tjh.dev / kernel
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kernel / drivers / net / arm / ether00.c
at v2.6.13-rc4 1017 lines 27 kB view raw
1/* 2 * drivers/net/ether00.c 3 * 4 * Copyright (C) 2001 Altera Corporation 5 * 6 * This program is free software; you can redistribute it and/or modify 7 * it under the terms of the GNU General Public License as published by 8 * the Free Software Foundation; either version 2 of the License, or 9 * (at your option) any later version. 10 * 11 * This program is distributed in the hope that it will be useful, 12 * but WITHOUT ANY WARRANTY; without even the implied warranty of 13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 14 * GNU General Public License for more details. 15 * 16 * You should have received a copy of the GNU General Public License 17 * along with this program; if not, write to the Free Software 18 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA 19 */ 20 21/* includes */ 22#include <linux/config.h> 23#include <linux/pci.h> 24#include <linux/sched.h> 25#include <linux/netdevice.h> 26#include <linux/skbuff.h> 27#include <linux/etherdevice.h> 28#include <linux/module.h> 29#include <linux/tqueue.h> 30#include <linux/mtd/mtd.h> 31#include <linux/pld/pld_hotswap.h> 32#include <asm/arch/excalibur.h> 33#include <asm/arch/hardware.h> 34#include <asm/irq.h> 35#include <asm/io.h> 36#include <asm/sizes.h> 37 38#include <asm/arch/ether00.h> 39#include <asm/arch/tdkphy.h> 40 41 42MODULE_AUTHOR("Clive Davies"); 43MODULE_DESCRIPTION("Altera Ether00 IP core driver"); 44MODULE_LICENSE("GPL"); 45 46#define PKT_BUF_SZ 1540 /* Size of each rx buffer */ 47#define ETH_NR 4 /* Number of MACs this driver supports */ 48 49#define DEBUG(x) 50 51#define __dma_va(x) (unsigned int)((unsigned int)priv->dma_data+(((unsigned int)(x))&(EXC_SPSRAM_BLOCK0_SIZE-1))) 52#define __dma_pa(x) (unsigned int)(EXC_SPSRAM_BLOCK0_BASE+(((unsigned int)(x))-(unsigned int)priv->dma_data)) 53 54#define ETHER00_BASE 0 55#define ETHER00_TYPE 56#define ETHER00_NAME "ether00" 57#define MAC_REG_SIZE 0x400 /* size of MAC register area */ 58 59 60 61/* typedefs */ 62 63/* The definition of the driver control structure */ 64 65#define RX_NUM_BUFF 10 66#define RX_NUM_FDESC 10 67#define TX_NUM_FDESC 10 68 69struct tx_fda_ent{ 70 FDA_DESC fd; 71 BUF_DESC bd; 72 BUF_DESC pad; 73}; 74struct rx_fda_ent{ 75 FDA_DESC fd; 76 BUF_DESC bd; 77 BUF_DESC pad; 78}; 79struct rx_blist_ent{ 80 FDA_DESC fd; 81 BUF_DESC bd; 82 BUF_DESC pad; 83}; 84struct net_priv 85{ 86 struct net_device_stats stats; 87 struct sk_buff* skb; 88 void* dma_data; 89 struct rx_blist_ent* rx_blist_vp; 90 struct rx_fda_ent* rx_fda_ptr; 91 struct tx_fda_ent* tx_fdalist_vp; 92 struct tq_struct tq_memupdate; 93 unsigned char memupdate_scheduled; 94 unsigned char rx_disabled; 95 unsigned char queue_stopped; 96 spinlock_t rx_lock; 97}; 98 99static const char vendor_id[2]={0x07,0xed}; 100 101#ifdef ETHER00_DEBUG 102 103/* Dump (most) registers for debugging puposes */ 104 105static void dump_regs(struct net_device *dev){ 106 struct net_priv* priv=dev->priv; 107 unsigned int* i; 108 109 printk("\n RX free descriptor area:\n"); 110 111 for(i=(unsigned int*)priv->rx_fda_ptr; 112 i<((unsigned int*)(priv->rx_fda_ptr+RX_NUM_FDESC));){ 113 printk("%#8x %#8x %#8x %#8x\n",*i,*(i+1),*(i+2),*(i+3)); 114 i+=4; 115 } 116 117 printk("\n RX buffer list:\n"); 118 119 for(i=(unsigned int*)priv->rx_blist_vp; 120 i<((unsigned int*)(priv->rx_blist_vp+RX_NUM_BUFF));){ 121 printk("%#8x %#8x %#8x %#8x\n",*i,*(i+1),*(i+2),*(i+3)); 122 i+=4; 123 } 124 125 printk("\n TX frame descriptor list:\n"); 126 127 for(i=(unsigned int*)priv->tx_fdalist_vp; 128 i<((unsigned