1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 22 /* 23 * Copyright 2005 Sun Microsystems, Inc. All rights reserved. 24 * Use is subject to license terms. 25 */ 26 27 /* 28 * This file is part of the Chelsio T1 Ethernet driver. 29 * 30 * Copyright (C) 2003-2005 Chelsio Communications. All rights reserved. 31 */ 32 33 /* 34 * Solaris Multithreaded STREAMS Chelsio PCI Ethernet Driver. 35 * Interface code 36 */ 37 38 #include <sys/types.h> 39 #include <sys/systm.h> 40 #include <sys/cmn_err.h> 41 #include <sys/ddi.h> 42 #include <sys/sunddi.h> 43 #include <sys/byteorder.h> 44 #include <sys/atomic.h> 45 #include <sys/ethernet.h> 46 #if PE_PROFILING_ENABLED 47 #include <sys/time.h> 48 #endif 49 #include <sys/gld.h> 50 #include "ostypes.h" 51 #include "common.h" 52 #include "oschtoe.h" 53 #ifdef CONFIG_CHELSIO_T1_1G 54 #include "fpga_defs.h" 55 #endif 56 #include "regs.h" 57 #ifdef CONFIG_CHELSIO_T1_OFFLOAD 58 #include "mc3.h" 59 #include "mc4.h" 60 #endif 61 #include "sge.h" 62 #include "tp.h" 63 #ifdef CONFIG_CHELSIO_T1_OFFLOAD 64 #include "ulp.h" 65 #endif 66 #include "espi.h" 67 #include "elmer0.h" 68 #include "gmac.h" 69 #include "cphy.h" 70 #include "suni1x10gexp_regs.h" 71 #include "ch.h" 72 73 #define MLEN(mp) ((mp)->b_wptr - (mp)->b_rptr) 74 75 extern uint32_t buffers_in_use[]; 76 extern kmutex_t in_use_l; 77 extern uint32_t in_use_index; 78 79 static void link_start(ch_t *sa, struct pe_port_t *pp); 80 static ch_esb_t *ch_alloc_small_esbbuf(ch_t *sa, uint32_t i); 81 static ch_esb_t *ch_alloc_big_esbbuf(ch_t *sa, uint32_t i); 82 void ch_big_rbuf_recycle(ch_esb_t *rbp); 83 void ch_small_rbuf_recycle(ch_esb_t *rbp); 84 static const struct board_info *pe_sa_init(ch_t *sa); 85 static int ch_set_config_data(ch_t *chp); 86 void pe_rbuf_pool_free(ch_t *chp); 87 static void pe_free_driver_resources(ch_t *sa); 88 static void update_mtu_tab(ch_t *adapter); 89 static int pe_change_mtu(ch_t *chp); 90 91 /* 92 * CPL5 Defines (from netinet/cpl5_commands.h) 93 */ 94 #define FLITSTOBYTES 8 95 96 #define CPL_FORMAT_0_SIZE 8 97 #define CPL_FORMAT_1_SIZE 16 98 #define CPL_FORMAT_2_SIZE 24 99 #define CPL_FORMAT_3_SIZE 32 100 #define CPL_FORMAT_4_SIZE 40 101 #define CPL_FORMAT_5_SIZE 48 102 103 #define TID_MASK 0xffffff 104 105 #define PE_LINK_SPEED_AUTONEG 5 106 107 static int pe_small_rbuf_pool_init(ch_t *sa); 108 static int pe_big_rbuf_pool_init(ch_t *sa); 109 static int pe_make_fake_arp(ch_t *chp, unsigned char *arpp); 110 static uint32_t pe_get_ip(unsigned char *arpp); 111 112 /* 113 * May be set in /etc/system to 0 to use default latency timer for 10G. 114 * See PCI register 0xc definition. 115 */ 116 int enable_latency_timer = 1; 117 118 /* 119 * May be set in /etc/system to 0 to disable hardware checksum for 120 * TCP and UDP. 121 */ 122 int enable_checksum_offload = 1; 123 124 /* 125 * Multiplier for freelist pool. 126 */ 127 int fl_sz_multiplier = 6; 128 129 uint_t 130 pe_intr(ch_t *sa) 131 { 132 mutex_enter(&sa->ch_intr); 133 134 if (sge_data_in(sa->sge)) { 135 sa->isr_intr++; 136 mutex_exit(&sa->ch_intr); 137 return (DDI_INTR_CLAIMED); 138 } 139 140 mutex_exit(&sa->ch_intr); 141 142 return (DDI_INTR_UNCLAIMED); 143 } 144 145 /* 146 * Each setup struct will call this function to 147 * initialize. 148 */ 149 void 150 pe_init(void* xsa) 151 { 152 ch_t *sa = NULL; 153 int i = 0; 154 155 sa = (ch_t *)xsa; 156 157 /* 158 * Need to count the number of times this routine is called 159 * because we only want the resources to be allocated once. 160 * The 7500 has four ports and so this routine can be called 161 * once for each port. 162 */ 163 if (sa->init_counter == 0) { 164 for_each_port(sa, i) { 165 166 /* 167 * We only want to initialize the line if it is down. 168 */ 169 if (sa->port[i].line_up == 0) { 170 link_start(sa, &sa->port[i]); 171 sa->port[i].line_up = 1; 172 } 173 } 174 175 (void) t1_init_hw_modules(sa); 176 177 /* 178 * Enable/Disable checksum offloading. 179 */ 180 if (sa->ch_config.cksum_enabled) { 181 if (sa->config_data.offload_ip_cksum) { 182 /* Notify that HW will do the checksum. */ 183 t1_tp_set_ip_checksum_offload(sa->tp, 1); 184 } 185 186 if (sa->config_data.offload_tcp_cksum) { 187 /* Notify that HW will do the checksum. */ 188 t1_tp_set_tcp_checksum_offload(sa->tp, 1); 189 } 190 191 if (sa->config_data.offload_udp_cksum) { 192 /* Notify that HW will do the checksum. */ 193 t1_tp_set_udp_checksum_offload(sa->tp, 1); 194 } 195 } 196 197 sa->ch_flags |= PEINITDONE; 198 199 sa->init_counter++; 200 } 201 202 /* 203 * Enable interrupts after starting the SGE so 204 * that the SGE is ready to handle interrupts. 205 */ 206 (void) sge_start(sa->sge); 207 t1_interrupts_enable(sa); 208 209 /* 210 * set mtu (either 1500 or bigger) 211 */ 212 (void) pe_change_mtu(sa); 213 #ifdef HOST_PAUSE 214 /* 215 * get the configured value of the MAC. 216 */ 217 (void) t1_tpi_read(sa, SUNI1x10GEXP_REG_TXXG_CONFIG_1 << 2, 218 &sa->txxg_cfg1); 219 #endif 220 } 221 222 /* ARGSUSED */ 223 static void 224 link_start(ch_t *sa, struct pe_port_t *p) 225 { 226 struct cmac *mac = p->mac; 227 228 mac->ops->reset(mac); 229 if (mac->ops->macaddress_set) 230 mac->ops->macaddress_set(mac, p->enaddr); 231 (void) t1_link_start(p->phy, mac, &p->link_config); 232 mac->ops->enable(mac, MAC_DIRECTION_RX | MAC_DIRECTION_TX); 233 } 234 235 /* 236 * turn off interrupts... 237 */ 238 void 239 pe_stop(ch_t *sa) 240 { 241 t1_interrupts_disable(sa); 242 (void) sge_stop(sa->sge); 243 244 /* 245 * we can still be running an interrupt thread in sge_data_in(). 