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 * Copyright 2007 Sun Microsystems, Inc. All rights reserved. 23 * Use is subject to license terms. 24 */ 25 26 #pragma ident "%Z%%M% %I% %E% SMI" 27 28 #include <sys/conf.h> 29 #include <sys/kmem.h> 30 #include <sys/debug.h> 31 #include <sys/modctl.h> 32 #include <sys/autoconf.h> 33 #include <sys/hwconf.h> 34 #include <sys/ddi_impldefs.h> 35 #include <sys/ddi.h> 36 #include <sys/sunddi.h> 37 #include <sys/sunndi.h> 38 #include <sys/ndi_impldefs.h> 39 #include <sys/machsystm.h> 40 #include <sys/fcode.h> 41 #include <sys/promif.h> 42 #include <sys/promimpl.h> 43 #include <sys/opl_cfg.h> 44 #include <sys/scfd/scfostoescf.h> 45 46 static unsigned int opl_cfg_inited; 47 static opl_board_cfg_t opl_boards[HWD_SBS_PER_DOMAIN]; 48 49 /* 50 * Module control operations 51 */ 52 53 extern struct mod_ops mod_miscops; 54 55 static struct modlmisc modlmisc = { 56 &mod_miscops, /* Type of module */ 57 "OPL opl_cfg %I%" 58 }; 59 60 static struct modlinkage modlinkage = { 61 MODREV_1, (void *)&modlmisc, NULL 62 }; 63 64 static int opl_map_in(dev_info_t *, fco_handle_t, fc_ci_t *); 65 static int opl_map_out(dev_info_t *, fco_handle_t, fc_ci_t *); 66 static int opl_register_fetch(dev_info_t *, fco_handle_t, fc_ci_t *); 67 static int opl_register_store(dev_info_t *, fco_handle_t, fc_ci_t *); 68 69 static int opl_claim_memory(dev_info_t *, fco_handle_t, fc_ci_t *); 70 static int opl_release_memory(dev_info_t *, fco_handle_t, fc_ci_t *); 71 static int opl_vtop(dev_info_t *, fco_handle_t, fc_ci_t *); 72 73 static int opl_config_child(dev_info_t *, fco_handle_t, fc_ci_t *); 74 75 static int opl_get_fcode_size(dev_info_t *, fco_handle_t, fc_ci_t *); 76 static int opl_get_fcode(dev_info_t *, fco_handle_t, fc_ci_t *); 77 78 static int opl_map_phys(dev_info_t *, struct regspec *, caddr_t *, 79 ddi_device_acc_attr_t *, ddi_acc_handle_t *); 80 static void opl_unmap_phys(ddi_acc_handle_t *); 81 static int opl_get_hwd_va(dev_info_t *, fco_handle_t, fc_ci_t *); 82 static int opl_master_interrupt(dev_info_t *, fco_handle_t, fc_ci_t *); 83 84 extern int prom_get_fcode_size(char *); 85 extern int prom_get_fcode(char *, char *); 86 87 static int master_interrupt_init(uint32_t, uint32_t); 88 89 #define PROBE_STR_SIZE 64 90 #define UNIT_ADDR_SIZE 64 91 92 opl_fc_ops_t opl_fc_ops[] = { 93 94 { FC_MAP_IN, opl_map_in}, 95 { FC_MAP_OUT, opl_map_out}, 96 { "rx@", opl_register_fetch}, 97 { FC_RL_FETCH, opl_register_fetch}, 98 { FC_RW_FETCH, opl_register_fetch}, 99 { FC_RB_FETCH, opl_register_fetch}, 100 { "rx!", opl_register_store}, 101 { FC_RL_STORE, opl_register_store}, 102 { FC_RW_STORE, opl_register_store}, 103 { FC_RB_STORE, opl_register_store}, 104 { "claim-memory", opl_claim_memory}, 105 { "release-memory", opl_release_memory}, 106 { "vtop", opl_vtop}, 107 { FC_CONFIG_CHILD, opl_config_child}, 108 { FC_GET_FCODE_SIZE, opl_get_fcode_size}, 109 { FC_GET_FCODE, opl_get_fcode}, 110 { "get-hwd-va", opl_get_hwd_va}, 111 { "master-interrupt", opl_master_interrupt}, 112 { NULL, NULL} 113 114 }; 115 116 extern caddr_t