int*)(priv->tx_fdalist_vp+TX_NUM_FDESC));){ 129 printk("%#8x %#8x %#8x %#8x\n",*i,*(i+1),*(i+2),*(i+3)); 130 i+=4; 131 } 132 133 printk("\ndma ctl=%#x\n",readw(ETHER_DMA_CTL(dev->base_addr))); 134 printk("txfrmptr=%#x\n",readw(ETHER_TXFRMPTR(dev->base_addr))); 135 printk("txthrsh=%#x\n",readw(ETHER_TXTHRSH(dev->base_addr))); 136 printk("txpollctr=%#x\n",readw(ETHER_TXPOLLCTR(dev->base_addr))); 137 printk("blfrmptr=%#x\n",readw(ETHER_BLFRMPTR(dev->base_addr))); 138 printk("rxfragsize=%#x\n",readw(ETHER_RXFRAGSIZE(dev->base_addr))); 139 printk("tx_int_en=%#x\n",readw(ETHER_INT_EN(dev->base_addr))); 140 printk("fda_bas=%#x\n",readw(ETHER_FDA_BAS(dev->base_addr))); 141 printk("fda_lim=%#x\n",readw(ETHER_FDA_LIM(dev->base_addr))); 142 printk("int_src=%#x\n",readw(ETHER_INT_SRC(dev->base_addr))); 143 printk("pausecnt=%#x\n",readw(ETHER_PAUSECNT(dev->base_addr))); 144 printk("rempaucnt=%#x\n",readw(ETHER_REMPAUCNT(dev->base_addr))); 145 printk("txconfrmstat=%#x\n",readw(ETHER_TXCONFRMSTAT(dev->base_addr))); 146 printk("mac_ctl=%#x\n",readw(ETHER_MAC_CTL(dev->base_addr))); 147 printk("arc_ctl=%#x\n",readw(ETHER_ARC_CTL(dev->base_addr))); 148 printk("tx_ctl=%#x\n",readw(ETHER_TX_CTL(dev->base_addr))); 149} 150#endif /* ETHER00_DEBUG */ 151 152 153static int ether00_write_phy(struct net_device *dev, short address, short value) 154{ 155 volatile int count = 1024; 156 writew(value,ETHER_MD_DATA(dev->base_addr)); 157 writew( ETHER_MD_CA_BUSY_MSK | 158 ETHER_MD_CA_WR_MSK | 159 (address & ETHER_MD_CA_ADDR_MSK), 160 ETHER_MD_CA(dev->base_addr)); 161 162 /* Wait for the command to complete */ 163 while((readw(ETHER_MD_CA(dev->base_addr)) & ETHER_MD_CA_BUSY_MSK)&&count){ 164 count--; 165 } 166 if (!count){ 167 printk("Write to phy failed, addr=%#x, data=%#x\n",address, value); 168 return -EIO; 169 } 170 return 0; 171} 172 173static int ether00_read_phy(struct net_device *dev, short address) 174{ 175 volatile int count = 1024; 176 writew( ETHER_MD_CA_BUSY_MSK | 177 (address & ETHER_MD_CA_ADDR_MSK), 178 ETHER_MD_CA(dev->base_addr)); 179 180 /* Wait for the command to complete */ 181 while((readw(ETHER_MD_CA(dev->base_addr)) & ETHER_MD_CA_BUSY_MSK)&&count){ 182 count--; 183 } 184 if (!count){ 185 printk(KERN_WARNING "Read from phy timed out\n"); 186 return -EIO; 187 } 188 return readw(ETHER_MD_DATA(dev->base_addr)); 189} 190 191static void ether00_phy_int(int irq_num, void* dev_id, struct pt_regs* regs) 192{ 193 struct net_device* dev=dev_id; 194 int irq_status; 195 196 irq_status=ether00_read_phy(dev, PHY_IRQ_CONTROL); 197 198 if(irq_status & PHY_IRQ_CONTROL_ANEG_COMP_INT_MSK){ 199 /* 200 * Autonegotiation complete on epxa10db. The mac doesn't 201 * twig if we're in full duplex so we need to check the 202 * phy status register and configure the mac accordingly 203 */ 204 if(ether00_read_phy(dev, PHY_STATUS)&(PHY_STATUS_10T_F_MSK|PHY_STATUS_100_X_F_MSK)){ 205 int tmp; 206 tmp=readl(ETHER_MAC_CTL(dev->base_addr)); 207 writel(tmp|ETHER_MAC_CTL_FULLDUP_MSK,ETHER_MAC_CTL(dev->base_addr)); 208 } 209 } 210 211 if(irq_status&PHY_IRQ_CONTROL_LS_CHG_INT_MSK){ 212 213 if(ether00_read_phy(dev, PHY_STATUS)& PHY_STATUS_LINK_MSK){ 214 /* Link is up */ 215 netif_carrier_on(dev); 216 //printk("Carrier on\n"); 217 }else{ 218 netif_carrier_off(dev); 219 //printk("Carrier off\n"); 220 221 } 222 } 223 224} 225 226static void setup_blist_entry(struct sk_buff* skb,struct rx_blist_ent* blist_ent_ptr){ 227 /* Make the buffer consistent with the cache as the mac is going to write 228 * directly into it*/ 229 blist_ent_ptr->fd.FDSystem=(unsigned int)skb; 230 blist_ent_ptr->bd.BuffData=(char*)__pa(skb->data); 231 consistent_sync(skb->data,PKT_BUF_SZ,PCI_DMA_FROMDEVICE); 