246 * If we are, we'll block on the ch_intr lock 247 */ 248 mutex_enter(&sa->ch_intr); 249 mutex_exit(&sa->ch_intr); 250 } 251 252 /* 253 * output mblk to SGE level and out to the wire. 254 */ 255 256 int 257 pe_start(ch_t *sa, mblk_t *mp, uint32_t flg) 258 { 259 mblk_t *m0 = mp; 260 cmdQ_ce_t cm[16]; 261 cmdQ_ce_t *cmp; 262 cmdQ_ce_t *hmp = &cm[0]; /* head of cm table (may be kmem_alloed) */ 263 int cm_flg = 0; /* flag (1 - if kmem-alloced) */ 264 int nseg = 0; /* number cmdQ_ce entries created */ 265 int mseg = 16; /* maximum entries in hmp arrary */ 266 int freeme = 0; /* we have an mblk to free in case of error */ 267 uint32_t ch_bind_dma_handle(ch_t *, int, caddr_t, cmdQ_ce_t *, 268 uint32_t); 269 #if defined(__sparc) 270 uint32_t ch_bind_dvma_handle(ch_t *, int, caddr_t, cmdQ_ce_t *, 271 uint32_t); 272 #endif 273 int rv; /* return value on error */ 274 275 #ifdef CONFIG_CHELSIO_T1_OFFLOAD 276 if (flg & CH_OFFLOAD) { 277 hmp->ce_pa = ((tbuf_t *)mp)->tb_pa; 278 hmp->ce_dh = NULL; 279 hmp->ce_flg = DH_TOE; 280 hmp->ce_len = ((tbuf_t *)mp)->tb_len; 281 hmp->ce_mp = mp; 282 283 /* make sure data is flushed to physical memory */ 284 (void) ddi_dma_sync((ddi_dma_handle_t)((tbuf_t *)mp)->tb_dh, 285 (off_t)0, hmp->ce_len, DDI_DMA_SYNC_FORDEV); 286 287 if (sge_data_out(sa->sge, 0, mp, hmp, 1, flg) == 0) { 288 return (0); 289 } 290 291 /* 292 * set a flag so we'll restart upper layer when 293 * resources become available. 294 */ 295 sa->ch_blked = 1; 296 return (1); 297 } 298 #endif /* CONFIG_CHELSIO_T1_OFFLOAD */ 299 300 /* writes from toe will always have CPL header in place */ 301 if (flg & CH_NO_CPL) { 302 struct cpl_tx_pkt *cpl; 303 304 /* PR2928 & PR3309 */ 305 if (sa->ch_ip == 0) { 306 ushort_t ethertype = ntohs(*(short *)&mp->b_rptr[12]); 307 if (ethertype == ETHERTYPE_ARP) { 308 if (is_T2(sa)) { 309 /* 310 * We assume here that the arp will be 311 * contained in one mblk. 312 */ 313 if (pe_make_fake_arp(sa, mp->b_rptr)) { 314 freemsg(mp); 315 sa->oerr++; 316 return (0); 317 } 318 } else { 319 sa->ch_ip = pe_get_ip(mp->b_rptr); 320 } 321 } 322 } 323 324 /* 325 * if space in front of packet big enough for CPL 326 * header, then use it. We'll allocate an mblk 327 * otherwise. 328 */ 329 if ((mp->b_rptr - mp->b_datap->db_base) >= SZ_CPL_TX_PKT) { 330 331 mp->b_rptr -= SZ_CPL_TX_PKT; 332 333 } else { 334 335 #ifdef SUN_KSTATS 336 sa->sge->intr_cnt.tx_need_cpl_space++; 337 #endif 338 m0 = allocb(SZ_CPL_TX_PKT, BPRI_HI); 339 if (m0 == NULL) { 340 freemsg(mp); 341 sa->oerr++; 342 return (0); 343 } 344 345 m0->b_wptr = m0->b_rptr + SZ_CPL_TX_PKT; 346 m0->b_cont = mp; 347 freeme = 1; 348 349 mp = m0; 350 } 351 352 /* fill in cpl header */ 353 cpl = (struct cpl_tx_pkt *)mp->b_rptr; 354 cpl->opcode = CPL_TX_PKT; 355 cpl->iff = 0; /* XXX port 0 needs fixing with NEMO */ 356 cpl->ip_csum_dis = 1; /* no IP header cksum */ 357 cpl->l4_csum_dis = 358 flg & CH_NO_HWCKSUM; /* CH_NO_HWCKSUM == 1 */ 359 cpl->vlan_valid = 0; /* no vlan */ 360 } 361 362 if (m0->b_cont) { 363 364 #ifdef SUN_KSTATS 365 sa->sge->intr_cnt.tx_multi_mblks++; 366 #endif 367 368 while (mp) { 369 int lseg; /* added by ch_bind_dma_handle() */ 370 int len; 371 372 len = MLEN(mp); 373 /* skip mlks with no data */ 374 if (len == 0) { 375 mp = mp->b_cont; 376 continue; 377 } 378 379 /* 380 * if we've run out of space on stack, then we 381 * allocate a temporary buffer to hold the 382 * information. This will kill the the performance, 383 * but since it shouldn't really occur, we can live 384 * with it. Since jumbo frames may map multiple 385 * descriptors, we reallocate the hmp[] array before 386 * we reach the end. 387 */ 388 if (nseg >= (mseg-4)) { 389 cmdQ_ce_t *buf; 390 int j; 391 392 buf = kmem_alloc(sizeof (cmdQ_ce_t) * 2 * mseg, 393 KM_SLEEP); 394 395 for (j = 0; j < nseg; j++) 396 buf[j] = hmp[j]; 397 398 if (cm_flg) { 399 kmem_free(hmp, 400 mseg * sizeof (cmdQ_ce_t)); 401 } else 402 cm_flg = 1; 403 404 hmp = buf; 405 mseg = 2*mseg; 406 407 /* 408 * We've used up ch table on stack 409 */ 410 } 411 412 #if defined(__sparc) 413 if (sa->ch_config.enable_dvma) { 414 lseg = ch_bind_dvma_handle(sa, len, 415 (void *)mp->b_rptr, 416 &hmp[nseg], mseg - nseg); 417 if (lseg == NULL) { 418 sa->sge->intr_cnt.tx_no_dvma1++; 419 if ((lseg = ch_bind_dma_handle(sa, len, 420 (void *)mp->b_rptr, 421 &hmp[nseg], 422 mseg - nseg)) == NULL) { 423 sa->sge->intr_cnt.tx_no_dma1++; 424 425 /* 426 * ran out of space. Gonna bale 427 */ 428 rv = 0; 429 430 /* 431 * we may have processed 432 * previous mblks and have 433 * descriptors. If so, we need 434 * to free the meta struct 435 * entries before freeing 436 * the mblk. 437 */ 438 if (nseg) 439 goto error; 440 goto error1; 441 } 442 } 443 } else { 444 lseg = ch_bind_dma_handle(sa, len, 445 (void *)mp->b_rptr, &hmp[nseg], 446 mseg - nseg); 447 if (lseg == NULL) { 448 sa->sge->intr_cnt.tx_no_dma1++; 449 450 /* 451 * ran out of space. Gona bale 452 */ 453 rv = 0; 454 455 /* 456 * we may have processed previous 457 * mblks and have descriptors. If so, 458 * we need to free the meta struct 459 * entries before freeing the mblk. 460 */ 461 if (nseg) 462 goto error; 463 goto error1; 464 } 465 } 466 #else /* defined(__sparc) */ 467 lseg = ch_bind_dma_handle(sa, len, 468 (void *)mp->b_rptr, &hmp[nseg], 469 mseg - nseg); 470 if (lseg == 0) { 471 sa->sge->intr_cnt.tx_no_dma1++; 472 473 /* 474 * ran