/****************************************************************************** iphase.c: Device driver for Interphase ATM PCI adapter cards Author: Peter Wang Some fixes: Arnaldo Carvalho de Melo Interphase Corporation Version: 1.0 ******************************************************************************* This software may be used and distributed according to the terms of the GNU General Public License (GPL), incorporated herein by reference. Drivers based on this skeleton fall under the GPL and must retain the authorship (implicit copyright) notice. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. Modified from an incomplete driver for Interphase 5575 1KVC 1M card which was originally written by Monalisa Agrawal at UNH. Now this driver supports a variety of varients of Interphase ATM PCI (i)Chip adapter card family (See www.iphase.com/products/ClassSheet.cfm?ClassID=ATM) in terms of PHY type, the size of control memory and the size of packet memory. The followings are the change log and history: Bugfix the Mona's UBR driver. Modify the basic memory allocation and dma logic. Port the driver to the latest kernel from 2.0.46. Complete the ABR logic of the driver, and added the ABR work- around for the hardware anormalies. Add the CBR support. Add the flow control logic to the driver to allow rate-limit VC. Add 4K VC support to the board with 512K control memory. Add the support of all the variants of the Interphase ATM PCI (i)Chip adapter cards including x575 (155M OC3 and UTP155), x525 (25M UTP25) and x531 (DS3 and E3). Add SMP support. Support and updates available at: ftp://ftp.iphase.com/pub/atm *******************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "iphase.h" #include "suni.h" #define swap_byte_order(x) (((x & 0xff) << 8) | ((x & 0xff00) >> 8)) #define PRIV(dev) ((struct suni_priv *) dev->phy_data) static unsigned char ia_phy_get(struct atm_dev *dev, unsigned long addr); static void desc_dbg(IADEV *iadev); static IADEV *ia_dev[8]; static struct atm_dev *_ia_dev[8]; static int iadev_count; static void ia_led_timer(unsigned long arg); static DEFINE_TIMER(ia_timer, ia_led_timer, 0, 0); static int IA_TX_BUF = DFL_TX_BUFFERS, IA_TX_BUF_SZ = DFL_TX_BUF_SZ; static int IA_RX_BUF = DFL_RX_BUFFERS, IA_RX_BUF_SZ = DFL_RX_BUF_SZ; static uint IADebugFlag = /* IF_IADBG_ERR | IF_IADBG_CBR| IF_IADBG_INIT_ADAPTER |IF_IADBG_ABR | IF_IADBG_EVENT*/ 0; module_param(IA_TX_BUF, int, 0); module_param(IA_TX_BUF_SZ, int, 0); module_param(IA_RX_BUF, int, 0); module_param(IA_RX_BUF_SZ, int, 0); module_param(IADebugFlag, uint, 0644); MODULE_LICENSE("GPL"); /**************************** IA_LIB **********************************/ static void ia_init_rtn_q (IARTN_Q *que) { que->next = NULL; que->tail = NULL; } static void ia_enque_head_rtn_q (IARTN_Q *que, IARTN_Q * data) { data->next = NULL; if (que->next == NULL) que->next = que->tail = data; else { data->next = que->next; que->next = data; } return; } static int ia_enque_rtn_q (IARTN_Q *que, struct desc_tbl_t data) { IARTN_Q *entry = kmalloc(sizeof(*entry), GFP_ATOMIC); if (!entry) return -1; entry->data = data; entry->next = NULL; if (que->next == NULL) que->next = que->tail = entry; else { que->tail->next = entry; que->tail = que->tail->next; } return 1; } static IARTN_Q * ia_deque_rtn_q (IARTN_Q *que) { IARTN_Q *tmpdata; if (que->next == NULL) return NULL; tmpdata = que->next; if ( que->next == que->tail) que->next = que->tail = NULL; else que->next = que->next->next; return tmpdata; } static void ia_hack_tcq(IADEV *dev) { u_short desc1; u_short tcq_wr; struct ia_vcc *iavcc_r = NULL; tcq_wr = readl(dev->seg_reg+TCQ_WR_PTR) & 0xffff; while (dev->host_tcq_wr != tcq_wr) { desc1 = *(u_short *)(dev->seg_ram + dev->host_tcq_wr); if (!desc1) ; else if (!dev->desc_tbl[desc1 -1].timestamp) { IF_ABR(printk(" Desc %d is reset at %ld\n", desc1 -1, jiffies);) *(u_short *) (dev->seg_ram + dev->host_tcq_wr) = 0; } else if (dev->desc_tbl[desc1 -1].timestamp) { if (!(iavcc_r = dev->desc_tbl[desc1 -1].iavcc)) { printk("IA: Fatal err in get_desc\n"); continue; } iavcc_r->vc_desc_cnt--; dev->desc_tbl[desc1 -1].timestamp = 0; IF_EVENT(printk("ia_hack: return_q skb = 0x%p desc = %d\n", dev->desc_tbl[desc1 -1].txskb, desc1);) if (iavcc_r->pcr < dev->rate_limit) { IA_SKB_STATE (dev->desc_tbl[desc1-1].txskb) |= IA_TX_DONE; if (ia_enque_rtn_q(&dev->tx_return_q, dev->desc_tbl[desc1 -1]) < 0) printk("ia_hack_tcq: No memory available\n"); } dev->desc_tbl[desc1 -1].iavcc = NULL; dev->desc_tbl[desc1 -1].txskb = NULL; } dev->host_tcq_wr += 2; if (dev->host_tcq_wr > dev->ffL.tcq_ed) dev->host_tcq_wr = dev->ffL.tcq_st; } } /* ia_hack_tcq */ static u16 get_desc (IADEV *dev, struct ia_vcc *iavcc) { u_short desc_num, i; struct sk_buff *skb; struct ia_vcc *iavcc_r = NULL; unsigned long delta; static unsigned long timer = 0; int ltimeout; ia_hack_tcq (dev); if((time_after(jiffies,timer+50)) || ((dev->ffL.tcq_rd==dev->host_tcq_wr))) { timer = jiffies; i=0; while (i < dev->num_tx_desc) { if (!dev->desc_tbl[i].timestamp) { i++; continue; } ltimeout = dev->desc_tbl[i].iavcc->ltimeout; delta = jiffies - dev->desc_tbl[i].timestamp; if (delta >= ltimeout) { IF_ABR(printk("RECOVER run!! desc_tbl %d = %d delta = %ld, time = %ld\n", i,dev->desc_tbl[i].timestamp, delta, jiffies);) if (dev->ffL.tcq_rd == dev->ffL.tcq_st) dev->ffL.tcq_rd = dev->ffL.tcq_ed; else dev->ffL.tcq_rd -= 2; *(u_short *)(dev->seg_ram + dev->ffL.tcq_rd) = i+1; if (!(skb = dev->desc_tbl[i].txskb) || !(iavcc_r = dev->desc_tbl[i].iavcc)) printk("Fatal err, desc table vcc or skb is NULL\n"); else iavcc_r->vc_desc_cnt--; dev->desc_tbl[i].timestamp = 0; dev->desc_tbl[i].iavcc = NULL; dev->desc_tbl[i].txskb = NULL; } i++; } /* while */ } if (dev->ffL.tcq_rd == dev->host_tcq_wr) return 0xFFFF; /* Get the next available descriptor number from TCQ */ desc_num = *(u_short *)(dev->seg_ram + dev->ffL.tcq_rd); while (!desc_num || (dev->desc_tbl[desc_num -1]).timestamp) { dev->ffL.tcq_rd += 2; if (dev->ffL.tcq_rd > dev->ffL.tcq_ed) dev->ffL.tcq_rd = dev->ffL.tcq_st; if (dev->ffL.tcq_rd == dev->host_tcq_wr) return 0xFFFF; desc_num = *(u_short *)(dev->seg_ram + dev->ffL.tcq_rd); } /* get system time */ dev->desc_tbl[desc_num -1].timestamp = jiffies; return desc_num; } static void clear_lockup (struct atm_vcc *vcc, IADEV *dev) { u_char foundLockUp; vcstatus_t *vcstatus; u_short *shd_tbl; u_short tempCellSlot, tempFract; struct main_vc *abr_vc = (struct main_vc *)dev->MAIN_VC_TABLE_ADDR; struct ext_vc *eabr_vc = (struct ext_vc *)dev->EXT_VC_TABLE_ADDR; u_int i; if (vcc->qos.txtp.traffic_class == ATM_ABR) { vcstatus = (vcstatus_t *) &(dev->testTable[vcc->vci]->vc_status); vcstatus->cnt++; foundLockUp = 0; if( vcstatus->cnt == 0x05 ) { abr_vc += vcc->vci; eabr_vc += vcc->vci; if( eabr_vc->last_desc ) { if( (abr_vc->status & 0x07) == ABR_STATE /* 0x2 */ ) { /* Wait for 10 Micro sec */ udelay(10); if ((eabr_vc->last_desc)&&((abr_vc->status & 0x07)==ABR_STATE)) foundLockUp = 1; } else { tempCellSlot = abr_vc->last_cell_slot; tempFract = abr_vc->fraction; if((tempCellSlot == dev->testTable[vcc->vci]->lastTime) && (tempFract == dev->testTable[vcc->vci]->fract)) foundLockUp = 1; dev->testTable[vcc->vci]->lastTime = tempCellSlot; dev->testTable[vcc->vci]->fract = tempFract; } } /* last descriptor */ vcstatus->cnt = 0; } /* vcstatus->cnt */ if (foundLockUp) { IF_ABR(printk("LOCK UP found\n");) writew(0xFFFD, dev->seg_reg+MODE_REG_0); /* Wait for 10 Micro sec */ udelay(10); abr_vc->status &= 0xFFF8; abr_vc->status |= 0x0001; /* state is idle */ shd_tbl = (u_short *)dev->ABR_SCHED_TABLE_ADDR; for( i = 0; ((i < dev->num_vc) && (shd_tbl[i])); i++ ); if (i < dev->num_vc) shd_tbl[i] = vcc->vci; else IF_ERR(printk("ABR Seg. may not continue on VC %x\n",vcc->vci);) writew(T_ONLINE, dev->seg_reg+MODE_REG_0); writew(~(TRANSMIT_DONE|TCQ_NOT_EMPTY), dev->seg_reg+SEG_MASK_REG); writew(TRANSMIT_DONE, dev->seg_reg+SEG_INTR_STATUS_REG); vcstatus->cnt = 0; } /* foundLockUp */ } /* if an ABR VC */ } /* ** Conversion of 24-bit cellrate (cells/sec) to 16-bit floating point format. ** ** +----+----+------------------+-------------------------------+ ** | R | NZ | 5-bit exponent | 9-bit mantissa | ** +----+----+------------------+-------------------------------+ ** ** R = reserved (written as 0) ** NZ = 0 if 0 cells/sec; 1 otherwise ** ** if NZ = 1, rate = 1.mmmmmmmmm x 2^(eeeee) cells/sec */ static u16 cellrate_to_float(u32 cr) { #define NZ 0x4000 #define M_BITS 9 /* Number of bits in mantissa */ #define E_BITS 5 /* Number of bits in exponent */ #define M_MASK 0x1ff #define E_MASK 0x1f u16 flot; u32 tmp = cr & 0x00ffffff; int i = 0; if (cr == 0) return 0; while (tmp != 1) { tmp >>= 1; i++; } if (i == M_BITS) flot = NZ | (i << M_BITS) | (cr & M_MASK); else if (i < M_BITS) flot = NZ | (i << M_BITS) | ((cr << (M_BITS - i)) & M_MASK); else flot = NZ | (i << M_BITS) | ((cr >> (i - M_BITS)) & M_MASK); return flot; } #if 0 /* ** Conversion of 16-bit floating point format to 24-bit cellrate (cells/sec). */ static u32 float_to_cellrate(u16 rate) { u32 exp, mantissa, cps; if ((rate & NZ) == 0) return 0; exp = (rate >> M_BITS) & E_MASK; mantissa = rate & M_MASK; if (exp == 0) return 1; cps = (1 << M_BITS) | mantissa; if (exp == M_BITS) cps = cps; else if (exp > M_BITS) cps <<= (exp - M_BITS); else cps >>= (M_BITS - exp); return cps; } #endif static void init_abr_vc (IADEV *dev, srv_cls_param_t *srv_p) { srv_p->class_type = ATM_ABR; srv_p->pcr = dev->LineRate; srv_p->mcr = 0; srv_p->icr = 0x055cb7; srv_p->tbe = 0xffffff; srv_p->frtt = 0x3a; srv_p->rif = 0xf; srv_p->rdf = 0xb; srv_p->nrm = 0x4; srv_p->trm = 0x7; srv_p->cdf = 0x3; srv_p->adtf = 50; } static int ia_open_abr_vc(IADEV *dev, srv_cls_param_t *srv_p, struct atm_vcc *vcc, u8 flag) { f_vc_abr_entry *f_abr_vc; r_vc_abr_entry *r_abr_vc; u32 icr; u8 trm, nrm, crm; u16 adtf, air, *ptr16; f_abr_vc =(f_vc_abr_entry *)dev->MAIN_VC_TABLE_ADDR; f_abr_vc += vcc->vci; switch (flag) { case 1: /* FFRED initialization */ #if 0 /* sanity check */ if (srv_p->pcr == 0) return INVALID_PCR; if (srv_p->pcr > dev->LineRate) srv_p->pcr = dev->LineRate; if ((srv_p->mcr + dev->sum_mcr) > dev->LineRate) return MCR_UNAVAILABLE; if (srv_p->mcr > srv_p->pcr) return INVALID_MCR; if (!(srv_p->icr)) srv_p->icr = srv_p->pcr; if ((srv_p->icr < srv_p->mcr) || (srv_p->icr > srv_p->pcr)) return INVALID_ICR; if ((srv_p->tbe < MIN_TBE) || (srv_p->tbe > MAX_TBE)) return INVALID_TBE; if ((srv_p->frtt < MIN_FRTT) || (srv_p->frtt > MAX_FRTT)) return INVALID_FRTT; if (srv_p->nrm > MAX_NRM) return INVALID_NRM; if (srv_p->trm > MAX_TRM) return INVALID_TRM; if (srv_p->adtf > MAX_ADTF) return INVALID_ADTF; else if (srv_p->adtf == 0) srv_p->adtf = 1; if (srv_p->cdf > MAX_CDF) return INVALID_CDF; if (srv_p->rif > MAX_RIF) return INVALID_RIF; if (srv_p->rdf > MAX_RDF) return INVALID_RDF; #endif memset ((caddr_t)f_abr_vc, 0, sizeof(*f_abr_vc)); f_abr_vc->f_vc_type = ABR; nrm = 2 << srv_p->nrm; /* (2 ** (srv_p->nrm +1)) */ /* i.e 2**n = 2 << (n-1) */ f_abr_vc->f_nrm = nrm << 8 | nrm; trm = 100000/(2 << (16 - srv_p->trm)); if ( trm == 0) trm = 1; f_abr_vc->f_nrmexp =(((srv_p->nrm +1) & 0x0f) << 12)|(MRM << 8) | trm; crm = srv_p->tbe / nrm; if (crm == 0) crm = 1; f_abr_vc->f_crm = crm & 0xff; f_abr_vc->f_pcr = cellrate_to_float(srv_p->pcr); icr = min( srv_p->icr, (srv_p->tbe > srv_p->frtt) ? ((srv_p->tbe/srv_p->frtt)*1000000) : (1000000/(srv_p->frtt/srv_p->tbe))); f_abr_vc->f_icr = cellrate_to_float(icr); adtf = (10000 * srv_p->adtf)/8192; if (adtf == 0) adtf = 1; f_abr_vc->f_cdf = ((7 - srv_p->cdf) << 12 | adtf) & 0xfff; f_abr_vc->f_mcr = cellrate_to_float(srv_p->mcr); f_abr_vc->f_acr = f_abr_vc->f_icr; f_abr_vc->f_status = 0x0042; break; case 0: /* RFRED initialization */ ptr16 = (u_short *)(dev->reass_ram + REASS_TABLE*dev->memSize); *(ptr16 + vcc->vci) = NO_AAL5_PKT | REASS_ABR; r_abr_vc = (r_vc_abr_entry*)(dev->reass_ram+ABR_VC_TABLE*dev->memSize); r_abr_vc += vcc->vci; r_abr_vc->r_status_rdf = (15 - srv_p->rdf) & 0x000f; air = srv_p->pcr << (15 - srv_p->rif); if (air == 0) air = 1; r_abr_vc->r_air = cellrate_to_float(air); dev->testTable[vcc->vci]->vc_status = VC_ACTIVE | VC_ABR; dev->sum_mcr += srv_p->mcr; dev->n_abr++; break; default: break; } return 0; } static int ia_cbr_setup (IADEV *dev, struct atm_vcc *vcc) { u32 rateLow=0, rateHigh, rate; int entries; struct ia_vcc *ia_vcc; int idealSlot =0, testSlot, toBeAssigned, inc; u32 spacing; u16 *SchedTbl, *TstSchedTbl; u16 cbrVC, vcIndex; u32 fracSlot = 0; u32 sp_mod = 0; u32 sp_mod2 = 0; /* IpAdjustTrafficParams */ if (vcc->qos.txtp.max_pcr <= 0) { IF_ERR(printk("PCR for CBR not defined\n");) return -1; } rate = vcc->qos.txtp.max_pcr; entries = rate / dev->Granularity; IF_CBR(printk("CBR: CBR entries=0x%x for rate=0x%x & Gran=0x%x\n", entries, rate, dev->Granularity);) if (entries < 1) IF_CBR(printk("CBR: Bandwidth smaller than granularity of CBR table\n");) rateLow = entries * dev->Granularity; rateHigh = (entries + 1) * dev->Granularity; if (3*(rate - rateLow) > (rateHigh - rate)) entries++; if (entries > dev->CbrRemEntries) { IF_CBR(printk("CBR: Not enough bandwidth to support this PCR.\n");) IF_CBR(printk("Entries = 0x%x, CbrRemEntries = 0x%x.