232 /* align IP on 16 Byte (DMA_CTL set to skip 2 bytes) */ 233 skb_reserve(skb,2); 234 blist_ent_ptr->bd.BuffLength=PKT_BUF_SZ-2; 235 blist_ent_ptr->fd.FDLength=1; 236 blist_ent_ptr->fd.FDCtl=FDCTL_COWNSFD_MSK; 237 blist_ent_ptr->bd.BDCtl=BDCTL_COWNSBD_MSK; 238} 239 240 241static int ether00_mem_init(struct net_device* dev) 242{ 243 struct net_priv* priv=dev->priv; 244 struct tx_fda_ent *tx_fd_ptr,*tx_end_ptr; 245 struct rx_blist_ent* blist_ent_ptr; 246 int i; 247 248 /* 249 * Grab a block of on chip SRAM to contain the control stuctures for 250 * the ethernet MAC. This uncached becuase it needs to be accesses by both 251 * bus masters (cpu + mac). However, it shouldn't matter too much in terms 252 * of speed as its on chip memory 253 */ 254 priv->dma_data=ioremap_nocache(EXC_SPSRAM_BLOCK0_BASE,EXC_SPSRAM_BLOCK0_SIZE ); 255 if (!priv->dma_data) 256 return -ENOMEM; 257 258 priv->rx_fda_ptr=(struct rx_fda_ent*)priv->dma_data; 259 /* 260 * Now share it out amongst the Frame descriptors and the buffer list 261 */ 262 priv->rx_blist_vp=(struct rx_blist_ent*)((unsigned int)priv->dma_data+RX_NUM_FDESC*sizeof(struct rx_fda_ent)); 263 264 /* 265 *Initalise the FDA list 266 */ 267 /* set ownership to the controller */ 268 memset(priv->rx_fda_ptr,0x80,RX_NUM_FDESC*sizeof(struct rx_fda_ent)); 269 270 /* 271 *Initialise the buffer list 272 */ 273 blist_ent_ptr=priv->rx_blist_vp; 274 i=0; 275 while(blist_ent_ptr<(priv->rx_blist_vp+RX_NUM_BUFF)){ 276 struct sk_buff *skb; 277 blist_ent_ptr->fd.FDLength=1; 278 skb=dev_alloc_skb(PKT_BUF_SZ); 279 if(skb){ 280 setup_blist_entry(skb,blist_ent_ptr); 281 blist_ent_ptr->fd.FDNext=(FDA_DESC*)__dma_pa(blist_ent_ptr+1); 282 blist_ent_ptr->bd.BDStat=i++; 283 blist_ent_ptr++; 284 } 285 else 286 { 287 printk("Failed to initalise buffer list\n"); 288 } 289 290 } 291 blist_ent_ptr--; 292 blist_ent_ptr->fd.FDNext=(FDA_DESC*)__dma_pa(priv->rx_blist_vp); 293 294 priv->tx_fdalist_vp=(struct tx_fda_ent*)(priv->rx_blist_vp+RX_NUM_BUFF); 295 296 /* Initialise the buffers to be a circular list. The mac will then go poll 297 * the list until it finds a frame ready to transmit */ 298 tx_end_ptr=priv->tx_fdalist_vp+TX_NUM_FDESC; 299 for(tx_fd_ptr=priv->tx_fdalist_vp;tx_fd_ptr<tx_end_ptr;tx_fd_ptr++){ 300 tx_fd_ptr->fd.FDNext=(FDA_DESC*)__dma_pa((tx_fd_ptr+1)); 301 tx_fd_ptr->fd.FDCtl=1; 302 tx_fd_ptr->fd.FDStat=0; 303 tx_fd_ptr->fd.FDLength=1; 304 305 } 306 /* Change the last FDNext pointer to make a circular list */ 307 tx_fd_ptr--; 308 tx_fd_ptr->fd.FDNext=(FDA_DESC*)__dma_pa(priv->tx_fdalist_vp); 309 310 /* Point the device at the chain of Rx and Tx Buffers */ 311 writel((unsigned int)__dma_pa(priv->rx_fda_ptr),ETHER_FDA_BAS(dev->base_addr)); 312 writel((RX_NUM_FDESC-1)*sizeof(struct rx_fda_ent),ETHER_FDA_LIM(dev->base_addr)); 313 writel((unsigned int)__dma_pa(priv->rx_blist_vp),ETHER_BLFRMPTR(dev->base_addr)); 314 315 writel((unsigned int)__dma_pa(priv->tx_fdalist_vp),ETHER_TXFRMPTR(dev->base_addr)); 316 317 return 0; 318} 319 320 321void ether00_mem_update(void* dev_id) 322{ 323 struct net_device* dev=dev_id; 324 struct net_priv* priv=dev->priv; 325 struct sk_buff* skb; 326 struct tx_fda_ent *fda_ptr=priv->tx_fdalist_vp; 327 struct rx_blist_ent* blist_ent_ptr; 328 unsigned long flags; 329 330 priv->tq_memupdate.sync=0; 331 //priv->tq_memupdate.list= 332 priv->memupdate_scheduled=0; 333 334 /* Transmit interrupt */ 335 while(fda_ptr<(priv->tx_fdalist_vp+TX_NUM_FDESC)){ 336 if(!