mc_count]; u8 *work8 = (u8 *)(msg + 10); msg[0] = I2O_MESSAGE_SIZE(10 + 2 * dev->mc_count) | SGL_OFFSET_5; msg[1] = I2O_CMD_UTIL_PARAMS_SET << 24 | HOST_TID << 12 | i2o_dev->lct_data.tid; msg[2] = priv->unit << 16 | lan_context; // InitiatorContext msg[3] = 0x0002 << 16 | (u16)-1; // TransactionContext msg[4] = 0; // OperationFlags msg[5] = 0xCC000000 | (16 + 8 * dev->mc_count); // Immediate data SGL msg[6] = 2; // OperationCount msg[7] = 0x0002 << 16 | I2O_PARAMS_TABLE_CLEAR; // Group, Operation msg[8] = 0x0002 << 16 | I2O_PARAMS_ROW_ADD; // Group, Operation msg[9] = dev->mc_count << 16 | (u16)-1; // RowCount, FieldCount for (mc = dev->mc_list; mc ; mc = mc->next, work8 += 8) { memset(work8, 0, 8); memcpy(work8, mc->dmi_addr, mc->dmi_addrlen); // Values } return i2o_post_this(iop, msg, sizeof(msg)); } /* * i2o_lan_set_multicast_list(): Enable a network device to receive packets * not send to the protocol address. */ static void i2o_lan_set_multicast_list(struct net_device *dev) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; u32 filter_mask; if (dev->flags & IFF_PROMISC) { filter_mask = 0x00000002; dprintk(KERN_INFO "%s: Enabling promiscuous mode...\n", dev->name); } else if ((dev->flags & IFF_ALLMULTI) || dev->mc_count > priv->max_size_mc_table) { filter_mask = 0x00000004; dprintk(KERN_INFO "%s: Enabling all multicast mode...\n", dev->name); } else if (dev->mc_count) { filter_mask = 0x00000000; dprintk(KERN_INFO "%s: Enabling multicast mode...\n", dev->name); if (i2o_lan_set_mc_table(dev) < 0) printk(KERN_WARNING "%s: Unable to send MAC table.\n", dev->name); } else { filter_mask = 0x00000300; // Broadcast, Multicast disabled dprintk(KERN_INFO "%s: Enabling unicast mode...\n", dev->name); } /* Finally copy new FilterMask to DDM */ if (i2o_lan_set_mc_filter(dev, filter_mask) < 0) printk(KERN_WARNING "%s: Unable to send MAC FilterMask.\n", dev->name); } /* * i2o_lan_change_mtu(): Change maximum transfer unit size. */ static int i2o_lan_change_mtu(struct net_device *dev, int new_mtu) { struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; u32 max_pkt_size; if (i2o_query_scalar(i2o_dev->controller, i2o_dev->lct_data.tid, 0x0000, 6, &max_pkt_size, 4) < 0) return -EFAULT; if (new_mtu < 68 || new_mtu > 9000 || new_mtu > max_pkt_size) return -EINVAL; dev->mtu = new_mtu; i2o_lan_suspend(dev); // to SUSPENDED state, return buckets while (priv->i2o_fbl_tail >= 0) // free buffered buckets dev_kfree_skb(priv->i2o_fbl[priv->i2o_fbl_tail--]); i2o_lan_reset(dev); // to OPERATIONAL state i2o_set_ddm_parameters(dev); // reset some parameters i2o_lan_receive_post(dev); // post new buckets (new size) return 0; } /* Functions to initialize I2O LAN OSM: ======================================*/ /* * i2o_lan_register_device(): Register LAN class device to kernel. */ struct net_device *i2o_lan_register_device(struct i2o_device *i2o_dev) { struct net_device *dev = NULL; struct i2o_lan_local *priv = NULL; u8 hw_addr[8]; u32 tx_max_out = 0; unsigned short (*type_trans)(struct sk_buff *, struct net_device *); void (*unregister_dev)(struct net_device *dev); switch (i2o_dev->lct_data.sub_class) { case I2O_LAN_ETHERNET: dev = init_etherdev(NULL, sizeof(struct i2o_lan_local)); if (dev == NULL) return NULL; type_trans = eth_type_trans; unregister_dev = unregister_netdev; break; #ifdef CONFIG_ANYLAN case I2O_LAN_100VG: printk(KERN_ERR "i2o_lan: 100base VG not yet supported.