\n", entries, dev->CbrRemEntries);) return -EBUSY; } ia_vcc = INPH_IA_VCC(vcc); ia_vcc->NumCbrEntry = entries; dev->sum_mcr += entries * dev->Granularity; /* IaFFrednInsertCbrSched */ // Starting at an arbitrary location, place the entries into the table // as smoothly as possible cbrVC = 0; spacing = dev->CbrTotEntries / entries; sp_mod = dev->CbrTotEntries % entries; // get modulo toBeAssigned = entries; fracSlot = 0; vcIndex = vcc->vci; IF_CBR(printk("Vci=0x%x,Spacing=0x%x,Sp_mod=0x%x\n",vcIndex,spacing,sp_mod);) while (toBeAssigned) { // If this is the first time, start the table loading for this connection // as close to entryPoint as possible. if (toBeAssigned == entries) { idealSlot = dev->CbrEntryPt; dev->CbrEntryPt += 2; // Adding 2 helps to prevent clumping if (dev->CbrEntryPt >= dev->CbrTotEntries) dev->CbrEntryPt -= dev->CbrTotEntries;// Wrap if necessary } else { idealSlot += (u32)(spacing + fracSlot); // Point to the next location // in the table that would be smoothest fracSlot = ((sp_mod + sp_mod2) / entries); // get new integer part sp_mod2 = ((sp_mod + sp_mod2) % entries); // calc new fractional part } if (idealSlot >= (int)dev->CbrTotEntries) idealSlot -= dev->CbrTotEntries; // Continuously check around this ideal value until a null // location is encountered. SchedTbl = (u16*)(dev->seg_ram+CBR_SCHED_TABLE*dev->memSize); inc = 0; testSlot = idealSlot; TstSchedTbl = (u16*)(SchedTbl+testSlot); //set index and read in value IF_CBR(printk("CBR Testslot 0x%x AT Location 0x%p, NumToAssign=%d\n", testSlot, TstSchedTbl,toBeAssigned);) memcpy((caddr_t)&cbrVC,(caddr_t)TstSchedTbl,sizeof(cbrVC)); while (cbrVC) // If another VC at this location, we have to keep looking { inc++; testSlot = idealSlot - inc; if (testSlot < 0) { // Wrap if necessary testSlot += dev->CbrTotEntries; IF_CBR(printk("Testslot Wrap. STable Start=0x%p,Testslot=%d\n", SchedTbl,testSlot);) } TstSchedTbl = (u16 *)(SchedTbl + testSlot); // set table index memcpy((caddr_t)&cbrVC,(caddr_t)TstSchedTbl,sizeof(cbrVC)); if (!cbrVC) break; testSlot = idealSlot + inc; if (testSlot >= (int)dev->CbrTotEntries) { // Wrap if necessary testSlot -= dev->CbrTotEntries; IF_CBR(printk("TotCbrEntries=%d",dev->CbrTotEntries);) IF_CBR(printk(" Testslot=0x%x ToBeAssgned=%d\n", testSlot, toBeAssigned);) } // set table index and read in value TstSchedTbl = (u16*)(SchedTbl + testSlot); IF_CBR(printk("Reading CBR Tbl from 0x%p, CbrVal=0x%x Iteration %d\n", TstSchedTbl,cbrVC,inc);) memcpy((caddr_t)&cbrVC,(caddr_t)TstSchedTbl,sizeof(cbrVC)); } /* while */ // Move this VCI number into this location of the CBR Sched table. memcpy((caddr_t)TstSchedTbl, (caddr_t)&vcIndex, sizeof(*TstSchedTbl)); dev->CbrRemEntries--; toBeAssigned--; } /* while */ /* IaFFrednCbrEnable */ dev->NumEnabledCBR++; if (dev->NumEnabledCBR == 1) { writew((CBR_EN | UBR_EN | ABR_EN | (0x23 << 2)), dev->seg_reg+STPARMS); IF_CBR(printk("CBR is enabled\n");) } return 0; } static void ia_cbrVc_close (struct atm_vcc *vcc) { IADEV *iadev; u16 *SchedTbl, NullVci = 0; u32 i, NumFound; iadev = INPH_IA_DEV(vcc->dev); iadev->NumEnabledCBR--; SchedTbl = (u16*)(iadev->seg_ram+CBR_SCHED_TABLE*iadev->memSize); if (iadev->NumEnabledCBR == 0) { writew((UBR_EN | ABR_EN | (0x23 << 2)), iadev->seg_reg+STPARMS); IF_CBR (printk("CBR support disabled\n");) } NumFound = 0; for (i=0; i < iadev->CbrTotEntries; i++) { if (*SchedTbl == vcc->vci) { iadev->CbrRemEntries++; *SchedTbl = NullVci; IF_CBR(NumFound++;) } SchedTbl++; } IF_CBR(printk("Exit ia_cbrVc_close, NumRemoved=%d\n",NumFound);) } static int ia_avail_descs(IADEV *iadev) { int tmp = 0; ia_hack_tcq(iadev); if (iadev->host_tcq_wr >= iadev->ffL.tcq_rd) tmp = (iadev->host_tcq_wr - iadev->ffL.tcq_rd) / 2; else tmp = (iadev->ffL.tcq_ed - iadev->ffL.tcq_rd + 2 + iadev->host_tcq_wr - iadev->ffL.tcq_st) / 2; return tmp; } static int ia_pkt_tx (struct atm_vcc *vcc, struct sk_buff *skb); static int ia_que_tx (IADEV *iadev) { struct sk_buff *skb; int num_desc; struct atm_vcc *vcc; num_desc = ia_avail_descs(iadev); while (num_desc && (skb = skb_dequeue(&iadev->tx_backlog))) { if (!(vcc = ATM_SKB(skb)->vcc)) { dev_kfree_skb_any(skb); printk("ia_que_tx: Null vcc\n"); break; } if (!test_bit(ATM_VF_READY,&vcc->flags)) { dev_kfree_skb_any(skb); printk("Free the SKB on closed vci %d \n", vcc->vci); break; } if (ia_pkt_tx (vcc, skb)) { skb_queue_head(&iadev->tx_backlog, skb); } num_desc--; } return 0; } static void ia_tx_poll (IADEV *iadev) { struct atm_vcc *vcc = NULL; struct sk_buff *skb = NULL, *skb1 = NULL; struct ia_vcc *iavcc; IARTN_Q * rtne; ia_hack_tcq(iadev); while ( (rtne = ia_deque_rtn_q(&iadev->tx_return_q))) { skb = rtne->data.txskb; if (!skb) { printk("ia_tx_poll: skb is null\n"); goto out; } vcc = ATM_SKB(skb)->vcc; if (!vcc) { printk("ia_tx_poll: vcc is null\n"); dev_kfree_skb_any(skb); goto out; } iavcc = INPH_IA_VCC(vcc); if (!iavcc) { printk("ia_tx_poll: iavcc is null\n"); dev_kfree_skb_any(skb); goto out; } skb1 = skb_dequeue(&iavcc->txing_skb); while (skb1 && (skb1 != skb)) { if (!(IA_SKB_STATE(skb1) & IA_TX_DONE)) { printk("IA_tx_intr: Vci %d lost pkt!!!\n", vcc->vci); } IF_ERR(printk("Release the SKB not match\n");) if ((vcc->pop) && (skb1->len != 0)) { vcc->pop(vcc, skb1); IF_EVENT(printk("Tansmit Done - skb 0x%lx return\n", (long)skb1);) } else dev_kfree_skb_any(skb1); skb1 = skb_dequeue(&iavcc->txing_skb); } if (!skb1) { IF_EVENT(printk("IA: Vci %d - skb not found requed\n",vcc->vci);) ia_enque_head_rtn_q (&iadev->tx_return_q, rtne); break; } if ((vcc->pop) && (skb->len != 0)) { vcc->pop(vcc, skb); IF_EVENT(printk("Tx Done - skb 0x%lx return\n",(long)skb);) } else dev_kfree_skb_any(skb); kfree(rtne); } ia_que_tx(iadev); out: return; } #if 0 static void ia_eeprom_put (IADEV *iadev, u32 addr, u_short val) { u32 t; int i; /* * Issue a command to enable writes to the NOVRAM */ NVRAM_CMD (EXTEND + EWEN); NVRAM_CLR_CE; /* * issue the write command */ NVRAM_CMD(IAWRITE + addr); /* * Send the data, starting with D15, then D14, and so on for 16 bits */ for (i=15; i>=0; i--) { NVRAM_CLKOUT (val & 0x8000); val <<= 1; } NVRAM_CLR_CE; CFG_OR(NVCE); t = readl(iadev->reg+IPHASE5575_EEPROM_ACCESS); while (!