(FDCTL_COWNSFD_MSK&fda_ptr->fd.FDCtl) && (ETHER_TX_STAT_COMP_MSK&fda_ptr->fd.FDStat)){ 337 priv->stats.tx_packets++; 338 priv->stats.tx_bytes+=fda_ptr->bd.BuffLength; 339 skb=(struct sk_buff*)fda_ptr->fd.FDSystem; 340 //printk("%d:txcln:fda=%#x skb=%#x\n",jiffies,fda_ptr,skb); 341 dev_kfree_skb(skb); 342 fda_ptr->fd.FDSystem=0; 343 fda_ptr->fd.FDStat=0; 344 fda_ptr->fd.FDCtl=0; 345 } 346 fda_ptr++; 347 } 348 /* Fill in any missing buffers from the received queue */ 349 spin_lock_irqsave(&priv->rx_lock,flags); 350 blist_ent_ptr=priv->rx_blist_vp; 351 while(blist_ent_ptr<(priv->rx_blist_vp+RX_NUM_BUFF)){ 352 /* fd.FDSystem of 0 indicates we failed to allocate the buffer in the ISR */ 353 if(!blist_ent_ptr->fd.FDSystem){ 354 struct sk_buff *skb; 355 skb=dev_alloc_skb(PKT_BUF_SZ); 356 blist_ent_ptr->fd.FDSystem=(unsigned int)skb; 357 if(skb){ 358 setup_blist_entry(skb,blist_ent_ptr); 359 } 360 else 361 { 362 break; 363 } 364 } 365 blist_ent_ptr++; 366 } 367 spin_unlock_irqrestore(&priv->rx_lock,flags); 368 if(priv->queue_stopped){ 369 //printk("%d:cln:start q\n",jiffies); 370 netif_start_queue(dev); 371 } 372 if(priv->rx_disabled){ 373 //printk("%d:enable_irq\n",jiffies); 374 priv->rx_disabled=0; 375 writel(ETHER_RX_CTL_RXEN_MSK,ETHER_RX_CTL(dev->base_addr)); 376 377 } 378} 379 380 381static void ether00_int( int irq_num, void* dev_id, struct pt_regs* regs) 382{ 383 struct net_device* dev=dev_id; 384 struct net_priv* priv=dev->priv; 385 386 unsigned int interruptValue; 387 388 interruptValue=readl(ETHER_INT_SRC(dev->base_addr)); 389 390 //printk("INT_SRC=%x\n",interruptValue); 391 392 if(!(readl(ETHER_INT_SRC(dev->base_addr)) & ETHER_INT_SRC_IRQ_MSK)) 393 { 394 return; /* Interrupt wasn't caused by us!! */ 395 } 396 397 if(readl(ETHER_INT_SRC(dev->base_addr))& 398 (ETHER_INT_SRC_INTMACRX_MSK | 399 ETHER_INT_SRC_FDAEX_MSK | 400 ETHER_INT_SRC_BLEX_MSK)) { 401 struct rx_blist_ent* blist_ent_ptr; 402 struct rx_fda_ent* fda_ent_ptr; 403 struct sk_buff* skb; 404 405 fda_ent_ptr=priv->rx_fda_ptr; 406 spin_lock(&priv->rx_lock); 407 while(fda_ent_ptr<(priv->rx_fda_ptr+RX_NUM_FDESC)){ 408 int result; 409 410 if(!(fda_ent_ptr->fd.FDCtl&FDCTL_COWNSFD_MSK)) 411 { 412 /* This frame is ready for processing */ 413 /*find the corresponding buffer in the bufferlist */ 414 blist_ent_ptr=priv->rx_blist_vp+fda_ent_ptr->bd.BDStat; 415 skb=(struct sk_buff*)blist_ent_ptr->fd.FDSystem; 416 417 /* Pass this skb up the stack */ 418 skb->dev=dev; 419 skb_put(skb,fda_ent_ptr->fd.FDLength); 420 skb->protocol=eth_type_trans(skb,dev); 421 skb->ip_summed=CHECKSUM_UNNECESSARY; 422 result=netif_rx(skb); 423 /* Update statistics */ 424 priv->stats.rx_packets++; 425 priv->stats.rx_bytes+=fda_ent_ptr->fd.FDLength; 426 427 /* Free the FDA entry */ 428 fda_ent_ptr->bd.BDStat=0xff; 429 fda_ent_ptr->fd.FDCtl=FDCTL_COWNSFD_MSK; 430 431 /* Allocate a new skb and point the bd entry to it */ 432 blist_ent_ptr->fd.FDSystem=0; 433 skb=dev_alloc_skb(PKT_BUF_SZ); 434 //printk("allocskb=%#x\n",skb); 435 if(skb){ 436 setup_blist_entry(skb,blist_ent_ptr); 437 438 } 439 else if(!priv->memupdate_scheduled){ 440 int tmp; 441 /* There are no buffers at the moment, so schedule */ 442 /* the background task to sort this out */ 443 schedule_task(&priv->tq_memupdate); 444 priv->memupdate_scheduled=1; 445 printk(KERN_DEBUG "%s:No buffers",dev->name); 446 /* If this interrupt was due to a lack of buffers then 447 * we'd better stop the receiver too */ 448 if(interruptValue&ETHER_INT_SRC_BLEX_MSK){ 449 priv->rx_disabled=1; 450 tmp=readl(ETHER_INT_SRC(dev->base_addr)); 451 writel(tmp&~ETHER_RX_CTL_RXEN_MSK,ETHER_RX_CTL(dev->base_addr)); 452 printk(KERN_DEBUG "%s:Halting rx",dev->name); 453 } 454 455 } 456 457 } 458 fda_ent_ptr++; 459 } 460 spin_unlock(&priv->rx_lock); 461 462 /* Clear the interrupts */ 463 writel(ETHER_INT_SRC_INTMACRX_MSK | ETHER_INT_SRC_FDAEX_MSK 