efcode_vaddr; 117 extern int efcode_size; 118 119 #ifdef DEBUG 120 #define HWDDUMP_OFFSETS 1 121 #define HWDDUMP_ALL_STATUS 2 122 #define HWDDUMP_CHUNKS 3 123 #define HWDDUMP_SBP 4 124 125 int hwddump_flags = HWDDUMP_SBP | HWDDUMP_CHUNKS; 126 #endif 127 128 static int master_interrupt_inited = 0; 129 130 int 131 _init() 132 { 133 int err = 0; 134 135 /* 136 * Create a resource map for the contiguous memory allocated 137 * at start-of-day in startup.c 138 */ 139 err = ndi_ra_map_setup(ddi_root_node(), "opl-fcodemem"); 140 if (err == NDI_FAILURE) { 141 cmn_err(CE_WARN, "Cannot setup resource map opl-fcodemem\n"); 142 return (1); 143 } 144 145 /* 146 * Put the allocated memory into the pool. 147 */ 148 (void) ndi_ra_free(ddi_root_node(), (uint64_t)efcode_vaddr, 149 (uint64_t)efcode_size, "opl-fcodemem", 0); 150 151 if ((err = mod_install(&modlinkage)) != 0) { 152 cmn_err(CE_WARN, "opl_cfg failed to load, error=%d", err); 153 (void) ndi_ra_map_destroy(ddi_root_node(), "opl-fcodemem"); 154 } 155 156 return (err); 157 } 158 159 int 160 _fini(void) 161 { 162 int ret; 163 164 ret = (mod_remove(&modlinkage)); 165 if (ret != 0) 166 return (ret); 167 168 (void) ndi_ra_map_destroy(ddi_root_node(), "opl-fcodemem"); 169 170 return (ret); 171 } 172 173 int 174 _info(modinfop) 175 struct modinfo *modinfop; 176 { 177 return (mod_info(&modlinkage, modinfop)); 178 } 179 180 #ifdef DEBUG 181 static void 182 opl_dump_hwd(opl_probe_t *probe) 183 { 184 hwd_header_t *hdrp; 185 hwd_sb_status_t *statp; 186 hwd_domain_info_t *dinfop; 187 hwd_sb_t *sbp; 188 hwd_cpu_chip_t *chips; 189 hwd_pci_ch_t *channels; 190 int board, i, status; 191 192 board = probe->pr_board; 193 194 hdrp = probe->pr_hdr; 195 statp = probe->pr_sb_status; 196 dinfop = probe->pr_dinfo; 197 sbp = probe->pr_sb; 198 199 printf("HWD: board %d\n", board); 200 printf("HWD:magic = 0x%x\n", hdrp->hdr_magic); 201 printf("HWD:version = 0x%x.%x\n", hdrp->hdr_version.major, 202 hdrp->hdr_version.minor); 203 204 if (hwddump_flags & HWDDUMP_OFFSETS) { 205 printf("HWD:status offset = 0x%x\n", 206 hdrp->hdr_sb_status_offset); 207 printf("HWD:domain offset = 0x%x\n", 208 hdrp->hdr_domain_info_offset); 209 printf("HWD:board offset = 0x%x\n", hdrp->hdr_sb_info_offset); 210 } 211 212 if (hwddump_flags & HWDDUMP_SBP) 213 printf("HWD:sb_t ptr = 0x%p\n", (void *)probe->pr_sb); 214 215 if (hwddump_flags & HWDDUMP_ALL_STATUS) { 216 int bd; 217 printf("HWD:board status ="); 218 for (bd = 0; bd < HWD_SBS_PER_DOMAIN; bd++) 219 printf("%x ", statp->sb_status[bd]); 220 printf("\n"); 221 } else { 222 printf("HWD:board status = %d\n", statp->sb_status[board]); 223 } 224 225 printf("HWD:banner name = %s\n", dinfop->dinf_banner_name); 226 printf("HWD:platform = %s\n", dinfop->dinf_platform_token); 227 228 printf("HWD:chip status:\n"); 229 chips = &sbp->sb_cmu.cmu_cpu_chips[0]; 230 for (i = 0; i < HWD_CPU_CHIPS_PER_CMU; i++) { 231 232 status = chips[i].chip_status; 233 printf("chip[%d] = ", i); 234 if (HWD_STATUS_NONE(status)) 235 printf("none"); 236 else if (HWD_STATUS_FAILED(status)) 237 printf("fail"); 238 