(t & NVDO)) t = readl(iadev->reg+IPHASE5575_EEPROM_ACCESS); NVRAM_CLR_CE; /* * disable writes again */ NVRAM_CMD(EXTEND + EWDS) NVRAM_CLR_CE; CFG_AND(~NVDI); } #endif static u16 ia_eeprom_get (IADEV *iadev, u32 addr) { u_short val; u32 t; int i; /* * Read the first bit that was clocked with the falling edge of the * the last command data clock */ NVRAM_CMD(IAREAD + addr); /* * Now read the rest of the bits, the next bit read is D14, then D13, * and so on. */ val = 0; for (i=15; i>=0; i--) { NVRAM_CLKIN(t); val |= (t << i); } NVRAM_CLR_CE; CFG_AND(~NVDI); return val; } static void ia_hw_type(IADEV *iadev) { u_short memType = ia_eeprom_get(iadev, 25); iadev->memType = memType; if ((memType & MEM_SIZE_MASK) == MEM_SIZE_1M) { iadev->num_tx_desc = IA_TX_BUF; iadev->tx_buf_sz = IA_TX_BUF_SZ; iadev->num_rx_desc = IA_RX_BUF; iadev->rx_buf_sz = IA_RX_BUF_SZ; } else if ((memType & MEM_SIZE_MASK) == MEM_SIZE_512K) { if (IA_TX_BUF == DFL_TX_BUFFERS) iadev->num_tx_desc = IA_TX_BUF / 2; else iadev->num_tx_desc = IA_TX_BUF; iadev->tx_buf_sz = IA_TX_BUF_SZ; if (IA_RX_BUF == DFL_RX_BUFFERS) iadev->num_rx_desc = IA_RX_BUF / 2; else iadev->num_rx_desc = IA_RX_BUF; iadev->rx_buf_sz = IA_RX_BUF_SZ; } else { if (IA_TX_BUF == DFL_TX_BUFFERS) iadev->num_tx_desc = IA_TX_BUF / 8; else iadev->num_tx_desc = IA_TX_BUF; iadev->tx_buf_sz = IA_TX_BUF_SZ; if (IA_RX_BUF == DFL_RX_BUFFERS) iadev->num_rx_desc = IA_RX_BUF / 8; else iadev->num_rx_desc = IA_RX_BUF; iadev->rx_buf_sz = IA_RX_BUF_SZ; } iadev->rx_pkt_ram = TX_PACKET_RAM + (iadev->num_tx_desc * iadev->tx_buf_sz); IF_INIT(printk("BUF: tx=%d,sz=%d rx=%d sz= %d rx_pkt_ram=%d\n", iadev->num_tx_desc, iadev->tx_buf_sz, iadev->num_rx_desc, iadev->rx_buf_sz, iadev->rx_pkt_ram);) #if 0 if ((memType & FE_MASK) == FE_SINGLE_MODE) { iadev->phy_type = PHY_OC3C_S; else if ((memType & FE_MASK) == FE_UTP_OPTION) iadev->phy_type = PHY_UTP155; else iadev->phy_type = PHY_OC3C_M; #endif iadev->phy_type = memType & FE_MASK; IF_INIT(printk("memType = 0x%x iadev->phy_type = 0x%x\n", memType,iadev->phy_type);) if (iadev->phy_type == FE_25MBIT_PHY) iadev->LineRate = (u32)(((25600000/8)*26)/(27*53)); else if (iadev->phy_type == FE_DS3_PHY) iadev->LineRate = (u32)(((44736000/8)*26)/(27*53)); else if (iadev->phy_type == FE_E3_PHY) iadev->LineRate = (u32)(((34368000/8)*26)/(27*53)); else iadev->LineRate = (u32)(ATM_OC3_PCR); IF_INIT(printk("iadev->LineRate = %d \n", iadev->LineRate);) } static u32 ia_phy_read32(struct iadev_priv *ia, unsigned int reg) { return readl(ia->phy + (reg >> 2)); } static void ia_phy_write32(struct iadev_priv *ia, unsigned int reg, u32 val) { writel(val, ia->phy + (reg >> 2)); } static void ia_frontend_intr(struct iadev_priv *iadev) { u32 status; if (iadev->phy_type & FE_25MBIT_PHY) { status = ia_phy_read32(iadev, MB25_INTR_STATUS); iadev->carrier_detect = (status & MB25_IS_GSB) ? 1 : 0; } else if (iadev->phy_type & FE_DS3_PHY) { ia_phy_read32(iadev, SUNI_DS3_FRM_INTR_STAT); status = ia_phy_read32(iadev, SUNI_DS3_FRM_STAT); iadev->carrier_detect = (status & SUNI_DS3_LOSV) ? 0 : 1; } else if (iadev->phy_type & FE_E3_PHY) { ia_phy_read32(iadev, SUNI_E3_FRM_MAINT_INTR_IND); status = ia_phy_read32(iadev, SUNI_E3_FRM_FRAM_INTR_IND_STAT); iadev->carrier_detect = (status & SUNI_E3_LOS) ? 0 : 1; } else { status = ia_phy_read32(iadev, SUNI_RSOP_STATUS); iadev->carrier_detect = (status & SUNI_LOSV) ? 0 : 1; } printk(KERN_INFO "IA: SUNI carrier %s\n", iadev->carrier_detect ? "detected" : "lost signal"); } static void ia_mb25_init(struct iadev_priv *iadev) { #if 0 mb25->mb25_master_ctrl = MB25_MC_DRIC | MB25_MC_DREC | MB25_MC_ENABLED; #endif ia_phy_write32(iadev, MB25_MASTER_CTRL, MB25_MC_DRIC | MB25_MC_DREC); ia_phy_write32(iadev, MB25_DIAG_CONTROL, 0); iadev->carrier_detect = (ia_phy_read32(iadev, MB25_INTR_STATUS) & MB25_IS_GSB) ? 1 : 0; } struct ia_reg { u16 reg; u16 val; }; static void ia_phy_write(struct iadev_priv *iadev, const struct ia_reg *regs, int len) { while (len--) { ia_phy_write32(iadev, regs->reg, regs->val); regs++; } } static void ia_suni_pm7345_init_ds3(struct iadev_priv *iadev) { static const struct ia_reg suni_ds3_init [] = { { SUNI_DS3_FRM_INTR_ENBL, 0x17 }, { SUNI_DS3_FRM_CFG, 0x01 }, { SUNI_DS3_TRAN_CFG, 0x01 }, { SUNI_CONFIG, 0 }, { SUNI_SPLR_CFG, 0 }, { SUNI_SPLT_CFG, 0 } }; u32 status; status = ia_phy_read32(iadev, SUNI_DS3_FRM_STAT); iadev->carrier_detect = (status & SUNI_DS3_LOSV) ? 0 : 1; ia_phy_write(iadev, suni_ds3_init, ARRAY_SIZE(suni_ds3_init)); } static void ia_suni_pm7345_init_e3(struct iadev_priv *iadev) { static const struct ia_reg suni_e3_init [] = { { SUNI_E3_FRM_FRAM_OPTIONS, 0x04 }, { SUNI_E3_FRM_MAINT_OPTIONS, 0x20 }, { SUNI_E3_FRM_FRAM_INTR_ENBL, 0x1d }, { SUNI_E3_FRM_MAINT_INTR_ENBL, 0x30 }, { SUNI_E3_TRAN_STAT_DIAG_OPTIONS, 0 }, { SUNI_E3_TRAN_FRAM_OPTIONS, 0x01 }, { SUNI_CONFIG, SUNI_PM7345_E3ENBL }, { SUNI_SPLR_CFG, 0x41 }, { SUNI_SPLT_CFG, 0x41 } }; u32 status; status = ia_phy_read32(iadev, SUNI_E3_FRM_FRAM_INTR_IND_STAT); iadev->carrier_detect = (status & SUNI_E3_LOS) ? 0 : 1; ia_phy_write(iadev, suni_e3_init, ARRAY_SIZE(suni_e3_init)); } static void ia_suni_pm7345_init(struct iadev_priv *iadev) { static const struct ia_reg suni_init [] = { /* Enable RSOP loss of signal interrupt. */ { SUNI_INTR_ENBL, 0x28 }, /* Clear error counters. */ { SUNI_ID_RESET, 0 }, /* Clear "PMCTST" in master test register. */ { SUNI_MASTER_TEST, 0 }, { SUNI_RXCP_CTRL, 0x2c }, { SUNI_RXCP_FCTRL, 0x81 }, { SUNI_RXCP_IDLE_PAT_H1, 0 }, { SUNI_RXCP_IDLE_PAT_H2, 0 }, { SUNI_RXCP_IDLE_PAT_H3, 0 }, { SUNI_RXCP_IDLE_PAT_H4, 0x01 }, { SUNI_RXCP_IDLE_MASK_H1, 0xff }, { SUNI_RXCP_IDLE_MASK_H2, 0xff }, { SUNI_RXCP_IDLE_MASK_H3, 0xff }, { SUNI_RXCP_IDLE_MASK_H4, 0xfe }, { SUNI_RXCP_CELL_PAT_H1, 0 }, { SUNI_RXCP_CELL_PAT_H2, 0 }, { SUNI_RXCP_CELL_PAT_H3, 0 }, { SUNI_RXCP_CELL_PAT_H4, 0x01 }, { SUNI_RXCP_CELL_MASK_H1, 0xff }, { SUNI_RXCP_CELL_MASK_H2, 0xff }, { SUNI_RXCP_CELL_MASK_H3, 0xff }, { SUNI_RXCP_CELL_MASK_H4, 0xff }, { SUNI_TXCP_CTRL, 0xa4 }, { SUNI_TXCP_INTR_EN_STS, 0x10 }, { SUNI_TXCP_IDLE_PAT_H5, 0x55 } }; if (iadev->phy_type & FE_DS3_PHY) ia_suni_pm7345_init_ds3(iadev); else ia_suni_pm7345_init_e3(iadev); ia_phy_write(iadev, suni_init, ARRAY_SIZE(suni_init)); ia_phy_write32(iadev, SUNI_CONFIG, ia_phy_read32(iadev, SUNI_CONFIG) & ~(SUNI_PM7345_LLB | SUNI_PM7345_CLB | SUNI_PM7345_DLB | SUNI_PM7345_PLB)); #ifdef __SNMP__ suni_pm7345->suni_rxcp_intr_en_sts |= SUNI_OOCDE; #endif /* __SNMP__ */ return; } /***************************** IA_LIB END *****************************/ #ifdef CONFIG_ATM_IA_DEBUG static int tcnter = 0; static void xdump( u_char* cp, int length, char* prefix ) { int col, count; u_char prntBuf[120]; u_char* pBuf = prntBuf; count = 0; while(count < length){ pBuf += sprintf( pBuf, "%s", prefix ); for(col = 0;count + col < length && col < 16; col++){ if (col != 0 && (col % 4) == 0) pBuf += sprintf( pBuf, " " ); pBuf += sprintf( pBuf, "%02X ", cp[count + col] ); } while(col++ < 16){ /* pad end of buffer with blanks */ if ((col % 4) == 