\n"); return NULL; break; #endif #ifdef CONFIG_TR case I2O_LAN_TR: dev = init_trdev(NULL, sizeof(struct i2o_lan_local)); if (dev==NULL) return NULL; type_trans = tr_type_trans; unregister_dev = unregister_trdev; break; #endif #ifdef CONFIG_FDDI case I2O_LAN_FDDI: { int size = sizeof(struct net_device) + sizeof(struct i2o_lan_local); dev = (struct net_device *) kmalloc(size, GFP_KERNEL); if (dev == NULL) return NULL; memset((char *)dev, 0, size); dev->priv = (void *)(dev + 1); if (dev_alloc_name(dev, "fddi%d") < 0) { printk(KERN_WARNING "i2o_lan: Too many FDDI devices.\n"); kfree(dev); return NULL; } type_trans = fddi_type_trans; unregister_dev = (void *)unregister_netdevice; fddi_setup(dev); register_netdev(dev); } break; #endif #ifdef CONFIG_NET_FC case I2O_LAN_FIBRE_CHANNEL: dev = init_fcdev(NULL, sizeof(struct i2o_lan_local)); if (dev == NULL) return NULL; type_trans = NULL; /* FIXME: Move fc_type_trans() from drivers/net/fc/iph5526.c to net/802/fc.c * and export it in include/linux/fcdevice.h * type_trans = fc_type_trans; */ unregister_dev = (void *)unregister_fcdev; break; #endif case I2O_LAN_UNKNOWN: default: printk(KERN_ERR "i2o_lan: LAN type 0x%04x not supported.\n", i2o_dev->lct_data.sub_class); return NULL; } priv = (struct i2o_lan_local *)dev->priv; priv->i2o_dev = i2o_dev; priv->type_trans = type_trans; priv->sgl_max = (i2o_dev->controller->status_block->inbound_frame_size - 4) / 3; atomic_set(&priv->buckets_out, 0); /* Set default values for user configurable parameters */ /* Private values are changed via /proc file system */ priv->max_buckets_out = max_buckets_out; priv->bucket_thresh = bucket_thresh; priv->rx_copybreak = rx_copybreak; priv->tx_batch_mode = tx_batch_mode & 0x03; priv->i2o_event_mask = i2o_event_mask; priv->tx_lock = SPIN_LOCK_UNLOCKED; priv->fbl_lock = SPIN_LOCK_UNLOCKED; unit++; i2o_landevs[unit] = dev; priv->unit = unit; if (i2o_query_scalar(i2o_dev->controller, i2o_dev->lct_data.tid, 0x0001, 0, &hw_addr, sizeof(hw_addr)) < 0) { printk(KERN_ERR "%s: Unable to query hardware address.\n", dev->name); unit--; unregister_dev(dev); kfree(dev); return NULL; } dprintk(KERN_DEBUG "%s: hwaddr = %02X:%02X:%02X:%02X:%02X:%02X\n", dev->name, hw_addr[0], hw_addr[1], hw_addr[2], hw_addr[3], hw_addr[4], hw_addr[5]); dev->addr_len = 6; memcpy(dev->dev_addr, hw_addr, 6); if (i2o_query_scalar(i2o_dev->controller, i2o_dev->lct_data.tid, 0x0007, 2, &tx_max_out, sizeof(tx_max_out)) < 0) { printk(KERN_ERR "%s: Unable to query max TX queue.\n", dev->name); unit--; unregister_dev(dev); kfree(dev); return NULL; } dprintk(KERN_INFO "%s: Max TX Outstanding = %d.\n", dev->name, tx_max_out); priv->tx_max_out = tx_max_out; atomic_set(&priv->tx_out, 0); priv->tx_count = 0; INIT_LIST_HEAD(&priv->i2o_batch_send_task.list); priv->i2o_batch_send_task.sync = 0; priv->i2o_batch_send_task.routine = (void *)i2o_lan_batch_send; priv->i2o_batch_send_task.data = (void *)dev; dev->open = i2o_lan_open; dev->stop = i2o_lan_close; dev->get_stats = i2o_lan_get_stats; dev->set_multicast_list = i2o_lan_set_multicast_list; dev->tx_timeout = i2o_lan_tx_timeout; dev->watchdog_timeo = I2O_LAN_TX_TIMEOUT; #ifdef CONFIG_NET_FC if (i2o_dev->lct_data.sub_class == I2O_LAN_FIBRE_CHANNEL) dev->hard_start_xmit = i2o_lan_sdu_send; else #endif dev->hard_start_xmit = i2o_lan_packet_send; if (i2o_dev->lct_data.sub_class == I2O_LAN_ETHERNET) dev->change_mtu = i2o_lan_change_mtu; return dev; } #ifdef MODULE #define i2o_lan_init init_module #endif int __init i2o_lan_init(void) { struct net_device *dev; int i; printk(KERN_INFO "I2O LAN OSM (C) 1999 University of Helsinki.