else if (HWD_STATUS_OK(status)) 239 printf("ok"); 240 printf("\n"); 241 } 242 243 if (hwddump_flags & HWDDUMP_CHUNKS) { 244 int chunk; 245 hwd_memory_t *mem = &sbp->sb_cmu.cmu_memory; 246 printf("HWD:chunks:\n"); 247 for (chunk = 0; chunk < HWD_MAX_MEM_CHUNKS; chunk++) 248 printf("\t%d 0x%lx 0x%lx\n", chunk, 249 mem->mem_chunks[chunk].chnk_start_address, 250 mem->mem_chunks[chunk].chnk_size); 251 } 252 253 printf("HWD:channel status:\n"); 254 channels = &sbp->sb_pci_ch[0]; 255 for (i = 0; i < HWD_PCI_CHANNELS_PER_SB; i++) { 256 257 status = channels[i].pci_status; 258 printf("channels[%d] = ", i); 259 if (HWD_STATUS_NONE(status)) 260 printf("none"); 261 else if (HWD_STATUS_FAILED(status)) 262 printf("fail"); 263 else if (HWD_STATUS_OK(status)) 264 printf("ok"); 265 printf("\n"); 266 } 267 printf("channels[%d] = ", i); 268 status = sbp->sb_cmu.cmu_ch.chan_status; 269 if (HWD_STATUS_NONE(status)) 270 printf("none"); 271 else if (HWD_STATUS_FAILED(status)) 272 printf("fail"); 273 else if (HWD_STATUS_OK(status)) 274 printf("ok"); 275 printf("\n"); 276 } 277 #endif /* DEBUG */ 278 279 #ifdef UCTEST 280 /* 281 * For SesamI debugging, just map the SRAM directly to a kernel 282 * VA and read it out from there 283 */ 284 285 #include <sys/vmem.h> 286 #include <vm/seg_kmem.h> 287 288 /* 289 * 0x4081F1323000LL is the HWD base address for LSB 0. But we need to map 290 * at page boundaries. So, we use a base address of 0x4081F1322000LL. 291 * Note that this has to match the HWD base pa set in .sesami-common-defs. 292 * 293 * The size specified for the HWD in the SCF spec is 36K. But since 294 * we adjusted the base address by 4K, we need to use 40K for the 295 * mapping size to cover the HWD. And 40K is also a multiple of the 296 * base page size. 297 */ 298 #define OPL_HWD_BASE(lsb) \ 299 (0x4081F1322000LL | (((uint64_t)(lsb)) << 40)) 300 301 void *opl_hwd_vaddr; 302 #endif /* UCTEST */ 303 304 /* 305 * Get the hardware descriptor from SCF. 306 */ 307 308 /*ARGSUSED*/ 309 int 310 opl_read_hwd(int board, hwd_header_t **hdrp, hwd_sb_status_t **statp, 311 hwd_domain_info_t **dinfop, hwd_sb_t **sbp) 312 { 313 static int (*getinfop)(uint32_t, uint8_t, uint32_t, uint32_t *, 314 void *) = NULL; 315 void *hwdp; 316 317 uint32_t key = KEY_ESCF; /* required value */ 318 uint8_t type = 0x40; /* SUB_OS_RECEIVE_HWD */ 319 uint32_t transid = board; 320 uint32_t datasize = HWD_DATA_SIZE; 321 322 hwd_header_t *hd; 323 hwd_sb_status_t *st; 324 hwd_domain_info_t *di; 325 hwd_sb_t *sb; 326 327 int ret; 328 329 if (opl_boards[board].cfg_hwd == NULL) { 330 #ifdef UCTEST 331 /* 332 * Just map the HWD in SRAM to a kernel VA 333 */ 334 335 size_t size; 336 pfn_t pfn; 337 338 size = 0xA000; 339 340 opl_hwd_vaddr = vmem_alloc(heap_arena, size, VM_SLEEP); 341 if (opl_hwd_vaddr == NULL) { 342 cmn_err(CE_NOTE, "No space for HWD"); 343 return (-1); 344 } 345 346 pfn = btop(OPL_HWD_BASE(board)); 347 hat_devload(kas.a_hat, opl_hwd_vaddr, size, pfn, PROT_READ, 348 HAT_LOAD_NOCONSIST | HAT_LOAD_LOCK); 349 350 hwdp = (void *)((char *)opl_hwd_vaddr + 0x1000); 351 