0) sprintf( pBuf, " " ); pBuf += sprintf( pBuf, " " ); } pBuf += sprintf( pBuf, " " ); for(col = 0;count + col < length && col < 16; col++){ if (isprint((int)cp[count + col])) pBuf += sprintf( pBuf, "%c", cp[count + col] ); else pBuf += sprintf( pBuf, "." ); } printk("%s\n", prntBuf); count += col; pBuf = prntBuf; } } /* close xdump(... */ #endif /* CONFIG_ATM_IA_DEBUG */ static struct atm_dev *ia_boards = NULL; #define ACTUAL_RAM_BASE \ RAM_BASE*((iadev->mem)/(128 * 1024)) #define ACTUAL_SEG_RAM_BASE \ IPHASE5575_FRAG_CONTROL_RAM_BASE*((iadev->mem)/(128 * 1024)) #define ACTUAL_REASS_RAM_BASE \ IPHASE5575_REASS_CONTROL_RAM_BASE*((iadev->mem)/(128 * 1024)) /*-- some utilities and memory allocation stuff will come here -------------*/ static void desc_dbg(IADEV *iadev) { u_short tcq_wr_ptr, tcq_st_ptr, tcq_ed_ptr; u32 i; void __iomem *tmp; // regval = readl((u32)ia_cmds->maddr); tcq_wr_ptr = readw(iadev->seg_reg+TCQ_WR_PTR); printk("B_tcq_wr = 0x%x desc = %d last desc = %d\n", tcq_wr_ptr, readw(iadev->seg_ram+tcq_wr_ptr), readw(iadev->seg_ram+tcq_wr_ptr-2)); printk(" host_tcq_wr = 0x%x host_tcq_rd = 0x%x \n", iadev->host_tcq_wr, iadev->ffL.tcq_rd); tcq_st_ptr = readw(iadev->seg_reg+TCQ_ST_ADR); tcq_ed_ptr = readw(iadev->seg_reg+TCQ_ED_ADR); printk("tcq_st_ptr = 0x%x tcq_ed_ptr = 0x%x \n", tcq_st_ptr, tcq_ed_ptr); i = 0; while (tcq_st_ptr != tcq_ed_ptr) { tmp = iadev->seg_ram+tcq_st_ptr; printk("TCQ slot %d desc = %d Addr = %p\n", i++, readw(tmp), tmp); tcq_st_ptr += 2; } for(i=0; i num_tx_desc; i++) printk("Desc_tbl[%d] = %d \n", i, iadev->desc_tbl[i].timestamp); } /*----------------------------- Receiving side stuff --------------------------*/ static void rx_excp_rcvd(struct atm_dev *dev) { #if 0 /* closing the receiving size will cause too many excp int */ IADEV *iadev; u_short state; u_short excpq_rd_ptr; //u_short *ptr; int vci, error = 1; iadev = INPH_IA_DEV(dev); state = readl(iadev->reass_reg + STATE_REG) & 0xffff; while((state & EXCPQ_EMPTY) != EXCPQ_EMPTY) { printk("state = %x \n", state); excpq_rd_ptr = readw(iadev->reass_reg + EXCP_Q_RD_PTR) & 0xffff; printk("state = %x excpq_rd_ptr = %x \n", state, excpq_rd_ptr); if (excpq_rd_ptr == *(u16*)(iadev->reass_reg + EXCP_Q_WR_PTR)) IF_ERR(printk("excpq_rd_ptr is wrong!!!\n");) // TODO: update exception stat vci = readw(iadev->reass_ram+excpq_rd_ptr); error = readw(iadev->reass_ram+excpq_rd_ptr+2) & 0x0007; // pwang_test excpq_rd_ptr += 4; if (excpq_rd_ptr > (readw(iadev->reass_reg + EXCP_Q_ED_ADR)& 0xffff)) excpq_rd_ptr = readw(iadev->reass_reg + EXCP_Q_ST_ADR)& 0xffff; writew( excpq_rd_ptr, iadev->reass_reg + EXCP_Q_RD_PTR); state = readl(iadev->reass_reg + STATE_REG) & 0xffff; } #endif } static void free_desc(struct atm_dev *dev, int desc) { IADEV *iadev; iadev = INPH_IA_DEV(dev); writew(desc, iadev->reass_ram+iadev->rfL.fdq_wr); iadev->rfL.fdq_wr +=2; if (iadev->rfL.fdq_wr > iadev->rfL.fdq_ed) iadev->rfL.fdq_wr = iadev->rfL.fdq_st; writew(iadev->rfL.fdq_wr, iadev->reass_reg+FREEQ_WR_PTR); } static int rx_pkt(struct atm_dev *dev) { IADEV *iadev; struct atm_vcc *vcc; unsigned short status; struct rx_buf_desc __iomem *buf_desc_ptr; int desc; struct dle* wr_ptr; int len; struct sk_buff *skb; u_int buf_addr, dma_addr; iadev = INPH_IA_DEV(dev); if (iadev->rfL.pcq_rd == (readw(iadev->reass_reg+PCQ_WR_PTR)&0xffff)) { printk(KERN_ERR DEV_LABEL "(itf %d) Receive queue empty\n", dev->number); return -EINVAL; } /* mask 1st 3 bits to get the actual descno. */ desc = readw(iadev->reass_ram+iadev->rfL.pcq_rd) & 0x1fff; IF_RX(printk("reass_ram = %p iadev->rfL.pcq_rd = 0x%x desc = %d\n", iadev->reass_ram, iadev->rfL.pcq_rd, desc); printk(" pcq_wr_ptr = 0x%x\n", readw(iadev->reass_reg+PCQ_WR_PTR)&0xffff);) /* update the read pointer - maybe we shud do this in the end*/ if ( iadev->rfL.pcq_rd== iadev->rfL.pcq_ed) iadev->rfL.pcq_rd = iadev->rfL.pcq_st; else iadev->rfL.pcq_rd += 2; writew(iadev->rfL.pcq_rd, iadev->reass_reg+PCQ_RD_PTR); /* get the buffer desc entry. update stuff. - doesn't seem to be any update necessary */ buf_desc_ptr = iadev->RX_DESC_BASE_ADDR; /* make the ptr point to the corresponding buffer desc entry */ buf_desc_ptr += desc; if (!desc || (desc > iadev->num_rx_desc) || ((buf_desc_ptr->vc_index & 0xffff) > iadev->num_vc)) { free_desc(dev, desc); IF_ERR(printk("IA: bad descriptor desc = %d \n", desc);) return -1; } vcc = iadev->rx_open[buf_desc_ptr->vc_index & 0xffff]; if (!vcc) { free_desc(dev, desc); printk("IA: null vcc, drop PDU\n"); return -1; } /* might want to check the status bits for errors */ status = (u_short) (buf_desc_ptr->desc_mode); if (status & (RX_CER | RX_PTE | RX_OFL)) { atomic_inc(&vcc->stats->rx_err); IF_ERR(printk("IA: bad packet, dropping it");) if (status & RX_CER) { IF_ERR(printk(" cause: packet CRC error\n");) } else if (status & RX_PTE) { IF_ERR(printk(" cause: packet time out\n");) } else { IF_ERR(printk(" cause: buffer overflow\n");) } goto out_free_desc; } /* build DLE. */ buf_addr = (buf_desc_ptr->buf_start_hi << 16) | buf_desc_ptr->buf_start_lo; dma_addr = (buf_desc_ptr->dma_start_hi << 16) | buf_desc_ptr->dma_start_lo; len = dma_addr - buf_addr; if (len > iadev->rx_buf_sz) { printk("Over %d bytes sdu received, dropped!!!\n", iadev->rx_buf_sz); atomic_inc(&vcc->stats->rx_err); goto out_free_desc; } if (!(skb = atm_alloc_charge(vcc, len, GFP_ATOMIC))) { if (vcc->vci < 32) printk("Drop control packets\n"); goto out_free_desc; } skb_put(skb,len); // pwang_test ATM_SKB(skb)->vcc = vcc; ATM_DESC(skb) = desc; skb_queue_tail(&iadev->rx_dma_q, skb); /* Build the DLE structure */ wr_ptr = iadev->rx_dle_q.write; wr_ptr->sys_pkt_addr = pci_map_single(iadev->pci, skb->data, len, PCI_DMA_FROMDEVICE); wr_ptr->local_pkt_addr = buf_addr; wr_ptr->bytes = len; /* We don't know this do we ?? */ wr_ptr->mode = DMA_INT_ENABLE; /* shud take care of wrap around here too. */ if(++wr_ptr == iadev->rx_dle_q.end) wr_ptr = iadev->rx_dle_q.start; iadev->rx_dle_q.write = wr_ptr; udelay(1); /* Increment transaction counter */ writel(1, iadev->dma+IPHASE5575_RX_COUNTER); out: return 0; out_free_desc: free_desc(dev, desc); goto out; } static void rx_intr(struct atm_dev *dev) { IADEV *iadev; u_short status; u_short state, i; iadev = INPH_IA_DEV(dev); status = readl(iadev->reass_reg+REASS_INTR_STATUS_REG) & 0xffff; IF_EVENT(printk("rx_intr: status = 0x%x\n", status);) if (status & RX_PKT_RCVD) { /* do something */ /* Basically recvd an interrupt for receiving a packet. A descriptor would have been written to the packet complete queue. Get all the descriptors and set up dma to move the packets till the packet complete queue is empty.. */ state = readl(iadev->reass_reg + STATE_REG) & 0xffff; IF_EVENT(printk("Rx intr status: RX_PKT_RCVD %08x\n", status);) while(!