\n"); /* Module params are used as global defaults for private values */ if (max_buckets_out > I2O_LAN_MAX_BUCKETS_OUT) max_buckets_out = I2O_LAN_MAX_BUCKETS_OUT; if (bucket_thresh > max_buckets_out) bucket_thresh = max_buckets_out; /* Install handlers for incoming replies */ if (i2o_install_handler(&i2o_lan_send_handler) < 0) { printk(KERN_ERR "i2o_lan: Unable to register I2O LAN OSM.\n"); return -EINVAL; } lan_send_context = i2o_lan_send_handler.context; if (i2o_install_handler(&i2o_lan_receive_handler) < 0) { printk(KERN_ERR "i2o_lan: Unable to register I2O LAN OSM.\n"); return -EINVAL; } lan_receive_context = i2o_lan_receive_handler.context; if (i2o_install_handler(&i2o_lan_handler) < 0) { printk(KERN_ERR "i2o_lan: Unable to register I2O LAN OSM.\n"); return -EINVAL; } lan_context = i2o_lan_handler.context; for(i=0; i <= MAX_LAN_CARDS; i++) i2o_landevs[i] = NULL; for (i=0; i < MAX_I2O_CONTROLLERS; i++) { struct i2o_controller *iop = i2o_find_controller(i); struct i2o_device *i2o_dev; if (iop==NULL) continue; for (i2o_dev=iop->devices;i2o_dev != NULL;i2o_dev=i2o_dev->next) { if (i2o_dev->lct_data.class_id != I2O_CLASS_LAN) continue; /* Make sure device not already claimed by an ISM */ if (i2o_dev->lct_data.user_tid != 0xFFF) continue; if (unit == MAX_LAN_CARDS) { i2o_unlock_controller(iop); printk(KERN_WARNING "i2o_lan: Too many I2O LAN devices.\n"); return -EINVAL; } dev = i2o_lan_register_device(i2o_dev); if (dev == NULL) { printk(KERN_ERR "i2o_lan: Unable to register I2O LAN device 0x%04x.\n", i2o_dev->lct_data.sub_class); continue; } printk(KERN_INFO "%s: I2O LAN device registered, " "subclass = 0x%04x, unit = %d, tid = %d.\n", dev->name, i2o_dev->lct_data.sub_class, ((struct i2o_lan_local *)dev->priv)->unit, i2o_dev->lct_data.tid); } i2o_unlock_controller(iop); } dprintk(KERN_INFO "%d I2O LAN devices found and registered.\n", unit+1); return 0; } #ifdef MODULE void cleanup_module(void) { int i; for (i = 0; i <= unit; i++) { struct net_device *dev = i2o_landevs[i]; struct i2o_lan_local *priv = (struct i2o_lan_local *)dev->priv; struct i2o_device *i2o_dev = priv->i2o_dev; switch (i2o_dev->lct_data.sub_class) { case I2O_LAN_ETHERNET: unregister_netdev(dev); break; #ifdef CONFIG_FDDI case I2O_LAN_FDDI: unregister_netdevice(dev); break; #endif #ifdef CONFIG_TR case I2O_LAN_TR: unregister_trdev(dev); break; #endif #ifdef CONFIG_NET_FC case I2O_LAN_FIBRE_CHANNEL: unregister_fcdev(dev); break; #endif default: printk(KERN_WARNING "%s: Spurious I2O LAN subclass 0x%08x.\n", dev->name, i2o_dev->lct_data.sub_class); } dprintk(KERN_INFO "%s: I2O LAN device unregistered.\n", dev->name); kfree(dev); } i2o_remove_handler(&i2o_lan_handler); i2o_remove_handler(&i2o_lan_send_handler); i2o_remove_handler(&i2o_lan_receive_handler); } EXPORT_NO_SYMBOLS; MODULE_AUTHOR("University of Helsinki, Department of Computer Science"); MODULE_DESCRIPTION("I2O Lan OSM"); MODULE_LICENSE("GPL"); MODULE_PARM(max_buckets_out, "1-" __MODULE_STRING(I2O_LAN_MAX_BUCKETS_OUT) "i"); MODULE_PARM_DESC(max_buckets_out, "Total number of buckets to post (1-)"); MODULE_PARM(bucket_thresh, "1-" __MODULE_STRING(I2O_LAN_MAX_BUCKETS_OUT) "i"); MODULE_PARM_DESC(bucket_thresh, "Bucket post threshold (1-)"); MODULE_PARM(rx_copybreak, "1-" "i"); MODULE_PARM_DESC(rx_copybreak, "Copy breakpoint for copy only small frames (1-)"); MODULE_PARM(tx_batch_mode, "0-2" "i"); MODULE_PARM_DESC(tx_batch_mode, "0=Send immediatelly, 1=Send in batches, 2=Switch automatically"); #endif