opl_boards[board].cfg_hwd = hwdp; 352 ret = 0; 353 #else 354 355 /* find the scf_service_getinfo() function */ 356 if (getinfop == NULL) 357 getinfop = (int (*)(uint32_t, uint8_t, uint32_t, 358 uint32_t *, 359 void *))modgetsymvalue("scf_service_getinfo", 0); 360 361 if (getinfop == NULL) 362 return (-1); 363 364 /* allocate memory to receive the data */ 365 hwdp = kmem_alloc(HWD_DATA_SIZE, KM_SLEEP); 366 367 /* get the HWD */ 368 ret = (*getinfop)(key, type, transid, &datasize, hwdp); 369 if (ret == 0) 370 opl_boards[board].cfg_hwd = hwdp; 371 else 372 kmem_free(hwdp, HWD_DATA_SIZE); 373 #endif 374 } else { 375 hwdp = opl_boards[board].cfg_hwd; 376 ret = 0; 377 } 378 379 /* copy the data to the destination */ 380 if (ret == 0) { 381 hd = (hwd_header_t *)hwdp; 382 st = (hwd_sb_status_t *) 383 ((char *)hwdp + hd->hdr_sb_status_offset); 384 di = (hwd_domain_info_t *) 385 ((char *)hwdp + hd->hdr_domain_info_offset); 386 sb = (hwd_sb_t *) 387 ((char *)hwdp + hd->hdr_sb_info_offset); 388 if (hdrp != NULL) 389 *hdrp = hd; 390 if (statp != NULL) 391 *statp = st; 392 if (dinfop != NULL) 393 *dinfop = di; 394 if (sbp != NULL) 395 *sbp = sb; 396 } 397 398 return (ret); 399 } 400 401 /* 402 * The opl_probe_t probe structure is used to pass all sorts of parameters 403 * to callback functions during probing. It also contains a snapshot of 404 * the hardware descriptor that is taken at the beginning of a probe. 405 */ 406 static int 407 opl_probe_init(opl_probe_t *probe) 408 { 409 hwd_header_t **hdrp; 410 hwd_sb_status_t **statp; 411 hwd_domain_info_t **dinfop; 412 hwd_sb_t **sbp; 413 int board, ret; 414 415 board = probe->pr_board; 416 417 hdrp = &probe->pr_hdr; 418 statp = &probe->pr_sb_status; 419 dinfop = &probe->pr_dinfo; 420 sbp = &probe->pr_sb; 421 422 /* 423 * Read the hardware descriptor. 424 */ 425 ret = opl_read_hwd(board, hdrp, statp, dinfop, sbp); 426 if (ret != 0) { 427 428 cmn_err(CE_WARN, "IKP: failed to read HWD header"); 429 return (-1); 430 } 431 432 #ifdef DEBUG 433 opl_dump_hwd(probe); 434 #endif 435 return (0); 436 } 437 438 /* 439 * This function is used to obtain pointers to relevant device nodes 440 * which are created by Solaris at boot time. 441 * 442 * This function walks the child nodes of a given node, extracts 443 * the "name" property, if it exists, and passes the node to a 444 * callback init function. The callback determines if this node is 445 * interesting or not. If it is, then a pointer to the node is 446 * stored away by the callback for use during unprobe. 447 * 448 * The DDI get property function allocates storage for the name 449 * property. That needs to be freed within this function. 