out of space. Gona bale 475 */ 476 rv = 0; 477 478 /* 479 * we may have processed previous mblks and 480 * have descriptors. If so, we need to free 481 * the meta struct entries before freeing 482 * the mblk. 483 */ 484 if (nseg) 485 goto error; 486 goto error1; 487 } 488 #endif /* defined(__sparc) */ 489 nseg += lseg; 490 mp = mp->b_cont; 491 } 492 493 /* 494 * SHOULD NEVER OCCUR, BUT... 495 * no data if nseg 0 or 496 * nseg 1 and a CPL mblk (CPL mblk only with offload mode) 497 * and no data 498 */ 499 if ((nseg == 0) || (freeme && (nseg == 1))) { 500 rv = 0; 501 goto error1; 502 } 503 504 } else { 505 int len; 506 507 /* we assume that we always have data with one packet */ 508 len = MLEN(mp); 509 510 #if defined(__sparc) 511 if (sa->ch_config.enable_dvma) { 512 nseg = ch_bind_dvma_handle(sa, len, 513 (void *)mp->b_rptr, 514 &hmp[0], 16); 515 if (nseg == NULL) { 516 sa->sge->intr_cnt.tx_no_dvma2++; 517 nseg = ch_bind_dma_handle(sa, len, 518 (void *)mp->b_rptr, 519 &hmp[0], 16); 520 if (nseg == NULL) { 521 sa->sge->intr_cnt.tx_no_dma2++; 522 523 /* 524 * ran out of space. Gona bale 525 */ 526 rv = 0; 527 goto error1; 528 } 529 } 530 } else { 531 nseg = ch_bind_dma_handle(sa, len, 532 (void *)mp->b_rptr, &hmp[0], 16); 533 if (nseg == NULL) { 534 sa->sge->intr_cnt.tx_no_dma2++; 535 536 /* 537 * ran out of space. Gona bale 538 */ 539 rv = 0; 540 goto error1; 541 } 542 } 543 #else /* defined(__sparc) */ 544 nseg = ch_bind_dma_handle(sa, len, 545 (void *)mp->b_rptr, &hmp[0], 16); 546 if (nseg == 0) { 547 sa->sge->intr_cnt.tx_no_dma2++; 548 549 /* 550 * ran out of space. Gona bale 551 */ 552 rv = 0; 553 goto error1; 554 } 555 #endif /* defined(__sparc) */ 556 557 /* 558 * dummy arp message to handle PR3309 & PR2928 559 */ 560 if (flg & CH_ARP) 561 hmp->ce_flg |= DH_ARP; 562 } 563 564 if (sge_data_out(sa->sge, 0, m0, hmp, nseg, flg) == 0) { 565 if (cm_flg) 566 kmem_free(hmp, mseg * sizeof (cmdQ_ce_t)); 567 return (0); 568 } 569 570 /* 571 * set a flag so we'll restart upper layer when 572 * resources become available. 573 */ 574 if ((flg & CH_ARP) == 0) 575 sa->ch_blked = 1; 576 rv = 1; 577 578 error: 579 /* 580 * unmap the physical addresses allocated earlier. 581 */ 582 cmp = hmp; 583 for (--nseg; nseg >= 0; nseg--) { 584 if (cmp->ce_dh) { 585 if (cmp->ce_flg == DH_DMA) 586 ch_unbind_dma_handle(sa, cmp->ce_dh); 587 #if defined(__sparc) 588 else 589 ch_unbind_dvma_handle(sa, cmp->ce_dh); 590 #endif 591 } 592 cmp++; 593 } 594 595 error1: 596 597 /* free the temporary array */ 598 if (cm_flg) 599 kmem_free(hmp, mseg * sizeof (cmdQ_ce_t)); 600 601 /* 602 * if we've allocated an mblk above, then we need to free it 603 * before returning. This is safe since we haven't done anything to 604 * the original message. The caller, gld, will still have a pointer 605 * to the original mblk. 606 */ 607 if (rv == 1) { 608 if (freeme) { 609 /* we had to allocate an mblk. Free it. */ 610 freeb(m0); 611 } else { 612 /* adjust the mblk back to original start */ 613 if (flg & CH_NO_CPL) 614 m0->b_rptr += SZ_CPL_TX_PKT; 615 } 616 } else { 617 freemsg(m0); 618 sa->oerr++; 619 } 620 621 return (rv); 622 } 623 624 /* KLUDGE ALERT. HARD WIRED TO PORT ZERO */ 625 void 626 pe_set_mac(ch_t *sa, unsigned char *ac_enaddr) 627 { 628 sa->port[0].mac->ops->macaddress_set(sa->port[0].mac, ac_enaddr); 629 } 630 631 /* KLUDGE ALERT. HARD WIRED TO PORT ZERO */ 632 unsigned char * 633 pe_get_mac(ch_t *sa) 634 { 635 return (sa->port[0].enaddr); 636 } 637 638 /* KLUDGE ALERT. HARD WIRED TO ONE PORT */ 639 void 640 pe_set_promiscuous(ch_t *sa, int flag) 641 { 642 struct cmac *mac = sa->port[0].mac; 643 struct t1_rx_mode rm; 644 645 switch (flag) { 646 case 0: /* turn off promiscuous mode */ 647 sa->ch_flags &= ~(PEPROMISC|PEALLMULTI); 648 break; 649 650 case 1: /* turn on promiscuous mode */ 651 sa->ch_flags |= PEPROMISC; 652 break; 653 654 case 2: /* turn on multicast reception */ 655 sa->ch_flags |= PEALLMULTI; 656 break; 657 } 658 659 mutex_enter(&sa->ch_mc_lck); 660 rm.chp = sa; 661 rm.mc = sa->ch_mc; 662 663 mac->ops->set_rx_mode(mac, &rm); 664 mutex_exit(&sa->ch_mc_lck); 665 } 666 667 int 668 pe_set_mc(ch_t *sa, uint8_t *ep, int flg) 669 { 670 struct cmac *mac = sa->port[0].mac; 671 struct t1_rx_mode rm; 672 673 if (flg == GLD_MULTI_ENABLE) { 674 ch_mc_t *mcp; 675 676 mcp = (ch_mc_t *)kmem_zalloc(sizeof (struct ch_mc), 677 KM_NOSLEEP); 678 if (mcp == NULL) 679 return (GLD_NORESOURCES); 680 681 bcopy(ep, &mcp->cmc_mca, 6); 682 683 mutex_enter(&sa->ch_mc_lck); 684 mcp->cmc_next = sa->ch_mc; 685 sa->ch_mc = mcp; 686 sa->ch_mc_cnt++; 687 mutex_exit(&sa->ch_mc_lck); 688 689 } else if (flg == GLD_MULTI_DISABLE) { 690 ch_mc_t **p = &sa->ch_mc; 691 ch_mc_t *q = NULL; 692 693 mutex_enter(&sa->ch_mc_lck); 694 p = &sa->ch_mc; 695 while (*p) { 696 if (bcmp(ep, (*p)->cmc_mca, 6) == 0) { 697 q = *p; 698 *p = (*p)->cmc_next; 699 kmem_free(q, sizeof (*q)); 700 sa->ch_mc_cnt--; 701 break; 702 } 703 704 p = &(*p)->cmc_next; 705 } 706 mutex_exit(&sa->ch_mc_lck); 707 708 if (q == NULL) 709 return (GLD_BADARG); 710 } else 711 return (GLD_BADARG); 712 713 mutex_enter(&sa->ch_mc_lck); 714 rm.chp = sa; 715 rm.mc = sa->ch_mc; 716 717 mac->ops->set_rx_mode(mac, &rm); 718 mutex_exit(&sa->ch_mc_lck); 719 720 return (GLD_SUCCESS); 721 } 722 723 /* 724 * return: speed - bandwidth of interface 725 * return: intrcnt - # interrupts 726 * return: norcvbuf - # recedived packets dropped by driver 727 * return: oerrors - # bad send packets 728 * return: ierrors - # bad receive packets 729 * return: underrun - # bad underrun xmit packets 730 * return: overrun - # bad overrun recv packets 731 * return: framing - # bad aligned recv packets 732 * return: crc - # bad FCS (crc) recv packets 733 * return: carrier - times carrier was lost 734 * return: collisions - # xmit collisions 735 * return: xcollisions - # xmit pkts dropped due to collisions 736 * return: late - # late xmit collisions 737 * return: defer - # deferred xmit packets 738 * return: xerrs - # xmit dropped packets 739 * return: rerrs - # recv dropped packets 740 * return: toolong - # recv pkts too long 741 * return: runt - # recv runt pkts 742 * return: multixmt - # multicast pkts xmitted 743 * return: multircv - # multicast pkts recved 744 * return: brdcstxmt - # broadcast pkts xmitted 745 * return: brdcstrcv - # broadcast pkts rcv 746 */ 747 748 int 749 pe_get_stats(ch_t *sa, uint64_t *speed, uint32_t *intrcnt, uint32_t *norcvbuf, 750 uint32_t *oerrors, uint32_t *ierrors, uint32_t *underrun, 751 uint32_t *overrun, uint32_t *framing, uint32_t *crc, 752 uint32_t *carrier, uint32_t *collisions, uint32_t *xcollisions, 753 uint32_t *late, uint32_t *defer, uint32_t *xerrs, uint32_t *rerrs, 754 uint32_t *toolong, uint32_t *runt, ulong_t *multixmt, ulong_t *multircv, 755 ulong_t *brdcstxmt, ulong_t *brdcstrcv) 756 { 757 struct pe_port_t *pt; 758 int line_speed; 759 int line_duplex; 760 int line_is_active; 761 uint64_t v; 762 const struct cmac_statistics *sp; 763 764 pt = &(sa->port[0]); 765 (void) pt->phy->ops->get_link_status(pt->phy, 766 &line_is_active, &line_speed, &line_duplex, NULL); 767 768 switch (line_speed) { 769 case SPEED_10: 770 *speed = 10000000; 771 break; 772 case SPEED_100: 773 *speed = 100000000; 774 break; 775 case SPEED_1000: 776 *speed = 1000000000; 777 break; 778 case SPEED_10000: 779 /* 780 * kludge to get 10,000,000,000 constant (and keep 781 * compiler happy). 782 */ 783 v = 10000000; 784 v *= 1000; 785 *speed = v; 786 break; 787 default: 788 goto error; 789 } 790 791 *intrcnt = sa->isr_intr; 792 *norcvbuf = sa->norcvbuf; 793 794 sp = sa->port[0].mac->ops->statistics_update(sa->port[0].mac, 795 MAC_STATS_UPDATE_FULL); 796 797 *ierrors = sp->RxOctetsBad; 798 799 /* 800 * not sure this is correct. # aborted at driver level + 801 * # at hardware level 802 */ 803 *oerrors = sa->oerr + sp->TxFramesAbortedDueToXSCollisions + 804 sp->TxUnderrun + sp->TxLengthErrors + 805 sp->TxInternalMACXmitError + 806 sp->TxFramesWithExcessiveDeferral + 807 sp->TxFCSErrors; 808 809 *underrun = sp->TxUnderrun; 810 *overrun = sp->RxFrameTooLongErrors; 811 *framing = sp->RxAlignErrors; 812 *crc = sp->RxFCSErrors; 813 *carrier = 0; /* need to find this */ 814 *collisions = sp->TxTotalCollisions; 815 *xcollisions = sp->TxFramesAbortedDueToXSCollisions; 816 *late = sp->TxLateCollisions; 817 *defer = sp->TxFramesWithDeferredXmissions; 818 *xerrs = sp->TxUnderrun + sp->TxLengthErrors + 819 sp->TxInternalMACXmitError + sp->TxFCSErrors; 820 *rerrs = sp->RxSymbolErrors + sp->RxSequenceErrors + sp->RxRuntErrors + 821 sp->RxJabberErrors + sp->RxInternalMACRcvError + 822 sp->RxInRangeLengthErrors + sp->RxOutOfRangeLengthField; 823 *toolong = sp->RxFrameTooLongErrors; 824 *runt = sp->RxRuntErrors; 825 826 *multixmt = sp->TxMulticastFramesOK; 827 *multircv = sp->RxMulticastFramesOK; 828 *brdcstxmt = sp->TxBroadcastFramesOK; 829 *brdcstrcv = sp->RxBroadcastFramesOK; 830 831 return (0); 832 833 error: 834 *speed = 0; 835 *intrcnt = 0; 836 *norcvbuf = 0; 837 *norcvbuf = 0; 838 *oerrors = 0; 839 *ierrors = 0; 840 *underrun = 0; 841 *overrun = 0; 842 *framing = 0; 843 *crc = 0; 844 *carrier = 0; 845 *collisions = 0; 846 *xcollisions = 0; 847 *late = 0; 848 *defer = 0; 849 *xerrs = 0; 850 *rerrs = 0; 851 *toolong = 0; 852 *runt = 0; 853 *multixmt = 0; 854 *multircv = 0; 855 *brdcstxmt = 0; 856 *brdcstrcv = 0; 857 858 return (1); 859 } 860 861 uint32_t ch_gtm = 0; /* Default: Global Tunnel Mode off */ 862 uint32_t ch_global_config = 0x07000000; /* Default: errors, warnings, status */ 863 uint32_t ch_is_asic = 0; /* Default: non-ASIC */ 864 uint32_t ch_link_speed = PE_LINK_SPEED_AUTONEG; /* Default: auto-negoiate */ 865 uint32_t ch_num_of_ports = 1; /* Default: 1 port */ 866 uint32_t ch_tp_reset_cm = 1; /* Default: reset CM memory map */ 867 uint32_t ch_phy_tx_fifo = 0; /* Default: 0 phy tx fifo depth */ 868 uint32_t ch_phy_rx_fifo = 0; /* Default: 0 phy rx fifo depth */ 869 uint32_t ch_phy_force_master = 1; /* Default: link always master mode */ 870 uint32_t ch_mc5_rtbl_size = 2048; /* Default: TCAM routing table size */ 871 uint32_t ch_mc5_dbsvr_size = 128; /* Default: TCAM server size */ 872 uint32_t ch_mc5_parity = 1; /* Default: parity error checking */ 873 uint32_t ch_mc5_issue_syn = 0; /* Default: Allow transaction overlap */ 874 uint32_t ch_packet_tracing = 0; /* Default: no packet tracing */ 875 uint32_t ch_server_region_len = 876 DEFAULT_SERVER_REGION_LEN; 877 uint32_t ch_rt_region_len = 878 DEFAULT_RT_REGION_LEN; 879 uint32_t ch_offload_ip_cksum = 0; /* Default: no checksum offloading */ 880 uint32_t ch_offload_udp_cksum = 1; /* Default: offload UDP ckecksum */ 881 uint32_t ch_offload_tcp_cksum = 1; /* Default: offload TCP checksum */ 882 uint32_t ch_sge_cmdq_threshold = 0; /* Default: threshold 0 */ 883 uint32_t ch_sge_flq_threshold = 0; /* Default: SGE flq threshold */ 884 uint32_t ch_sge_cmdq0_cnt = /* Default: cmd