464 | ETHER_INT_SRC_BLEX_MSK,ETHER_INT_SRC(dev->base_addr)); 465 466 } 467 468 if(readl(ETHER_INT_SRC(dev->base_addr))&ETHER_INT_SRC_INTMACTX_MSK){ 469 470 if(!priv->memupdate_scheduled){ 471 schedule_task(&priv->tq_memupdate); 472 priv->memupdate_scheduled=1; 473 } 474 /* Clear the interrupt */ 475 writel(ETHER_INT_SRC_INTMACTX_MSK,ETHER_INT_SRC(dev->base_addr)); 476 } 477 478 if (readl(ETHER_INT_SRC(dev->base_addr)) & (ETHER_INT_SRC_SWINT_MSK| 479 ETHER_INT_SRC_INTEARNOT_MSK| 480 ETHER_INT_SRC_INTLINK_MSK| 481 ETHER_INT_SRC_INTEXBD_MSK| 482 ETHER_INT_SRC_INTTXCTLCMP_MSK)) 483 { 484 /* 485 * Not using any of these so they shouldn't happen 486 * 487 * In the cased of INTEXBD - if you allocate more 488 * than 28 decsriptors you may need to think about this 489 */ 490 printk("Not using this interrupt\n"); 491 } 492 493 if (readl(ETHER_INT_SRC(dev->base_addr)) & 494 (ETHER_INT_SRC_INTSBUS_MSK | 495 ETHER_INT_SRC_INTNRABT_MSK 496 |ETHER_INT_SRC_DMPARERR_MSK)) 497 { 498 /* 499 * Hardware errors, we can either ignore them and hope they go away 500 *or reset the device, I'll try the first for now to see if they happen 501 */ 502 printk("Hardware error\n"); 503 } 504} 505 506static void ether00_setup_ethernet_address(struct net_device* dev) 507{ 508 int tmp; 509 510 dev->addr_len=6; 511 writew(0,ETHER_ARC_ADR(dev->base_addr)); 512 writel((dev->dev_addr[0]<<24) | 513 (dev->dev_addr[1]<<16) | 514 (dev->dev_addr[2]<<8) | 515 dev->dev_addr[3], 516 ETHER_ARC_DATA(dev->base_addr)); 517 518 writew(4,ETHER_ARC_ADR(dev->base_addr)); 519 tmp=readl(ETHER_ARC_DATA(dev->base_addr)); 520 tmp&=0xffff; 521 tmp|=(dev->dev_addr[4]<<24) | (dev->dev_addr[5]<<16); 522 writel(tmp, ETHER_ARC_DATA(dev->base_addr)); 523 /* Enable this entry in the ARC */ 524 525 writel(1,ETHER_ARC_ENA(dev->base_addr)); 526 527 return; 528} 529 530 531static void ether00_reset(struct net_device *dev) 532{ 533 /* reset the controller */ 534 writew(ETHER_MAC_CTL_RESET_MSK,ETHER_MAC_CTL(dev->base_addr)); 535 536 /* 537 * Make sure we're not going to send anything 538 */ 539 540 writew(ETHER_TX_CTL_TXHALT_MSK,ETHER_TX_CTL(dev->base_addr)); 541 542 /* 543 * Make sure we're not going to receive anything 544 */ 545 writew(ETHER_RX_CTL_RXHALT_MSK,ETHER_RX_CTL(dev->base_addr)); 546 547 /* 548 * Disable Interrupts for now, and set the burst size to 8 bytes 549 */ 550 551 writel(ETHER_DMA_CTL_INTMASK_MSK | 552 ((8 << ETHER_DMA_CTL_DMBURST_OFST) & ETHER_DMA_CTL_DMBURST_MSK) 553 |(2<<ETHER_DMA_CTL_RXALIGN_OFST), 554 ETHER_DMA_CTL(dev->base_addr)); 555 556 557 /* 558 * Set TxThrsh - start transmitting a packet after 1514 559 * bytes or when a packet is complete, whichever comes first 560 */ 561 writew(1514,ETHER_TXTHRSH(dev->base_addr)); 562 563 /* 564 * Set TxPollCtr. Each cycle is 565 * 61.44 microseconds with a 33 MHz bus 566 */ 567 writew(1,ETHER_TXPOLLCTR(dev->base_addr)); 568 569 /* 570 * Set Rx_Ctl - Turn off reception and let RxData turn it 571 * on later 572 */ 573 writew(ETHER_RX_CTL_RXHALT_MSK,ETHER_RX_CTL(dev->base_addr)); 574 575} 576 577 578static void ether00_set_multicast(struct net_device* dev) 579{ 580 int count=dev->mc_count; 581 582 /* Set promiscuous mode if it's asked for. */ 583 584 if (dev->flags&IFF_PROMISC){ 585 586 writew( ETHER_ARC_CTL_COMPEN_MSK | 587 ETHER_ARC_CTL_BROADACC_MSK | 588 ETHER_ARC_CTL_GROUPACC_MSK | 589 ETHER_ARC_CTL_STATIONACC_MSK, 590 ETHER_ARC_CTL(dev->base_addr)); 591 return; 592 } 593 594 /* 595 * Get all multicast packets if required, or if there are too 596 * many addresses to fit in hardware 597 */ 598 if (dev->flags & IFF_ALLMULTI){ 599 writew( ETHER_ARC_CTL_COMPEN_MSK | 600 ETHER_ARC_CTL_GROUPACC_MSK | 601 