450 */ 451 static int 452 opl_init_nodes(dev_info_t *parent, opl_init_func_t init) 453 { 454 dev_info_t *node; 455 char *name; 456 int circ, ret; 457 int len; 458 459 ASSERT(parent != NULL); 460 461 /* 462 * Hold parent node busy to walk its child list 463 */ 464 ndi_devi_enter(parent, &circ); 465 node = ddi_get_child(parent); 466 467 while (node != NULL) { 468 469 ret = OPL_GET_PROP(string, node, "name", &name, &len); 470 if (ret != DDI_PROP_SUCCESS) { 471 /* 472 * The property does not exist for this node. 473 */ 474 node = ddi_get_next_sibling(node); 475 continue; 476 } 477 478 ret = init(node, name, len); 479 kmem_free(name, len); 480 if (ret != 0) { 481 482 ndi_devi_exit(parent, circ); 483 return (-1); 484 } 485 486 node = ddi_get_next_sibling(node); 487 } 488 489 ndi_devi_exit(parent, circ); 490 491 return (0); 492 } 493 494 /* 495 * This init function finds all the interesting nodes under the 496 * root node and stores pointers to them. The following nodes 497 * are considered interesting by this implementation: 498 * 499 * "cmp" 500 * These are nodes that represent processor chips. 501 * 502 * "pci" 503 * These are nodes that represent PCI leaves. 504 * 505 * "pseudo-mc" 506 * These are nodes that contain memory information. 507 */ 508 static int 509 opl_init_root_nodes(dev_info_t *node, char *name, int len) 510 { 511 int portid, board, chip, channel, leaf; 512 int ret; 513 514 if (strncmp(name, OPL_CPU_CHIP_NODE, len) == 0) { 515 516 ret = OPL_GET_PROP(int, node, "portid", &portid, -1); 517 if (ret != DDI_PROP_SUCCESS) 518 return (-1); 519 520 ret = OPL_GET_PROP(int, node, "board#", &board, -1); 521 if (ret != DDI_PROP_SUCCESS) 522 return (-1); 523 524 chip = OPL_CPU_CHIP(portid); 525 opl_boards[board].cfg_cpu_chips[chip] = node; 526 527 } else if (strncmp(name, OPL_PCI_LEAF_NODE, len) == 0) { 528 529 ret = OPL_GET_PROP(int, node, "portid", &portid, -1); 530 if (ret != DDI_PROP_SUCCESS) 531 return (-1); 532 533 board = OPL_IO_PORTID_TO_LSB(portid); 534 channel = OPL_PORTID_TO_CHANNEL(portid); 535 536 if (channel == OPL_CMU_CHANNEL) { 537 538 opl_boards[board].cfg_cmuch_leaf = node; 539 540 } else { 541 542 leaf = OPL_PORTID_TO_LEAF(portid); 543 opl_boards[board].cfg_pcich_leaf[channel][leaf] = node; 544 } 545 } else if (strncmp(name, OPL_PSEUDO_MC_NODE, len) == 0) { 546 547 ret = OPL_GET_PROP(int, node, "board#", &board, -1); 548 if (ret != DDI_PROP_SUCCESS) 549 return (-1); 550 551 ASSERT((board >= 0) && (board < HWD_SBS_PER_DOMAIN)); 552 553 opl_boards[board].cfg_pseudo_mc = node; 554 } 555 556 return (0); 557 } 558 559 /* 560 * This function initializes the OPL IKP feature. Currently, all it does 561 * is find the interesting nodes that Solaris has created at boot time 562 * for boards present at boot time and store pointers to them. This 563 * is useful if those boards are unprobed by DR. 564 */ 565 int 566 opl_init_cfg() 567 { 568 dev_info_t *root; 569 570 if (opl_cfg_inited == 0) { 571 572 root = ddi_root_node(); 573 if ((opl_init_nodes(root, opl_init_root_nodes) != 0)) { 574 cmn_err(CE_WARN, "IKP: init failed"); 575 return (1); 576 } 577 578 opl_cfg_inited = 1; 579 } 580 581 return (0); 582 } 583 584 /* 585 * When DR is initialized, we walk the device tree and acquire a hold on 586 * all the nodes that are interesting to IKP. This is so that the corresponding 587 * branches cannot be deleted. 588 * 589 * The following function informs the walk about which nodes are interesting 590 * so that it can hold the corresponding branches. 