queue 0 size */ 885 SGE_CMDQ0_CNT; 886 uint32_t ch_sge_cmdq1_cnt = /* Default: cmd queue 1 size */ 887 SGE_CMDQ0_CNT; 888 uint32_t ch_sge_flq0_cnt = /* Default: free list queue-0 length */ 889 SGE_FLQ0_CNT; 890 uint32_t ch_sge_flq1_cnt = /* Default: free list queue-1 length */ 891 SGE_FLQ0_CNT; 892 uint32_t ch_sge_respq_cnt = /* Default: reqsponse queue size */ 893 SGE_RESPQ_CNT; 894 uint32_t ch_stats = 1; /* Default: Automatic Update MAC stats */ 895 uint32_t ch_tx_delay_us = 0; /* Default: No Msec delay to Tx pkts */ 896 int32_t ch_chip = -1; /* Default: use hardware lookup tbl */ 897 uint32_t ch_exit_early = 0; /* Default: complete initialization */ 898 uint32_t ch_rb_num_of_entries = 1000; /* Default: number ring buffer entries */ 899 uint32_t ch_rb_size_of_entries = 64; /* Default: ring buffer entry size */ 900 uint32_t ch_rb_flag = 1; /* Default: ring buffer flag */ 901 uint32_t ch_type; 902 uint64_t ch_cat_opt0 = 0; 903 uint64_t ch_cat_opt1 = 0; 904 uint32_t ch_timer_delay = 0; /* Default: use value from board entry */ 905 906 int 907 pe_attach(ch_t *chp) 908 { 909 int return_val = 1; 910 const struct board_info *bi; 911 uint32_t pcix_cmd; 912 913 (void) ch_set_config_data(chp); 914 915 bi = pe_sa_init(chp); 916 if (bi == 0) 917 return (1); 918 919 if (t1_init_sw_modules(chp, bi) < 0) 920 return (1); 921 922 if (pe_small_rbuf_pool_init(chp) == 0) 923 return (1); 924 925 if (pe_big_rbuf_pool_init(chp) == 0) 926 return (1); 927 928 /* 929 * We gain significaint performance improvements when we 930 * increase the PCI's maximum memory read byte count to 931 * 2K(HW doesn't support 4K at this time) and set the PCI's 932 * maximum outstanding split transactions to 4. We want to do 933 * this for 10G. Done by software utility. 934 */ 935 936 if (board_info(chp)->caps & SUPPORTED_10000baseT_Full) { 937 (void) t1_os_pci_read_config_4(chp, A_PCICFG_PCIX_CMD, 938 &pcix_cmd); 939 /* 940 * if the burstsize is set, then use it instead of default 941 */ 942 if (chp->ch_config.burstsize_set) { 943 pcix_cmd &= ~0xc0000; 944 pcix_cmd |= (chp->ch_config.burstsize << 18); 945 } 946 /* 947 * if the split transaction count is set, then use it. 948 */ 949 if (chp->ch_config.transaction_cnt_set) { 950 pcix_cmd &= ~ 0x700000; 951 pcix_cmd |= (chp->ch_config.transaction_cnt << 20); 952 } 953 954 /* 955 * set ralaxed ordering flag as configured in chxge.conf 956 */ 957 pcix_cmd |= (chp->ch_config.relaxed_ordering << 17); 958 959 (void) t1_os_pci_write_config_4(chp, A_PCICFG_PCIX_CMD, 960 pcix_cmd); 961 } 962 963 /* 964 * set the latency time to F8 for 10G cards. 965 * Done by software utiltiy. 966 */ 967 if (enable_latency_timer) { 968 if (board_info(chp)->caps & SUPPORTED_10000baseT_Full) { 969 (void) t1_os_pci_write_config_4(chp, 0xc, 0xf800); 970 } 971 } 972 973 /* 974 * update mtu table (regs: 0x404 - 0x420) with bigger values than 975 * default. 976 */ 977 update_mtu_tab(chp); 978 979 /* 980 * Clear all interrupts now. Don't enable 981 * them until later. 982 */ 983 t1_interrupts_clear(chp); 984 985 /* 986 * Function succeeded. 987 */ 988 return_val = 0; 989 990 return (return_val); 991 } 992 993 /* 994 * DESC: Read variables set in /boot/loader.conf and save 995 * them internally. These internal values are then 996 * used to make decisions at run-time on behavior thus 997 * allowing a certain level of customization. 998 * OUT: p_config - pointer to config structure that 999 * contains all of the new values. 1000 * RTN: 0 - Success; 1001 */ 1002 static int 1003 ch_set_config_data(ch_t *chp) 1004 { 1005 pe_config_data_t *p_config = (pe_config_data_t *)&chp->config_data; 1006 1007 bzero(p_config, sizeof (pe_config_data_t)); 1008 1009 /* 1010 * Global Tunnel Mode configuration 1011 */ 1012 p_config->gtm = ch_gtm; 1013 1014 p_config->global_config = ch_global_config; 1015 1016 if (p_config->gtm) 1017 p_config->global_config |= CFGMD_TUNNEL; 1018 1019 p_config->tp_reset_cm = ch_tp_reset_cm; 1020 p_config->is_asic = ch_is_asic; 1021 1022 /* 1023 * MC5 configuration. 1024 */ 1025 p_config->mc5_rtbl_size = ch_mc5_rtbl_size; 1026 p_config->mc5_dbsvr_size = ch_mc5_dbsvr_size; 1027 p_config->mc5_parity = ch_mc5_parity; 1028 p_config->mc5_issue_syn = ch_mc5_issue_syn; 1029 1030 p_config->offload_ip_cksum = ch_offload_ip_cksum; 1031 p_config->offload_udp_cksum = ch_offload_udp_cksum; 1032 p_config->offload_tcp_cksum = ch_offload_tcp_cksum; 1033 1034 p_config->packet_tracing = ch_packet_tracing; 1035 1036 p_config->server_region_len = ch_server_region_len; 1037 p_config->rt_region_len = ch_rt_region_len; 1038 1039 /* 1040 * Link configuration. 1041 * 1042 * 5-auto-neg 2-1000Gbps; 1-100Gbps; 0-10Gbps 1043 */ 1044 p_config->link_speed = ch_link_speed; 1045 p_config->num_of_ports = ch_num_of_ports; 1046 1047 /* 1048 * Catp options 1049 */ 1050 p_config->cat_opt0 = ch_cat_opt0; 1051 p_config->cat_opt1 = ch_cat_opt1; 1052 1053 /* 1054 * SGE configuration. 