(state & PCQ_EMPTY)) { rx_pkt(dev); state = readl(iadev->reass_reg + STATE_REG) & 0xffff; } iadev->rxing = 1; } if (status & RX_FREEQ_EMPT) { if (iadev->rxing) { iadev->rx_tmp_cnt = iadev->rx_pkt_cnt; iadev->rx_tmp_jif = jiffies; iadev->rxing = 0; } else if ((time_after(jiffies, iadev->rx_tmp_jif + 50)) && ((iadev->rx_pkt_cnt - iadev->rx_tmp_cnt) == 0)) { for (i = 1; i <= iadev->num_rx_desc; i++) free_desc(dev, i); printk("Test logic RUN!!!!\n"); writew( ~(RX_FREEQ_EMPT|RX_EXCP_RCVD),iadev->reass_reg+REASS_MASK_REG); iadev->rxing = 1; } IF_EVENT(printk("Rx intr status: RX_FREEQ_EMPT %08x\n", status);) } if (status & RX_EXCP_RCVD) { /* probably need to handle the exception queue also. */ IF_EVENT(printk("Rx intr status: RX_EXCP_RCVD %08x\n", status);) rx_excp_rcvd(dev); } if (status & RX_RAW_RCVD) { /* need to handle the raw incoming cells. This deepnds on whether we have programmed to receive the raw cells or not. Else ignore. */ IF_EVENT(printk("Rx intr status: RX_RAW_RCVD %08x\n", status);) } } static void rx_dle_intr(struct atm_dev *dev) { IADEV *iadev; struct atm_vcc *vcc; struct sk_buff *skb; int desc; u_short state; struct dle *dle, *cur_dle; u_int dle_lp; int len; iadev = INPH_IA_DEV(dev); /* free all the dles done, that is just update our own dle read pointer - do we really need to do this. Think not. */ /* DMA is done, just get all the recevie buffers from the rx dma queue and push them up to the higher layer protocol. Also free the desc associated with the buffer. */ dle = iadev->rx_dle_q.read; dle_lp = readl(iadev->dma+IPHASE5575_RX_LIST_ADDR) & (sizeof(struct dle)*DLE_ENTRIES - 1); cur_dle = (struct dle*)(iadev->rx_dle_q.start + (dle_lp >> 4)); while(dle != cur_dle) { /* free the DMAed skb */ skb = skb_dequeue(&iadev->rx_dma_q); if (!skb) goto INCR_DLE; desc = ATM_DESC(skb); free_desc(dev, desc); if (!(len = skb->len)) { printk("rx_dle_intr: skb len 0\n"); dev_kfree_skb_any(skb); } else { struct cpcs_trailer *trailer; u_short length; struct ia_vcc *ia_vcc; pci_unmap_single(iadev->pci, iadev->rx_dle_q.write->sys_pkt_addr, len, PCI_DMA_FROMDEVICE); /* no VCC related housekeeping done as yet. lets see */ vcc = ATM_SKB(skb)->vcc; if (!vcc) { printk("IA: null vcc\n"); dev_kfree_skb_any(skb); goto INCR_DLE; } ia_vcc = INPH_IA_VCC(vcc); if (ia_vcc == NULL) { atomic_inc(&vcc->stats->rx_err); atm_return(vcc, skb->truesize); dev_kfree_skb_any(skb); goto INCR_DLE; } // get real pkt length pwang_test trailer = (struct cpcs_trailer*)((u_char *)skb->data + skb->len - sizeof(*trailer)); length = swap_byte_order(trailer->length); if ((length > iadev->rx_buf_sz) || (length > (skb->len - sizeof(struct cpcs_trailer)))) { atomic_inc(&vcc->stats->rx_err); IF_ERR(printk("rx_dle_intr: Bad AAL5 trailer %d (skb len %d)", length, skb->len);) atm_return(vcc, skb->truesize); dev_kfree_skb_any(skb); goto INCR_DLE; } skb_trim(skb, length); /* Display the packet */ IF_RXPKT(printk("\nDmad Recvd data: len = %d \n", skb->len); xdump(skb->data, skb->len, "RX: "); printk("\n");) IF_RX(printk("rx_dle_intr: skb push");) vcc->push(vcc,skb); atomic_inc(&vcc->stats->rx); iadev->rx_pkt_cnt++; } INCR_DLE: if (++dle == iadev->rx_dle_q.end) dle = iadev->rx_dle_q.start; } iadev->rx_dle_q.read = dle; /* if the interrupts are masked because there were no free desc available, unmask them now. */ if (!iadev->rxing) { state = readl(iadev->reass_reg + STATE_REG) & 0xffff; if (!(state & FREEQ_EMPTY)) { state = readl(iadev->reass_reg + REASS_MASK_REG) & 0xffff; writel(state & ~(RX_FREEQ_EMPT |/* RX_EXCP_RCVD |*/ RX_PKT_RCVD), iadev->reass_reg+REASS_MASK_REG); iadev->rxing++; } } } static int open_rx(struct atm_vcc *vcc) { IADEV *iadev; u_short __iomem *vc_table; u_short __iomem *reass_ptr; IF_EVENT(printk("iadev: open_rx %d.%d\n", vcc->vpi, vcc->vci);) if (vcc->qos.rxtp.traffic_class == ATM_NONE) return 0; iadev = INPH_IA_DEV(vcc->dev); if (vcc->qos.rxtp.traffic_class == ATM_ABR) { if (iadev->phy_type & FE_25MBIT_PHY) { printk("IA: ABR not support\n"); return -EINVAL; } } /* Make only this VCI in the vc table valid and let all others be invalid entries */ vc_table = iadev->reass_ram+RX_VC_TABLE*iadev->memSize; vc_table += vcc->vci; /* mask the last 6 bits and OR it with 3 for 1K VCs */ *vc_table = vcc->vci << 6; /* Also keep a list of open rx vcs so that we can attach them with incoming PDUs later. */ if ((vcc->qos.rxtp.traffic_class == ATM_ABR) || (vcc->qos.txtp.traffic_class == ATM_ABR)) { srv_cls_param_t srv_p; init_abr_vc(iadev, &srv_p); ia_open_abr_vc(iadev, &srv_p, vcc, 0); } else { /* for UBR later may need to add CBR logic */ reass_ptr = iadev->reass_ram+REASS_TABLE*iadev->memSize; reass_ptr += vcc->vci; *reass_ptr = NO_AAL5_PKT; } if (iadev->rx_open[vcc->vci]) printk(KERN_CRIT DEV_LABEL "(itf %d): VCI %d already open\n", vcc->dev->number, vcc->vci); iadev->rx_open[vcc->vci] = vcc; return 0; } static int rx_init(struct atm_dev *dev) { IADEV *iadev; struct rx_buf_desc __iomem *buf_desc_ptr; unsigned long rx_pkt_start = 0; void *dle_addr; struct abr_vc_table *abr_vc_table; u16 *vc_table; u16 *reass_table; int i,j, vcsize_sel; u_short freeq_st_adr; u_short *freeq_start; iadev = INPH_IA_DEV(dev); // spin_lock_init(&iadev->rx_lock); /* Allocate 4k bytes - more aligned than needed (4k boundary) */ dle_addr = pci_alloc_consistent(iadev->pci, DLE_TOTAL_SIZE, &iadev->rx_dle_dma); if (!dle_addr) { printk(KERN_ERR DEV_LABEL "can't allocate DLEs\n"); goto err_out; } iadev->rx_dle_q.start = (struct dle *)dle_addr; iadev->rx_dle_q.read = iadev->rx_dle_q.start; iadev->rx_dle_q.write = iadev->rx_dle_q.start; iadev->rx_dle_q.end = (struct dle*)((unsigned long)dle_addr+sizeof(struct dle)*DLE_ENTRIES); /* the end of the dle q points to the entry after the last DLE that can be used. */ /* write the upper 20 bits of the start address to rx list address register */ /* We know this is 32bit bus addressed so the following is safe */ writel(iadev->rx_dle_dma & 0xfffff000, iadev->dma + IPHASE5575_RX_LIST_ADDR); IF_INIT(printk("Tx Dle list addr: 0x%p value: 0x%0x\n", iadev->dma+IPHASE5575_TX_LIST_ADDR, readl(iadev->dma + IPHASE5575_TX_LIST_ADDR)); printk("Rx Dle list addr: 0x%p value: 0x%0x\n", iadev->dma+IPHASE5575_RX_LIST_ADDR, readl(iadev->dma + IPHASE5575_RX_LIST_ADDR));) writew(0xffff, iadev->reass_reg+REASS_MASK_REG); writew(0, iadev->reass_reg+MODE_REG); writew(RESET_REASS, iadev->reass_reg+REASS_COMMAND_REG); /* Receive side control memory map ------------------------------- Buffer