ETHER_ARC_CTL_BROADACC_MSK, 602 ETHER_ARC_CTL(dev->base_addr)); 603 return; 604 } 605 if (dev->mc_count > (ETHER_ARC_SIZE - 1)){ 606 607 printk(KERN_WARNING "Too many multicast addresses for hardware to filter - receiving all multicast packets\n"); 608 writew( ETHER_ARC_CTL_COMPEN_MSK | 609 ETHER_ARC_CTL_GROUPACC_MSK | 610 ETHER_ARC_CTL_BROADACC_MSK, 611 ETHER_ARC_CTL(dev->base_addr)); 612 return; 613 } 614 615 if(dev->mc_count){ 616 struct dev_mc_list *mc_list_ent=dev->mc_list; 617 unsigned int temp,i; 618 DEBUG(printk("mc_count=%d mc_list=%#x\n",dev-> mc_count, dev->mc_list)); 619 DEBUG(printk("mc addr=%02#x%02x%02x%02x%02x%02x\n", 620 mc_list_ent->dmi_addr[5], 621 mc_list_ent->dmi_addr[4], 622 mc_list_ent->dmi_addr[3], 623 mc_list_ent->dmi_addr[2], 624 mc_list_ent->dmi_addr[1], 625 mc_list_ent->dmi_addr[0]);) 626 627 /* 628 * The first 6 bytes are the MAC address, so 629 * don't change them! 630 */ 631 writew(4,ETHER_ARC_ADR(dev->base_addr)); 632 temp=readl(ETHER_ARC_DATA(dev->base_addr)); 633 temp&=0xffff0000; 634 635 /* Disable the current multicast stuff */ 636 writel(1,ETHER_ARC_ENA(dev->base_addr)); 637 638 for(;;){ 639 temp|=mc_list_ent->dmi_addr[1] | 640 mc_list_ent->dmi_addr[0]<<8; 641 writel(temp,ETHER_ARC_DATA(dev->base_addr)); 642 643 i=readl(ETHER_ARC_ADR(dev->base_addr)); 644 writew(i+4,ETHER_ARC_ADR(dev->base_addr)); 645 646 temp=mc_list_ent->dmi_addr[5]| 647 mc_list_ent->dmi_addr[4]<<8 | 648 mc_list_ent->dmi_addr[3]<<16 | 649 mc_list_ent->dmi_addr[2]<<24; 650 writel(temp,ETHER_ARC_DATA(dev->base_addr)); 651 652 count--; 653 if(!mc_list_ent->next || !count){ 654 break; 655 } 656 DEBUG(printk("mc_list_next=%#x\n",mc_list_ent->next);) 657 mc_list_ent=mc_list_ent->next; 658 659 660 i=readl(ETHER_ARC_ADR(dev->base_addr)); 661 writel(i+4,ETHER_ARC_ADR(dev->base_addr)); 662 663 temp=mc_list_ent->dmi_addr[3]| 664 mc_list_ent->dmi_addr[2]<<8 | 665 mc_list_ent->dmi_addr[1]<<16 | 666 mc_list_ent->dmi_addr[0]<<24; 667 writel(temp,ETHER_ARC_DATA(dev->base_addr)); 668 669 i=readl(ETHER_ARC_ADR(dev->base_addr)); 670 writel(i+4,ETHER_ARC_ADR(dev->base_addr)); 671 672 temp=mc_list_ent->dmi_addr[4]<<16 | 673 mc_list_ent->dmi_addr[5]<<24; 674 675 writel(temp,ETHER_ARC_DATA(dev->base_addr)); 676 677 count--; 678 if(!mc_list_ent->next || !count){ 679 break; 680 } 681 mc_list_ent=mc_list_ent->next; 682 } 683 684 685 if(count) 686 printk(KERN_WARNING "Multicast list size error\n"); 687 688 689 writew( ETHER_ARC_CTL_BROADACC_MSK| 690 ETHER_ARC_CTL_COMPEN_MSK, 691 ETHER_ARC_CTL(dev->base_addr)); 692 693 } 694 695 /* enable the active ARC enties */ 696 writew((1<<(count+2))-1,ETHER_ARC_ENA(dev->base_addr)); 697} 698 699 700static int ether00_open(struct net_device* dev) 701{ 702 int result,tmp; 703 struct net_priv* priv; 704 705 if (!is_valid_ether_addr(dev->dev_addr)) 706 return -EINVAL; 707 708 /* Install interrupt handlers */ 709 result=request_irq(dev->irq,ether00_int,0,"ether00",dev); 710 if(result) 711 goto open_err1; 712 713 result=request_irq(2,ether00_phy_int,0,"ether00_phy",dev); 714 if(result) 715 goto open_err2; 716 717 ether00_reset(dev); 718 result=ether00_mem_init(dev); 719 if(result) 720 goto open_err3; 721 722 723 ether00_setup_ethernet_address(dev); 724 725 ether00_set_multicast(dev); 726 727 result=ether00_write_phy(dev,PHY_CONTROL, PHY_CONTROL_ANEGEN_MSK | PHY_CONTROL_RANEG_MSK); 728 if(result) 729 goto open_err4; 730 result=ether00_write_phy(dev,PHY_IRQ_CONTROL, PHY_IRQ_CONTROL_LS_CHG_IE_MSK | 731 PHY_IRQ_CONTROL_ANEG_COMP_IE_MSK); 732 if(result) 733 goto open_err4; 734 735 /* Start the device enable interrupts */ 736 writew(ETHER_RX_CTL_RXEN_MSK 737// | ETHER_RX_CTL_STRIPCRC_MSK 738 | ETHER_RX_CTL_ENGOOD_MSK 739 | ETHER_RX_CTL_ENRXPAR_MSK| ETHER_RX_CTL_ENLONGERR_MSK 740 | ETHER_RX_CTL_ENOVER_MSK| ETHER_RX_CTL_ENCRCERR_MSK, 741 ETHER_RX_CTL(dev->base_addr)); 742 743 writew(ETHER_TX_CTL_TXEN_MSK| 744 ETHER_TX_CTL_ENEXDEFER_MSK| 745 ETHER_TX_CTL_ENLCARR_MSK| 746 ETHER_TX_CTL_ENEXCOLL_MSK| 747 ETHER_TX_CTL_ENLATECOLL_MSK| 748 ETHER_TX_CTL_ENTXPAR_MSK| 749 ETHER_TX_CTL_ENCOMP_MSK, 750 ETHER_TX_CTL(dev->base_addr)); 751 752 tmp=readl(ETHER_DMA_CTL(dev->base_addr)); 753 writel(tmp&~ETHER_DMA_CTL_INTMASK_MSK,ETHER_DMA_CTL(dev->base_addr)); 754 755 return 0; 756 757 open_err4: 758 ether00_reset(dev); 759 open_err3: 760 free_irq(2,dev); 761 open_err2: 762 free_irq(dev->irq,dev); 763 open_err1: 764 return result; 765 766} 767 768 769static int ether00_tx(struct sk_buff* skb, struct net_device* dev) 770{ 771 struct net_priv *priv=dev->priv; 772 struct tx_fda_ent *fda_ptr; 773 int i; 774 775 776 /* 777 * Find an empty slot in which to stick the frame 778 */ 779 fda_ptr=(struct tx_fda_ent*)__dma_va(readl(ETHER_TXFRMPTR(dev->base_addr))); 780 i=0; 781 while(i<TX_NUM_FDESC){ 782 if (fda_ptr->fd.FDStat||(fda_ptr->fd.FDCtl & FDCTL_COWNSFD_MSK)){ 783 fda_ptr =(struct tx_fda_ent*) __dma_va((struct tx_fda_ent*)fda_ptr->fd.FDNext); 784 } 785 else { 786 break; 787 } 788 i++; 789 } 790 791 /* Write the skb data from the cache*/ 792 consistent_sync(skb->data,skb->len,PCI_DMA_TODEVICE); 793 fda_ptr->bd.BuffData=(char*)__pa(skb->data); 794 fda_ptr->bd.BuffLength=(unsigned short)skb->len; 795 /* Save the pointer to the skb for freeing later */ 796 fda_ptr->fd.FDSystem=(unsigned int)skb; 797 fda_ptr->fd.FDStat=0; 798 /* Pass ownership of the buffers to the controller */ 799 fda_ptr->fd.FDCtl=1; 800 fda_ptr->fd.FDCtl|=FDCTL_COWNSFD_MSK; 801 802 /* If the next buffer in the list is full, stop the queue */ 803 fda_ptr=(struct tx_fda_ent*)__dma_va(fda_ptr->fd.FDNext); 804 if ((fda_ptr->fd.FDStat)||(fda_ptr->fd.FDCtl & FDCTL_COWNSFD_MSK)){ 805 netif_stop_queue(dev); 806 priv->queue_stopped=1; 807 } 808 809 return 0; 810} 811 812static struct net_device_stats *ether00_stats(struct net_device* dev) 813{ 814 struct net_priv *priv=dev->priv; 815 return &priv->stats; 816} 817 818 819static int ether00_stop(struct net_device* dev) 820{ 821 struct net_priv *priv=dev->priv; 822 int tmp; 823 824 /* Stop/disable the device. */ 825 tmp=readw(ETHER_RX_CTL(dev->base_addr)); 826 tmp&=~(ETHER_RX_CTL_RXEN_MSK | ETHER_RX_CTL_ENGOOD_MSK); 827 tmp|=ETHER_RX_CTL_RXHALT_MSK; 828 writew(tmp,ETHER_RX_CTL(dev->base_addr)); 829 830 tmp=readl(ETHER_TX_CTL(dev->base_addr)); 831 tmp&=~ETHER_TX_CTL_TXEN_MSK; 832 tmp|=ETHER_TX_CTL_TXHALT_MSK; 833 writel(tmp,ETHER_TX_CTL(dev->base_addr)); 834 835 /* Free up system resources */ 836 free_irq(dev->irq,dev); 837 free_irq(2,dev); 838 iounmap(priv->dma_data); 839 840 return 0; 841} 842 843 844static void ether00_get_ethernet_address(struct net_device* dev) 845{ 846 struct mtd_info *mymtd=NULL; 847 int i; 848 size_t retlen; 849 850 /* 851 * For the Epxa10 dev board (camelot), the ethernet MAC 852 * address is of the form 00:aa:aa:00:xx:xx where 853 * 00:aa:aa is the Altera vendor ID and xx:xx is the 854 * last 2 bytes of the board serial number, as programmed 855 * into the OTP area of the flash device on EBI1. If this 856 * isn't an expa10 dev board, or there's no mtd support to 857 * read the serial number from flash then we'll force the 858 * use to set their own mac address using ifconfig. 