1055 */ 1056 p_config->sge_cmdq0_cnt = ch_sge_cmdq0_cnt; 1057 p_config->sge_cmdq1_cnt = ch_sge_cmdq1_cnt; 1058 p_config->sge_flq0_cnt = ch_sge_flq0_cnt; 1059 p_config->sge_flq1_cnt = ch_sge_flq1_cnt; 1060 p_config->sge_respq_cnt = ch_sge_respq_cnt; 1061 1062 p_config->phy_rx_fifo = ch_phy_rx_fifo; 1063 p_config->phy_tx_fifo = ch_phy_tx_fifo; 1064 1065 p_config->sge_cmdq_threshold = ch_sge_cmdq_threshold; 1066 1067 p_config->sge_flq_threshold = ch_sge_flq_threshold; 1068 1069 p_config->phy_force_master = ch_phy_force_master; 1070 1071 p_config->rb_num_of_entries = ch_rb_num_of_entries; 1072 1073 p_config->rb_size_of_entries = ch_rb_size_of_entries; 1074 1075 p_config->rb_flag = ch_rb_flag; 1076 1077 p_config->exit_early = ch_exit_early; 1078 1079 p_config->chip = ch_chip; 1080 1081 p_config->stats = ch_stats; 1082 1083 p_config->tx_delay_us = ch_tx_delay_us; 1084 1085 return (0); 1086 } 1087 1088 static const struct board_info * 1089 pe_sa_init(ch_t *sa) 1090 { 1091 uint16_t device_id; 1092 uint16_t device_subid; 1093 const struct board_info *bi; 1094 1095 sa->config = sa->config_data.global_config; 1096 device_id = pci_config_get16(sa->ch_hpci, 2); 1097 device_subid = pci_config_get16(sa->ch_hpci, 0x2e); 1098 1099 bi = t1_get_board_info_from_ids(device_id, device_subid); 1100 if (bi == NULL) { 1101 cmn_err(CE_NOTE, 1102 "The adapter with device_id %d %d is not supported.\n", 1103 device_id, device_subid); 1104 return (NULL); 1105 } 1106 1107 if (t1_get_board_rev(sa, bi, &sa->params)) { 1108 cmn_err(CE_NOTE, "unknown device_id %d %d\n", 1109 device_id, device_subid); 1110 return ((const struct board_info *)NULL); 1111 } 1112 1113 return (bi); 1114 } 1115 1116 /* 1117 * allocate pool of small receive buffers (with vaddr & paddr) and 1118 * receiver buffer control structure (ch_esb_t *rbp). 1119 * XXX we should allow better tuning of the # of preallocated 1120 * free buffers against the # of freelist entries. 1121 */ 1122 static int 1123 pe_small_rbuf_pool_init(ch_t *sa) 1124 { 1125 int i; 1126 ch_esb_t *rbp; 1127 extern uint32_t sge_flq0_cnt; 1128 extern uint32_t sge_flq1_cnt; 1129 int size; 1130 uint32_t j; 1131 1132 if (is_T2(sa)) 1133 size = sge_flq1_cnt * fl_sz_multiplier; 1134 else 1135 size = sge_flq0_cnt * fl_sz_multiplier; 1136 1137 mutex_init(&sa->ch_small_esbl, NULL, MUTEX_DRIVER, sa->ch_icookp); 1138 1139 mutex_enter(&in_use_l); 1140 j = in_use_index++; 1141 if (in_use_index >= SZ_INUSE) 1142 in_use_index = 0; 1143 mutex_exit(&in_use_l); 1144 1145 sa->ch_small_owner = NULL; 1146 sa->ch_sm_index = j; 1147 sa->ch_small_esb_free = NULL; 1148 for (i = 0; i < size; i++) { 1149 rbp = ch_alloc_small_esbbuf(sa, j); 1150 if (rbp == NULL) 1151 goto error; 1152 /* 1153 * add entry to free list 1154 */ 1155 rbp->cs_next = sa->ch_small_esb_free; 1156 sa->ch_small_esb_free = rbp; 1157 1158 /* 1159 * add entry to owned list 1160 */ 1161 rbp->cs_owner = sa->ch_small_owner; 1162 sa->ch_small_owner = rbp; 1163 } 1164 return (1); 1165 1166 error: 1167 sa->ch_small_owner = NULL; 1168 1169 /* free whatever we've already allocated */ 1170 pe_rbuf_pool_free(sa); 1171 1172 return (0); 1173 } 1174 1175 /* 1176 * allocate pool of receive buffers (with vaddr & paddr) and 1177 * receiver buffer control structure (ch_esb_t *rbp). 1178 * XXX we should allow better tuning of the # of preallocated 1179 * free buffers against the # of freelist entries. 1180 */ 1181 static int 1182 pe_big_rbuf_pool_init(ch_t *sa) 1183 { 1184 int i; 1185 ch_esb_t *rbp; 1186 extern uint32_t sge_flq0_cnt; 1187 extern uint32_t sge_flq1_cnt; 1188 int size; 1189 uint32_t j; 1190 1191 if (is_T2(sa)) 1192 size = sge_flq0_cnt * fl_sz_multiplier; 1193 else 1194 size = sge_flq1_cnt * fl_sz_multiplier; 1195 1196 mutex_init(&sa->ch_big_esbl, NULL, MUTEX_DRIVER, sa->ch_icookp); 1197 1198 mutex_enter(&in_use_l); 1199 j = in_use_index++; 1200 if (in_use_index >= SZ_INUSE) 1201 in_use_index = 0; 1202 mutex_exit(&in_use_l); 1203 1204 sa->ch_big_owner = NULL; 1205 sa->ch_big_index = j; 1206 sa->ch_big_esb_free = NULL; 1207 for (i = 0; i < size; i++) { 1208 rbp = ch_alloc_big_esbbuf(sa, j); 1209 if (rbp == NULL) 1210 goto error; 1211 rbp->cs_next = sa->ch_big_esb_free; 1212 sa->ch_big_esb_free = rbp; 1213 1214 /* 1215 * add entry to owned list 1216 */ 1217 rbp->cs_owner = sa->ch_big_owner; 1218 sa->ch_big_owner = rbp; 1219 } 1220 return (1); 1221 1222 error: 1223 sa->ch_big_owner = NULL; 1224 1225 /* free whatever we've already allocated */ 1226 pe_rbuf_pool_free(sa); 1227 1228 return (0); 1229 } 1230 1231 /* 1232 * allocate receive buffer structure and dma mapped buffer (SGE_SM_BUF_SZ bytes) 1233 * note that we will DMA at a 2 byte offset for Solaris when checksum offload 1234 * is enabled. 1235 */ 1236 static ch_esb_t * 1237 ch_alloc_small_esbbuf(ch_t *sa, uint32_t i) 1238 { 1239 ch_esb_t *rbp; 1240 1241 rbp = (ch_esb_t *)kmem_zalloc(sizeof (ch_esb_t), KM_SLEEP); 1242 if (rbp == NULL) { 1243 return ((ch_esb_t *)0); 1244 } 1245 1246 #if BYTE_ORDER == BIG_ENDIAN 1247 rbp->cs_buf = (caddr_t)ch_alloc_dma_mem(sa, 1, DMA_STREAM|DMA_SMALN, 1248 SGE_SM_BUF_SZ(sa), &rbp->cs_pa, &rbp->cs_dh, &rbp->cs_ah); 1249 #else 1250 rbp->cs_buf = (caddr_t)ch_alloc_dma_mem(sa, 0, DMA_STREAM|DMA_SMALN, 1251 SGE_SM_BUF_SZ(sa), &rbp->cs_pa, &rbp->cs_dh, &rbp->cs_ah); 1252 #endif 1253 1254 if (rbp->cs_buf == NULL) { 1255 kmem_free(rbp, sizeof (ch_esb_t)); 1256 return ((ch_esb_t *)0); 1257 } 1258 1259 rbp->cs_sa = sa; 1260 rbp->cs_index = i; 1261 1262 rbp->cs_frtn.free_func = (void (*)())&ch_small_rbuf_recycle; 1263 rbp->cs_frtn.free_arg = (caddr_t)rbp; 1264 1265 return (rbp); 1266 } 1267 1268 /* 1269 * allocate receive buffer structure and dma mapped buffer (SGE_BG_BUF_SZ bytes) 1270 * note that we will DMA at a 2 byte offset for Solaris when checksum offload 1271 * is enabled. 