descr 0x0000 (736 - 23K) VP Table 0x5c00 (256 - 512) Except q 0x5e00 (128 - 512) Free buffer q 0x6000 (1K - 2K) Packet comp q 0x6800 (1K - 2K) Reass Table 0x7000 (1K - 2K) VC Table 0x7800 (1K - 2K) ABR VC Table 0x8000 (1K - 32K) */ /* Base address for Buffer Descriptor Table */ writew(RX_DESC_BASE >> 16, iadev->reass_reg+REASS_DESC_BASE); /* Set the buffer size register */ writew(iadev->rx_buf_sz, iadev->reass_reg+BUF_SIZE); /* Initialize each entry in the Buffer Descriptor Table */ iadev->RX_DESC_BASE_ADDR = iadev->reass_ram+RX_DESC_BASE*iadev->memSize; buf_desc_ptr = iadev->RX_DESC_BASE_ADDR; memset_io(buf_desc_ptr, 0, sizeof(*buf_desc_ptr)); buf_desc_ptr++; rx_pkt_start = iadev->rx_pkt_ram; for(i=1; i<=iadev->num_rx_desc; i++) { memset_io(buf_desc_ptr, 0, sizeof(*buf_desc_ptr)); buf_desc_ptr->buf_start_hi = rx_pkt_start >> 16; buf_desc_ptr->buf_start_lo = rx_pkt_start & 0x0000ffff; buf_desc_ptr++; rx_pkt_start += iadev->rx_buf_sz; } IF_INIT(printk("Rx Buffer desc ptr: 0x%p\n", buf_desc_ptr);) i = FREE_BUF_DESC_Q*iadev->memSize; writew(i >> 16, iadev->reass_reg+REASS_QUEUE_BASE); writew(i, iadev->reass_reg+FREEQ_ST_ADR); writew(i+iadev->num_rx_desc*sizeof(u_short), iadev->reass_reg+FREEQ_ED_ADR); writew(i, iadev->reass_reg+FREEQ_RD_PTR); writew(i+iadev->num_rx_desc*sizeof(u_short), iadev->reass_reg+FREEQ_WR_PTR); /* Fill the FREEQ with all the free descriptors. */ freeq_st_adr = readw(iadev->reass_reg+FREEQ_ST_ADR); freeq_start = (u_short *)(iadev->reass_ram+freeq_st_adr); for(i=1; i<=iadev->num_rx_desc; i++) { *freeq_start = (u_short)i; freeq_start++; } IF_INIT(printk("freeq_start: 0x%p\n", freeq_start);) /* Packet Complete Queue */ i = (PKT_COMP_Q * iadev->memSize) & 0xffff; writew(i, iadev->reass_reg+PCQ_ST_ADR); writew(i+iadev->num_vc*sizeof(u_short), iadev->reass_reg+PCQ_ED_ADR); writew(i, iadev->reass_reg+PCQ_RD_PTR); writew(i, iadev->reass_reg+PCQ_WR_PTR); /* Exception Queue */ i = (EXCEPTION_Q * iadev->memSize) & 0xffff; writew(i, iadev->reass_reg+EXCP_Q_ST_ADR); writew(i + NUM_RX_EXCP * sizeof(RX_ERROR_Q), iadev->reass_reg+EXCP_Q_ED_ADR); writew(i, iadev->reass_reg+EXCP_Q_RD_PTR); writew(i, iadev->reass_reg+EXCP_Q_WR_PTR); /* Load local copy of FREEQ and PCQ ptrs */ iadev->rfL.fdq_st = readw(iadev->reass_reg+FREEQ_ST_ADR) & 0xffff; iadev->rfL.fdq_ed = readw(iadev->reass_reg+FREEQ_ED_ADR) & 0xffff ; iadev->rfL.fdq_rd = readw(iadev->reass_reg+FREEQ_RD_PTR) & 0xffff; iadev->rfL.fdq_wr = readw(iadev->reass_reg+FREEQ_WR_PTR) & 0xffff; iadev->rfL.pcq_st = readw(iadev->reass_reg+PCQ_ST_ADR) & 0xffff; iadev->rfL.pcq_ed = readw(iadev->reass_reg+PCQ_ED_ADR) & 0xffff; iadev->rfL.pcq_rd = readw(iadev->reass_reg+PCQ_RD_PTR) & 0xffff; iadev->rfL.pcq_wr = readw(iadev->reass_reg+PCQ_WR_PTR) & 0xffff; IF_INIT(printk("INIT:pcq_st:0x%x pcq_ed:0x%x pcq_rd:0x%x pcq_wr:0x%x", iadev->rfL.pcq_st, iadev->rfL.pcq_ed, iadev->rfL.pcq_rd, iadev->rfL.pcq_wr);) /* just for check - no VP TBL */ /* VP Table */ /* writew(0x0b80, iadev->reass_reg+VP_LKUP_BASE); */ /* initialize VP Table for invalid VPIs - I guess we can write all 1s or 0x000f in the entire memory space or something similar. */ /* This seems to work and looks right to me too !!! */ i = REASS_TABLE * iadev->memSize; writew((i >> 3), iadev->reass_reg+REASS_TABLE_BASE); /* initialize Reassembly table to I don't know what ???? */ reass_table = (u16 *)(iadev->reass_ram+i); j = REASS_TABLE_SZ * iadev->memSize; for(i=0; i < j; i++) *reass_table++ = NO_AAL5_PKT; i = 8*1024; vcsize_sel = 0; while (i != iadev->num_vc) { i /= 2; vcsize_sel++; } i = RX_VC_TABLE * iadev->memSize; writew(((i>>3) & 0xfff8) | vcsize_sel, iadev->reass_reg+VC_LKUP_BASE); vc_table = (u16 *)(iadev->reass_ram+RX_VC_TABLE*iadev->memSize); j = RX_VC_TABLE_SZ * iadev->memSize; for(i = 0; i < j; i++) { /* shift the reassembly pointer by 3 + lower 3 bits of vc_lkup_base register (=3 for 1K VCs) and the last byte is those low 3 bits. Shall program this later. */ *vc_table = (i << 6) | 15; /* for invalid VCI */ vc_table++; } /* ABR VC table */ i = ABR_VC_TABLE * iadev->memSize; writew(i >> 3, iadev->reass_reg+ABR_LKUP_BASE); i = ABR_VC_TABLE * iadev->memSize; abr_vc_table = (struct abr_vc_table *)(iadev->reass_ram+i); j = REASS_TABLE_SZ * iadev->memSize; memset ((char*)abr_vc_table, 0, j * sizeof(*abr_vc_table)); for(i = 0; i < j; i++) { abr_vc_table->rdf = 0x0003; abr_vc_table->air = 0x5eb1; abr_vc_table++; } /* Initialize other registers */ /* VP Filter Register set for VC Reassembly only */ writew(0xff00, iadev->reass_reg+VP_FILTER); writew(0, iadev->reass_reg+XTRA_RM_OFFSET); writew(0x1, iadev->reass_reg+PROTOCOL_ID); /* Packet Timeout Count related Registers : Set packet timeout to occur in about 3 seconds Set Packet Aging Interval count register to overflow in about 4 us */ writew(0xF6F8, iadev->reass_reg+PKT_TM_CNT ); i = (j >> 6) & 0xFF; j += 2 * (j - 1); i |= ((j << 2) & 0xFF00); writew(i, iadev->reass_reg+TMOUT_RANGE); /* initiate the desc_tble */ for(i=0; inum_tx_desc;i++) iadev->desc_tbl[i].timestamp = 0; /* to clear the interrupt status register - read it */ readw(iadev->reass_reg+REASS_INTR_STATUS_REG); /* Mask Register - clear it */ writew(~(RX_FREEQ_EMPT|RX_PKT_RCVD), iadev->reass_reg+REASS_MASK_REG); skb_queue_head_init(&iadev->rx_dma_q); iadev->rx_free_desc_qhead = NULL; iadev->rx_open = kzalloc(4 * iadev->num_vc, GFP_KERNEL); if (!iadev->rx_open) { printk(KERN_ERR DEV_LABEL "itf %d couldn't get free page\n", dev->number); goto err_free_dle; } iadev->rxing = 1; iadev->rx_pkt_cnt = 0; /* Mode Register */ writew(R_ONLINE, iadev->reass_reg+MODE_REG); return 0; err_free_dle: pci_free_consistent(iadev->pci, DLE_TOTAL_SIZE, iadev->rx_dle_q.start, iadev->rx_dle_dma); err_out: return -ENOMEM; } /* The memory map suggested in appendix A and the coding for it. Keeping it around just in case we change our mind later. Buffer descr 0x0000 (128 - 4K) UBR sched 0x1000 (1K - 4K) UBR Wait q 0x2000 (1K - 4K) Commn queues 0x3000 Packet Ready, Trasmit comp(0x3100) (128 - 256) each extended VC 0x4000 (1K - 8K) ABR sched 0x6000 and ABR wait queue (1K - 2K) each CBR sched 0x7000 (as needed) VC table 0x8000 (1K - 32K) */ static void tx_intr(struct atm_dev *dev) { IADEV *iadev; unsigned short status; unsigned long flags; iadev = INPH_IA_DEV(dev); status = readl(iadev->seg_reg+SEG_INTR_STATUS_REG); if (status & TRANSMIT_DONE){ IF_EVENT(printk("Tansmit Done Intr logic run\n");) spin_lock_irqsave(&iadev->tx_lock, flags); ia_tx_poll(iadev); spin_unlock_irqrestore(&iadev->tx_lock, flags); writew(TRANSMIT_DONE, iadev->seg_reg+SEG_INTR_STATUS_REG); if (iadev->close_pending) wake_up(&iadev->close_wait); } if (status & TCQ_NOT_EMPTY) { IF_EVENT(printk("TCQ_NOT_EMPTY int received\n");) } } static void tx_dle_intr(struct atm_dev *dev) { IADEV *iadev; struct dle *dle, *cur_dle; struct sk_buff *skb; struct atm_vcc *vcc; struct ia_vcc *iavcc; u_int dle_lp; unsigned long flags; iadev = INPH_IA_DEV(dev); spin_lock_irqsave(&iadev->tx_lock, flags); dle = iadev->tx_dle_q.read; dle_lp = readl(iadev->dma+IPHASE5575_TX_LIST_ADDR) & (sizeof(struct dle)*DLE_ENTRIES - 1); cur_dle = (struct dle*)(iadev->tx_dle_q.start + (dle_lp >> 4)); while (dle != cur_dle) { /* free the DMAed skb */ skb = skb_dequeue(&iadev->tx_dma_q); if (!skb) break; /* Revenge of the 2 dle (skb + trailer) used in ia_pkt_tx() */ if (!