859 */ 860 861#ifdef CONFIG_ARCH_CAMELOT 862#ifdef CONFIG_MTD 863 /* get the mtd_info structure for the first mtd device*/ 864 for(i=0;i<MAX_MTD_DEVICES;i++){ 865 mymtd=get_mtd_device(NULL,i); 866 if(!mymtd||!strcmp(mymtd->name,"EPXA10DB flash")) 867 break; 868 } 869 870 if(!mymtd || !mymtd->read_user_prot_reg){ 871 printk(KERN_WARNING "%s: Failed to read MAC address from flash\n",dev->name); 872 }else{ 873 mymtd->read_user_prot_reg(mymtd,2,1,&retlen,&dev->dev_addr[5]); 874 mymtd->read_user_prot_reg(mymtd,3,1,&retlen,&dev->dev_addr[4]); 875 dev->dev_addr[3]=0; 876 dev->dev_addr[2]=vendor_id[1]; 877 dev->dev_addr[1]=vendor_id[0]; 878 dev->dev_addr[0]=0; 879 } 880#else 881 printk(KERN_WARNING "%s: MTD support required to read MAC address from EPXA10 dev board\n", dev->name); 882#endif 883#endif 884 885 if (!is_valid_ether_addr(dev->dev_addr)) 886 printk("%s: Invalid ethernet MAC address. Please set using " 887 "ifconfig\n", dev->name); 888 889} 890 891/* 892 * Keep a mapping of dev_info addresses -> port lines to use when 893 * removing ports dev==NULL indicates unused entry 894 */ 895 896 897static struct net_device* dev_list[ETH_NR]; 898 899static int ether00_add_device(struct pldhs_dev_info* dev_info,void* dev_ps_data) 900{ 901 struct net_device *dev; 902 struct net_priv *priv; 903 void *map_addr; 904 int result; 905 int i; 906 907 i=0; 908 while(dev_list[i] && i < ETH_NR) 909 i++; 910 911 if(i==ETH_NR){ 912 printk(KERN_WARNING "ether00: Maximum number of ports reached\n"); 913 return 0; 914 } 915 916 917 if (!request_mem_region(dev_info->base_addr, MAC_REG_SIZE, "ether00")) 918 return -EBUSY; 919 920 dev = alloc_etherdev(sizeof(struct net_priv)); 921 if(!dev) { 922 result = -ENOMEM; 923 goto out_release; 924 } 925 priv = dev->priv; 926 927 priv->tq_memupdate.routine=ether00_mem_update; 928 priv->tq_memupdate.data=(void*) dev; 929 930 spin_lock_init(&priv->rx_lock); 931 932 map_addr=ioremap_nocache(dev_info->base_addr,SZ_4K); 933 if(!map_addr){ 934 result = -ENOMEM; 935 out_kfree; 936 } 937 938 dev->open=ether00_open; 939 dev->stop=ether00_stop; 940 dev->set_multicast_list=ether00_set_multicast; 941 dev->hard_start_xmit=ether00_tx; 942 dev->get_stats=ether00_stats; 943 944 ether00_get_ethernet_address(dev); 945 946 SET_MODULE_OWNER(dev); 947 948 dev->base_addr=(unsigned int)map_addr; 949 dev->irq=dev_info->irq; 950 dev->features=NETIF_F_DYNALLOC | NETIF_F_HW_CSUM; 951 952 result=register_netdev(dev); 953 if(result){ 954 printk("Ether00: Error %i registering driver\n",result); 955 goto out_unmap; 956 } 957 printk("registered ether00 device at %#x\n",dev_info->base_addr); 958 959 dev_list[i]=dev; 960 961 return result; 962 963 out_unmap: 964 iounmap(map_addr); 965 out_kfree: 966 free_netdev(dev); 967 out_release: 968 release_mem_region(dev_info->base_addr, MAC_REG_SIZE); 969 return result; 970} 971 972 973static int ether00_remove_devices(void) 974{ 975 int i; 976 977 for(i=0;i<ETH_NR;i++){ 978 if(dev_list[i]){ 979 netif_device_detach(dev_list[i]); 980 unregister_netdev(dev_list[i]); 981 iounmap((void*)dev_list[i]->base_addr); 982 release_mem_region(dev_list[i]->base_addr, MAC_REG_SIZE); 983 free_netdev(dev_list[i]); 984 dev_list[i]=0; 985 } 986 } 987 return 0; 988} 989 990static struct pld_hotswap_ops ether00_pldhs_ops={ 991 .name = ETHER00_NAME, 992 .add_device = ether00_add_device, 993 .remove_devices = ether00_remove_devices, 994}; 995 996 997static void __exit ether00_cleanup_module(void) 998{ 999 int result; 1000 result=ether00_remove_devices(); 1001 if(result) 1002 printk(KERN_WARNING "ether00: failed to remove all devices\n"); 1003 1004 pldhs_unregister_driver(ETHER00_NAME); 1005} 1006module_exit(ether00_cleanup_module); 1007 1008 1009static int __init ether00_mod_init(void) 1010{ 1011 printk("mod init\n"); 1012 return pldhs_register_driver(&ether00_pldhs_ops); 1013 1014} 1015 1016module_init(ether00_mod_init); 1017