1272 */ 1273 static ch_esb_t * 1274 ch_alloc_big_esbbuf(ch_t *sa, uint32_t i) 1275 { 1276 ch_esb_t *rbp; 1277 1278 rbp = (ch_esb_t *)kmem_zalloc(sizeof (ch_esb_t), KM_SLEEP); 1279 if (rbp == NULL) { 1280 return ((ch_esb_t *)0); 1281 } 1282 1283 #if BYTE_ORDER == BIG_ENDIAN 1284 rbp->cs_buf = (caddr_t)ch_alloc_dma_mem(sa, 1, DMA_STREAM|DMA_BGALN, 1285 SGE_BG_BUF_SZ(sa), &rbp->cs_pa, &rbp->cs_dh, &rbp->cs_ah); 1286 #else 1287 rbp->cs_buf = (caddr_t)ch_alloc_dma_mem(sa, 0, DMA_STREAM|DMA_BGALN, 1288 SGE_BG_BUF_SZ(sa), &rbp->cs_pa, &rbp->cs_dh, &rbp->cs_ah); 1289 #endif 1290 1291 if (rbp->cs_buf == NULL) { 1292 kmem_free(rbp, sizeof (ch_esb_t)); 1293 return ((ch_esb_t *)0); 1294 } 1295 1296 rbp->cs_sa = sa; 1297 rbp->cs_index = i; 1298 1299 rbp->cs_frtn.free_func = (void (*)())&ch_big_rbuf_recycle; 1300 rbp->cs_frtn.free_arg = (caddr_t)rbp; 1301 1302 return (rbp); 1303 } 1304 1305 /* 1306 * free entries on the receive buffer list. 1307 */ 1308 void 1309 pe_rbuf_pool_free(ch_t *sa) 1310 { 1311 ch_esb_t *rbp; 1312 1313 mutex_enter(&sa->ch_small_esbl); 1314 1315 /* 1316 * Now set-up the rest to commit suicide. 1317 */ 1318 while (sa->ch_small_owner) { 1319 rbp = sa->ch_small_owner; 1320 sa->ch_small_owner = rbp->cs_owner; 1321 rbp->cs_owner = NULL; 1322 rbp->cs_flag = 1; 1323 } 1324 1325 while ((rbp = sa->ch_small_esb_free) != NULL) { 1326 /* advance head ptr to next entry */ 1327 sa->ch_small_esb_free = rbp->cs_next; 1328 /* free private buffer allocated in ch_alloc_esbbuf() */ 1329 ch_free_dma_mem(rbp->cs_dh, rbp->cs_ah); 1330 /* free descripter buffer */ 1331 kmem_free(rbp, sizeof (ch_esb_t)); 1332 } 1333 1334 mutex_exit(&sa->ch_small_esbl); 1335 1336 /* destroy ch_esbl lock */ 1337 mutex_destroy(&sa->ch_small_esbl); 1338 1339 1340 mutex_enter(&sa->ch_big_esbl); 1341 1342 /* 1343 * Now set-up the rest to commit suicide. 1344 */ 1345 while (sa->ch_big_owner) { 1346 rbp = sa->ch_big_owner; 1347 sa->ch_big_owner = rbp->cs_owner; 1348 rbp->cs_owner = NULL; 1349 rbp->cs_flag = 1; 1350 } 1351 1352 while ((rbp = sa->ch_big_esb_free) != NULL) { 1353 /* advance head ptr to next entry */ 1354 sa->ch_big_esb_free = rbp->cs_next; 1355 /* free private buffer allocated in ch_alloc_esbbuf() */ 1356 ch_free_dma_mem(rbp->cs_dh, rbp->cs_ah); 1357 /* free descripter buffer */ 1358 kmem_free(rbp, sizeof (ch_esb_t)); 1359 } 1360 1361 mutex_exit(&sa->ch_big_esbl); 1362 1363 /* destroy ch_esbl lock */ 1364 mutex_destroy(&sa->ch_big_esbl); 1365 } 1366 1367 void 1368 ch_small_rbuf_recycle(ch_esb_t *rbp) 1369 { 1370 ch_t *sa = rbp->cs_sa; 1371 1372 if (rbp->cs_flag) { 1373 uint32_t i; 1374 /* 1375 * free private buffer allocated in ch_alloc_esbbuf() 1376 */ 1377 ch_free_dma_mem(rbp->cs_dh, rbp->cs_ah); 1378 1379 i = rbp->cs_index; 1380 1381 /* 1382 * free descripter buffer 1383 */ 1384 kmem_free(rbp, sizeof (ch_esb_t)); 1385 1386 /* 1387 * decrement count of receive buffers freed by callback 1388 * We decrement here so anyone trying to do fini will 1389 * only remove the driver once the counts go to 0. 1390 */ 1391 atomic_dec_32(&buffers_in_use[i]); 1392 1393 return; 1394 } 1395 1396 mutex_enter(&sa->ch_small_esbl); 1397 rbp->cs_next = sa->ch_small_esb_free; 1398 sa->ch_small_esb_free = rbp; 1399 mutex_exit(&sa->ch_small_esbl); 1400 1401 /* 1402 * decrement count of receive buffers freed by callback 1403 */ 1404 atomic_dec_32(&buffers_in_use[rbp->cs_index]); 1405 } 1406 1407 /* 1408 * callback function from freeb() when esballoced mblk freed. 1409 */ 1410 void 1411 ch_big_rbuf_recycle(ch_esb_t *rbp) 1412 { 1413 ch_t *sa = rbp->cs_sa; 1414 1415 if (rbp->cs_flag) { 1416 uint32_t i; 1417 /* 1418 * free private buffer allocated in ch_alloc_esbbuf() 1419 */ 1420 ch_free_dma_mem(rbp->cs_dh, rbp->cs_ah); 1421 1422 i = rbp->cs_index; 1423 1424 /* 1425 * free descripter buffer 1426 */ 1427 kmem_free(rbp, sizeof (ch_esb_t)); 1428 1429 /* 1430 * decrement count of receive buffers freed by callback 1431 * We decrement here so anyone trying to do fini will 1432 * only remove the driver once the counts go to 0. 1433 */ 1434 atomic_dec_32(&buffers_in_use[i]); 1435 1436 return; 1437 } 1438 1439 mutex_enter(&sa->ch_big_esbl); 1440 rbp->cs_next = sa->ch_big_esb_free; 1441 sa->ch_big_esb_free = rbp; 1442 mutex_exit(&sa->ch_big_esbl); 1443 1444 /* 1445 * decrement count of receive buffers freed by callback 1446 */ 1447 atomic_dec_32(&buffers_in_use[rbp->cs_index]); 1448 } 1449 1450 /* 1451 * get a pre-allocated, pre-mapped receive buffer from free list. 1452 * (used sge.c) 1453 */ 1454 ch_esb_t * 1455 ch_get_small_rbuf(ch_t *sa) 1456 { 1457 ch_esb_t *rbp; 1458 1459 mutex_enter(&sa->ch_small_esbl); 1460 rbp = sa->ch_small_esb_free; 1461 if (rbp) { 1462 sa->ch_small_esb_free = rbp->cs_next; 1463 } 1464 mutex_exit(&sa->ch_small_esbl); 1465 1466 return (rbp); 1467 } 1468 1469 /* 1470 * get a pre-allocated, pre-mapped receive buffer from free list. 1471 * (used sge.c) 1472 */ 1473 1474 ch_esb_t * 1475 ch_get_big_rbuf(ch_t *sa) 1476 { 1477 ch_esb_t *rbp; 1478 1479 mutex_enter(&sa->ch_big_esbl); 1480 rbp = sa->ch_big_esb_free; 1481 if (rbp) { 1482 sa->ch_big_esb_free = rbp->cs_next; 1483 } 1484 mutex_exit(&sa->ch_big_esbl); 1485 1486 return (rbp); 1487 } 1488 1489 void 1490 pe_detach(ch_t *sa) 1491 { 1492 (void) sge_stop(sa->sge); 1493 1494 pe_free_driver_resources(sa); 1495 } 1496 1497 static void 1498 pe_free_driver_resources(ch_t *sa) 1499 { 1500 if (sa) { 1501 t1_free_sw_modules(sa); 1502 1503 /* free pool of receive buffers */ 1504 pe_rbuf_pool_free(sa); 1505 } 1506 } 1507 1508 /* 1509 * Processes elmer0 external interrupts in process context. 