((dle - iadev->tx_dle_q.start)%(2*sizeof(struct dle)))) { pci_unmap_single(iadev->pci, dle->sys_pkt_addr, skb->len, PCI_DMA_TODEVICE); } vcc = ATM_SKB(skb)->vcc; if (!vcc) { printk("tx_dle_intr: vcc is null\n"); spin_unlock_irqrestore(&iadev->tx_lock, flags); dev_kfree_skb_any(skb); return; } iavcc = INPH_IA_VCC(vcc); if (!iavcc) { printk("tx_dle_intr: iavcc is null\n"); spin_unlock_irqrestore(&iadev->tx_lock, flags); dev_kfree_skb_any(skb); return; } if (vcc->qos.txtp.pcr >= iadev->rate_limit) { if ((vcc->pop) && (skb->len != 0)) { vcc->pop(vcc, skb); } else { dev_kfree_skb_any(skb); } } else { /* Hold the rate-limited skb for flow control */ IA_SKB_STATE(skb) |= IA_DLED; skb_queue_tail(&iavcc->txing_skb, skb); } IF_EVENT(printk("tx_dle_intr: enque skb = 0x%p \n", skb);) if (++dle == iadev->tx_dle_q.end) dle = iadev->tx_dle_q.start; } iadev->tx_dle_q.read = dle; spin_unlock_irqrestore(&iadev->tx_lock, flags); } static int open_tx(struct atm_vcc *vcc) { struct ia_vcc *ia_vcc; IADEV *iadev; struct main_vc *vc; struct ext_vc *evc; int ret; IF_EVENT(printk("iadev: open_tx entered vcc->vci = %d\n", vcc->vci);) if (vcc->qos.txtp.traffic_class == ATM_NONE) return 0; iadev = INPH_IA_DEV(vcc->dev); if (iadev->phy_type & FE_25MBIT_PHY) { if (vcc->qos.txtp.traffic_class == ATM_ABR) { printk("IA: ABR not support\n"); return -EINVAL; } if (vcc->qos.txtp.traffic_class == ATM_CBR) { printk("IA: CBR not support\n"); return -EINVAL; } } ia_vcc = INPH_IA_VCC(vcc); memset((caddr_t)ia_vcc, 0, sizeof(*ia_vcc)); if (vcc->qos.txtp.max_sdu > (iadev->tx_buf_sz - sizeof(struct cpcs_trailer))){ printk("IA: SDU size over (%d) the configured SDU size %d\n", vcc->qos.txtp.max_sdu,iadev->tx_buf_sz); vcc->dev_data = NULL; kfree(ia_vcc); return -EINVAL; } ia_vcc->vc_desc_cnt = 0; ia_vcc->txing = 1; /* find pcr */ if (vcc->qos.txtp.max_pcr == ATM_MAX_PCR) vcc->qos.txtp.pcr = iadev->LineRate; else if ((vcc->qos.txtp.max_pcr == 0)&&( vcc->qos.txtp.pcr <= 0)) vcc->qos.txtp.pcr = iadev->LineRate; else if ((vcc->qos.txtp.max_pcr > vcc->qos.txtp.pcr) && (vcc->qos.txtp.max_pcr> 0)) vcc->qos.txtp.pcr = vcc->qos.txtp.max_pcr; if (vcc->qos.txtp.pcr > iadev->LineRate) vcc->qos.txtp.pcr = iadev->LineRate; ia_vcc->pcr = vcc->qos.txtp.pcr; if (ia_vcc->pcr > (iadev->LineRate / 6) ) ia_vcc->ltimeout = HZ / 10; else if (ia_vcc->pcr > (iadev->LineRate / 130)) ia_vcc->ltimeout = HZ; else if (ia_vcc->pcr <= 170) ia_vcc->ltimeout = 16 * HZ; else ia_vcc->ltimeout = 2700 * HZ / ia_vcc->pcr; if (ia_vcc->pcr < iadev->rate_limit) skb_queue_head_init (&ia_vcc->txing_skb); if (ia_vcc->pcr < iadev->rate_limit) { struct sock *sk = sk_atm(vcc); if (vcc->qos.txtp.max_sdu != 0) { if (ia_vcc->pcr > 60000) sk->sk_sndbuf = vcc->qos.txtp.max_sdu * 5; else if (ia_vcc->pcr > 2000) sk->sk_sndbuf = vcc->qos.txtp.max_sdu * 4; else sk->sk_sndbuf = vcc->qos.txtp.max_sdu * 3; } else sk->sk_sndbuf = 24576; } vc = (struct main_vc *)iadev->MAIN_VC_TABLE_ADDR; evc = (struct ext_vc *)iadev->EXT_VC_TABLE_ADDR; vc += vcc->vci; evc += vcc->vci; memset((caddr_t)vc, 0, sizeof(*vc)); memset((caddr_t)evc, 0, sizeof(*evc)); /* store the most significant 4 bits of vci as the last 4 bits of first part of atm header. store the last 12 bits of vci as first 12 bits of the second part of the atm header. */ evc->atm_hdr1 = (vcc->vci >> 12) & 0x000f; evc->atm_hdr2 = (vcc->vci & 0x0fff) << 4; /* check the following for different traffic classes */ if (vcc->qos.txtp.traffic_class == ATM_UBR) { vc->type = UBR; vc->status = CRC_APPEND; vc->acr = cellrate_to_float(iadev->LineRate); if (vcc->qos.txtp.pcr > 0) vc->acr = cellrate_to_float(vcc->qos.txtp.pcr); IF_UBR(printk("UBR: txtp.pcr = 0x%x f_rate = 0x%x\n", vcc->qos.txtp.max_pcr,vc->acr);) } else if (vcc->qos.txtp.traffic_class == ATM_ABR) { srv_cls_param_t srv_p; IF_ABR(printk("Tx ABR VCC\n");) init_abr_vc(iadev, &srv_p); if (vcc->qos.txtp.pcr > 0) srv_p.pcr = vcc->qos.txtp.pcr; if (vcc->qos.txtp.min_pcr > 0) { int tmpsum = iadev->sum_mcr+iadev->sum_cbr+vcc->qos.txtp.min_pcr; if (tmpsum > iadev->LineRate) return -EBUSY; srv_p.mcr = vcc->qos.txtp.min_pcr; iadev->sum_mcr += vcc->qos.txtp.min_pcr; } else srv_p.mcr = 0; if (vcc->qos.txtp.icr) srv_p.icr = vcc->qos.txtp.icr; if (vcc->qos.txtp.tbe) srv_p.tbe = vcc->qos.txtp.tbe; if (vcc->qos.txtp.frtt) srv_p.frtt = vcc->qos.txtp.frtt; if (vcc->qos.txtp.rif) srv_p.rif = vcc->qos.txtp.rif; if (vcc->qos.txtp.rdf) srv_p.rdf = vcc->qos.txtp.rdf; if (vcc->qos.txtp.nrm_pres) srv_p.nrm = vcc->qos.txtp.nrm; if (vcc->qos.txtp.trm_pres) srv_p.trm = vcc->qos.txtp.trm; if (vcc->qos.txtp.adtf_pres) srv_p.adtf = vcc->qos.txtp.adtf; if (vcc->qos.txtp.cdf_pres) srv_p.cdf = vcc->qos.txtp.cdf; if (srv_p.icr > srv_p.pcr) srv_p.icr = srv_p.pcr; IF_ABR(printk("ABR:vcc->qos.txtp.max_pcr = %d mcr = %d\n", srv_p.pcr, srv_p.mcr);) ia_open_abr_vc(iadev, &srv_p, vcc, 1); } else if (vcc->qos.txtp.traffic_class == ATM_CBR) { if (iadev->phy_type & FE_25MBIT_PHY) { printk("IA: CBR not support\n"); return -EINVAL; } if (vcc->qos.txtp.max_pcr > iadev->LineRate) { IF_CBR(printk("PCR is not available\n");) return -1; } vc->type = CBR; vc->status = CRC_APPEND; if ((ret = ia_cbr_setup (iadev, vcc)) < 0) { return ret; } } else printk("iadev: Non UBR, ABR and CBR traffic not supportedn"); iadev->testTable[vcc->vci]->vc_status |= VC_ACTIVE; IF_EVENT(printk("ia open_tx returning \n");) return 0; } static int tx_init(struct atm_dev *dev) { IADEV *iadev; struct tx_buf_desc *buf_desc_ptr; unsigned int tx_pkt_start; void *dle_addr; int i; u_short tcq_st_adr; u_short *tcq_start; u_short prq_st_adr; u_short *prq_start; struct main_vc *vc; struct ext_vc *evc; u_short tmp16; u32 vcsize_sel; iadev = INPH_IA_DEV(dev); spin_lock_init(&iadev->tx_lock); IF_INIT(printk("Tx MASK REG: 0x%0x\n", readw(iadev->seg_reg+SEG_MASK_REG));) /* Allocate 4k (boundary aligned) bytes */ dle_addr = pci_alloc_consistent(iadev->pci, DLE_TOTAL