1510 */ 1511 static void 1512 ext_intr_task(ch_t *adapter) 1513 { 1514 u32 enable; 1515 1516 (void) elmer0_ext_intr_handler(adapter); 1517 1518 /* Now reenable external interrupts */ 1519 t1_write_reg_4(adapter, A_PL_CAUSE, F_PL_INTR_EXT); 1520 enable = t1_read_reg_4(adapter, A_PL_ENABLE); 1521 t1_write_reg_4(adapter, A_PL_ENABLE, enable | F_PL_INTR_EXT); 1522 adapter->slow_intr_mask |= F_PL_INTR_EXT; 1523 } 1524 1525 /* 1526 * Interrupt-context handler for elmer0 external interrupts. 1527 */ 1528 void 1529 t1_os_elmer0_ext_intr(ch_t *adapter) 1530 { 1531 u32 enable = t1_read_reg_4(adapter, A_PL_ENABLE); 1532 1533 adapter->slow_intr_mask &= ~F_PL_INTR_EXT; 1534 t1_write_reg_4(adapter, A_PL_ENABLE, enable & ~F_PL_INTR_EXT); 1535 #ifdef NOTYET 1536 schedule_work(&adapter->ext_intr_handler_task); 1537 #else 1538 ext_intr_task(adapter); 1539 #endif 1540 } 1541 1542 uint8_t * 1543 t1_get_next_mcaddr(struct t1_rx_mode *rmp) 1544 { 1545 uint8_t *addr = 0; 1546 if (rmp->mc) { 1547 addr = rmp->mc->cmc_mca; 1548 rmp->mc = rmp->mc->cmc_next; 1549 } 1550 return (addr); 1551 } 1552 1553 void 1554 pe_dma_handle_init(ch_t *chp, int cnt) 1555 { 1556 free_dh_t *dhe; 1557 #if defined(__sparc) 1558 int tcnt = cnt/2; 1559 1560 for (; cnt; cnt--) { 1561 dhe = ch_get_dvma_handle(chp); 1562 if (dhe == NULL) 1563 break; 1564 mutex_enter(&chp->ch_dh_lck); 1565 dhe->dhe_next = chp->ch_vdh; 1566 chp->ch_vdh = dhe; 1567 mutex_exit(&chp->ch_dh_lck); 1568 } 1569 1570 cnt += tcnt; 1571 #endif 1572 while (cnt--) { 1573 dhe = ch_get_dma_handle(chp); 1574 if (dhe == NULL) 1575 return; 1576 mutex_enter(&chp->ch_dh_lck); 1577 dhe->dhe_next = chp->ch_dh; 1578 chp->ch_dh = dhe; 1579 mutex_exit(&chp->ch_dh_lck); 1580 } 1581 } 1582 1583 /* 1584 * Write new values to the MTU table. Caller must validate that the new MTUs 1585 * are in ascending order. params.mtus[] is initialized by init_mtus() 1586 * called in t1_init_sw_modules(). 1587 */ 1588 #define MTUREG(idx) (A_TP_MTU_REG0 + (idx) * 4) 1589 1590 static void 1591 update_mtu_tab(ch_t *adapter) 1592 { 1593 int i; 1594 1595 for (i = 0; i < NMTUS; ++i) { 1596 int mtu = (unsigned int)adapter->params.mtus[i]; 1597 1598 t1_write_reg_4(adapter, MTUREG(i), mtu); 1599 } 1600 } 1601 1602 static int 1603 pe_change_mtu(ch_t *chp) 1604 { 1605 struct cmac *mac = chp->port[0].mac; 1606 int ret; 1607 1608 if (!mac->ops->set_mtu) { 1609 return (EOPNOTSUPP); 1610 } 1611 if (chp->ch_mtu < 68) { 1612 return (EINVAL); 1613 } 1614 if (ret = mac->ops->set_mtu(mac, chp->ch_mtu)) { 1615 return (ret); 1616 } 1617 1618 return (0); 1619 } 1620 1621 typedef struct fake_arp { 1622 char fa_dst[6]; /* ethernet header */ 1623 char fa_src[6]; /* ethernet header */ 1624 ushort_t fa_typ; /* ethernet header */ 1625 1626 ushort_t fa_hrd; /* arp */ 1627 ushort_t fa_pro; 1628 char fa_hln; 1629 char fa_pln; 1630 ushort_t fa_op; 1631 char fa_src_mac[6]; 1632 uint_t fa_src_ip; 1633 char fa_dst_mac[6]; 1634 char fa_dst_ip[4]; 1635 } fake_arp_t; 1636 1637 /* 1638 * PR2928 & PR3309 1639 * construct packet in mblk and attach it to sge structure. 1640 */ 1641 static int 1642 pe_make_fake_arp(ch_t *chp, unsigned char *arpp) 1643 { 1644 pesge *sge = chp->sge; 1645 mblk_t *bp; 1646 fake_arp_t *fap; 1647 static char buf[6] = {0, 7, 0x43, 0, 0, 0}; 1648 struct cpl_tx_pkt *cpl; 1649 1650 bp = allocb(sizeof (struct fake_arp) + SZ_CPL_TX_PKT, BPRI_HI); 1651 if (bp == NULL) { 1652 return (1); 1653 } 1654 bzero(bp->b_rptr, sizeof (struct fake_arp) + SZ_CPL_TX_PKT); 1655 1656 /* fill in cpl header */ 1657 cpl = (struct cpl_tx_pkt *)bp->b_rptr; 1658 cpl->opcode = CPL_TX_PKT; 1659 cpl->iff = 0; /* XXX port 0 needs fixing with NEMO */ 1660 cpl->ip_csum_dis = 1; /* no IP header cksum */ 1661 cpl->l4_csum_dis = 1; /* no tcp/udp cksum */ 1662 cpl->vlan_valid = 0; /* no vlan */ 1663 1664 fap = (fake_arp_t *)&bp->b_rptr[SZ_CPL_TX_PKT]; 1665 1666 bcopy(arpp, fap, sizeof (*fap)); /* copy first arp to mblk */ 1667 1668 bcopy(buf, fap->fa_dst, 6); /* overwrite dst mac */ 1669 chp->ch_ip = fap->fa_src_ip; /* not used yet */ 1670 bcopy(buf, fap->fa_dst_mac, 6); /* overwrite dst mac */ 1671 1672 bp->b_wptr = bp->b_rptr + sizeof (struct fake_arp)+SZ_CPL_TX_PKT; 1673 1674 sge_add_fake_arp(sge, (void *)bp); 1675 1676 return (0); 1677 } 1678 1679 /* 1680 * PR2928 & PR3309 1681 * free the fake arp's mblk on sge structure. 1682 */ 1683 void 1684 pe_free_fake_arp(void *arp) 1685 { 1686 mblk_t *bp = (mblk_t *)(arp); 1687 1688 freemsg(bp); 1689 } 1690 1691 /* 1692 * extract ip address of nic from first outgoing arp. 1693 */ 1694 static uint32_t 1695 pe_get_ip(unsigned char *arpp) 1696 { 1697 fake_arp_t fap; 1698 1699 /* 1700 * first copy packet to buffer so we know 1701 * it will be properly aligned. 1702 */ 1703 bcopy(arpp, &fap, sizeof (fap)); /* copy first arp to buffer */ 1704 return (fap.fa_src_ip); 1705 } 1706 1707 /* ARGSUSED */ 1708 void 1709 t1_os_link_changed(ch_t *obj, int port_id, int link_status, 1710 int speed, int duplex, int fc) 1711 { 1712 gld_mac_info_t *macinfo = obj->ch_macp; 1713 if (link_status) { 1714 gld_linkstate(macinfo, GLD_LINKSTATE_UP); 1715 /* 1716 * Link states should be reported to user 1717 * whenever it changes 1718 */ 1719 cmn_err(CE_NOTE, "%s: link is up", adapter_name(obj)); 1720 } else { 1721 gld_linkstate(macinfo, GLD_LINKSTATE_DOWN); 1722 /* 1723 * Link states should be reported to user 1724 * whenever it changes 1725 */ 1726 cmn_err(CE_NOTE, "%s: link is down", adapter_name(obj)); 1727 } 1728 } 1729