591 */ 592 static int 593 opl_hold_node(char *name) 594 { 595 /* 596 * We only need to hold/release the following nodes which 597 * represent separate branches that must be managed. 598 */ 599 return ((strcmp(name, OPL_CPU_CHIP_NODE) == 0) || 600 (strcmp(name, OPL_PSEUDO_MC_NODE) == 0) || 601 (strcmp(name, OPL_PCI_LEAF_NODE) == 0)); 602 } 603 604 static int 605 opl_hold_rele_devtree(dev_info_t *rdip, void *arg) 606 { 607 608 int *holdp = (int *)arg; 609 char *name = ddi_node_name(rdip); 610 611 /* 612 * We only need to hold/release the following nodes which 613 * represent separate branches that must be managed. 614 */ 615 if (opl_hold_node(name) == 0) { 616 /* Not of interest to us */ 617 return (DDI_WALK_PRUNECHILD); 618 } 619 if (*holdp) { 620 ASSERT(!e_ddi_branch_held(rdip)); 621 e_ddi_branch_hold(rdip); 622 } else { 623 ASSERT(e_ddi_branch_held(rdip)); 624 e_ddi_branch_rele(rdip); 625 } 626 627 return (DDI_WALK_PRUNECHILD); 628 } 629 630 void 631 opl_hold_devtree() 632 { 633 dev_info_t *dip; 634 int circ; 635 int hold = 1; 636 637 dip = ddi_root_node(); 638 ndi_devi_enter(dip, &circ); 639 ddi_walk_devs(ddi_get_child(dip), opl_hold_rele_devtree, &hold); 640 ndi_devi_exit(dip, circ); 641 } 642 643 void 644 opl_release_devtree() 645 { 646 dev_info_t *dip; 647 int circ; 648 int hold = 0; 649 650 dip = ddi_root_node(); 651 ndi_devi_enter(dip, &circ); 652 ddi_walk_devs(ddi_get_child(dip), opl_hold_rele_devtree, &hold); 653 ndi_devi_exit(dip, circ); 654 } 655 656 /* 657 * This is a helper function that allows opl_create_node() to return a 658 * pointer to a newly created node to its caller. 659 */ 660 /*ARGSUSED*/ 661 static void 662 opl_set_node(dev_info_t *node, void *arg, uint_t flags) 663 { 664 opl_probe_t *probe; 665 666 probe = arg; 667 probe->pr_node = node; 668 } 669 670 /* 671 * Function to create a node in the device tree under a specified parent. 672 * 673 * e_ddi_branch_create() allows the creation of a whole branch with a 674 * single call of the function. However, we only use it to create one node 675 * at a time in the case of non-I/O device nodes. In other words, we 676 * create branches by repeatedly using this function. This makes the 677 * code more readable. 678 * 679 * The branch descriptor passed to e_ddi_branch_create() takes two 680 * callbacks. The create() callback is used to set the properties of a 681 * newly created node. The other callback is used to return a pointer 682 * to the newly created node. The create() callback is passed by the 683 * caller of this function based on the kind of node he wishes to 684 * create. 685 * 686 * e_ddi_branch_create() returns with the newly created node held. We 687 * only need to hold the top nodes of the branches we create. We release 688 * the hold for the others. E.g., the "cmp" node needs to be held. Since 689 * we hold the "cmp" node, there is no need to hold the "core" and "cpu" 690 * nodes below it. 691 */ 692 static dev_info_t * 693 opl_create_node(opl_probe_t *probe) 694 { 695 devi_branch_t branch; 696 697 probe->pr_node = NULL; 698 699 branch.arg = probe; 700 branch.type = DEVI_BRANCH_SID; 701 branch.create.sid_branch_create = probe->pr_create; 702 branch.devi_branch_callback = opl_set_node; 703 704 if (e_ddi_branch_create(probe->pr_parent, &branch, NULL, 0) != 0) 705 return (NULL); 706 707 ASSERT(probe->pr_node != NULL); 708 709 if (probe->pr_hold == 0) 710 e_ddi_branch_rele(probe->pr_node); 711 712 return (probe->pr_node); 713 } 714 715 /* 716 * Function to tear down a whole branch rooted at the specified node. 717 * 718 * Although we create each node of a branch individually, we destroy 719 * a whole branch in one call. This is more efficient. 720 */ 721 static int 722 opl_destroy_node(dev_info_t *node) 723 { 724 if (e_ddi_branch_destroy(node, NULL, 0) != 0) { 725 char *path = kmem_alloc(MAXPATHLEN, KM_SLEEP); 726 (void) ddi_pathname(node, path); 727 cmn_err(CE_WARN, "OPL node removal failed: %s (%p)", 728 path, (void *)node); 729 kmem_free(path, MAXPATHLEN); 730 return (-1); 731 } 732 733 return (0); 734 } 735 736 /* 737 * Set the properties for a "cpu" node. 738 */ 739 /*ARGSUSED*/ 740 static int 741 opl_create_cpu(dev_info_t *node, void *arg, uint_t flags) 742 { 743 opl_probe_t *probe; 744 hwd_cpu_chip_t *chip; 745 hwd_core_t *core; 746 hwd_cpu_t *cpu; 747 int ret; 748 749 probe = arg; 750 chip = &probe->pr_sb->sb_cmu.cmu_cpu_chips[probe->pr_cpu_chip]; 751 core = &chip->chip_cores[probe->pr_core]; 752 cpu = &core->core_cpus[probe->pr_cpu]; 753 OPL_UPDATE_PROP(string, node, "name", OPL_CPU_NODE); 754 OPL_UPDATE_PROP(string, node, "device_type", OPL_CPU_NODE); 755 756 OPL_UPDATE_PROP(int, node, "cpuid", cpu->cpu_cpuid); 757 OPL_UPDATE_PROP(int, node, "reg", probe->pr_cpu); 758 759 OPL_UPDATE_PROP(string, node, "status", "okay"); 760 761 return (DDI_WALK_TERMINATE); 762 } 763 764 /* 765 * Create "cpu" nodes as child nodes of a given "core" node. 766 */ 767 static int 768 opl_probe_cpus(opl_probe_t *probe) 769 { 770 int i; 771 hwd_cpu_chip_t *chip; 772 hwd_core_t *core; 773 hwd_cpu_t *cpus; 774 775 chip = &probe->pr_sb->sb_cmu.cmu_cpu_chips[probe->pr_cpu_chip]; 776 core = &chip->chip_cores[probe->pr_core]; 777 cpus = &core->core_cpus[0]; 778 779 for (i = 0; i < HWD_CPUS_PER_CORE; i++) { 780 781 /* 782 * Olympus-C has 2 cpus per core. 783 * Jupiter has 4 cpus per core. 784 * For the Olympus-C based platform, we expect the cpu_status 785 * of the non-existent cpus to be set to missing. 786 */ 787 if (!HWD_STATUS_OK(cpus[i].cpu_status)) 788 continue; 789 790 probe->pr_create = opl_create_cpu; 791 probe->pr_cpu = i; 792 if (opl_create_node(probe) == NULL) { 793 794 cmn_err(CE_WARN, "IKP: create cpu (%d-%d-%d-%d) failed", 795 probe->pr_board, probe->pr_cpu_chip, 796 probe->pr_core, probe->pr_cpu); 797 return (-1); 798 } 799 } 800 801 return (0); 802 } 803 804 /* 805 * Set the properties for a "core" node. 806 */ 807 /*ARGSUSED*/ 808 static int 809 opl_create_core(dev_info_t *node, void *arg, uint_t flags) 810 { 811 opl_probe_t *probe; 812 hwd_cpu_chip_t *chip; 813 hwd_core_t *core; 814 int sharing[2]; 815 int ret; 816 817 probe = arg; 818 chip = &probe->pr_sb->sb_cmu.cmu_cpu_chips[probe->pr_cpu_chip]; 819 core = &chip->chip_cores[probe->pr_core]; 820 821 OPL_UPDATE_PROP(string, node, "name", OPL_CORE_NODE); 822 OPL_UPDATE_PROP(string, node, "device_type", OPL_CORE_NODE); 823 OPL_UPDATE_PROP(string, node, "compatible", chip->chip_compatible); 824 825 OPL_UPDATE_PROP(int, node, "reg", probe->pr_core); 826 OPL_UPDATE_PROP(int, node, "manufacturer#", core->core_manufacturer); 827 OPL_UPDATE_PROP(int, node, "implementation#", 828 core->core_implementation); 829 OPL_UPDATE_PROP(int, node, "mask#", core->core_mask); 830 831 OPL_UPDATE_PROP(int, node, "sparc-version", core->core_version); 832 OPL_UPDATE_PROP(int, node, "clock-frequency", core->core_frequency); 833 834 OPL_UPDATE_PROP(int, node, "l1-icache-size", core->core_l1_icache_size); 835 OPL_UPDATE_PROP(int, node, "l1-icache-line-size", 836 core->core_l1_icache_line_size); 837 OPL_UPDATE_PROP(int, node, "l1-icache-associativity", 838 core->core_l1_icache_associativity); 839 OPL_UPDATE_PROP(int, node, "#itlb-entries", 840 core->core_num_itlb_entries); 841 842 OPL_UPDATE_PROP(int, node, "l1-dcache-size", core->core_l1_dcache_size); 843 OPL_UPDATE_PROP(int, node, "l1-dcache-line-size", 844 core->core_l1_dcache_line_size); 845 OPL_UPDATE_PROP(int, node, "l1-dcache-associativity", 846 core->core_l1_dcache_associativity); 847 OPL_UPDATE_PROP(int, node, "#dtlb-entries", 848 core->core_num_dtlb_entries); 849 850 OPL_UPDATE_PROP(int, node, "l2-cache-size", core->core_l2_cache_size); 851 OPL_UPDATE_PROP(int, node, "l2-cache-line-size", 852 core->core_l2_cache_line_size); 853 OPL_UPDATE_PROP(int, node, "l2-cache-associativity", 854 core->core_l2_cache_associativity); 855 sharing[0] = 0; 856 sharing[1] = core->core_l2_cache_sharing; 857 OPL_UPDATE_PROP_ARRAY(int, node, "l2-cache-sharing", sharing, 2); 858 859 OPL_UPDATE_PROP(string, node, "status", "okay"); 860 861 return (DDI_WALK_TERMINATE); 862 } 863 864 /* 865 * Create "core" nodes as child nodes of a given "cmp" node. 866 * 867 * Create the branch below each "core" node". 868 */ 869 static int 870 opl_probe_cores(opl_probe_t *probe) 871 { 872 int i; 873 hwd_cpu_chip_t *chip; 874 hwd_core_t *cores; 875 dev_info_t *parent, *node; 876 877 chip = &probe->pr_sb->sb_cmu.cmu_cpu_chips[probe->pr_cpu_chip]; 878 cores = &chip->chip_cores[0]; 879 parent = probe->pr_parent; 880 881 for (i = 0; i < HWD_CORES_PER_CPU_CHIP; i++) { 882 883 if (!HWD_STATUS_OK(cores[i].core_status)) 884 continue; 885 886 probe->pr_parent = parent; 887 probe->pr_create = opl_create_core; 888 probe->pr_core = i; 889 node = opl_create_node(probe); 890 if (node == NULL) { 891 892 cmn_err(CE_WARN, "IKP: create core (%d-%d-%d) failed", 893 probe->pr_board, probe->pr_cpu_chip, 894 probe->pr_core); 895 return (-1); 896 } 897 898 /* 899 * Create "cpu" nodes below "core". 900 */ 901 probe->pr_parent = node; 902 if (opl_probe_cpus(probe) != 0) 903 return (-1); 904 } 905 906 return (0); 907 } 908 909 /* 910 * Set the properties for a "cmp" node. 911 */ 912 /*ARGSUSED*/ 913 static int 914 opl_create_cpu_chip(dev_info_t *node, void *arg, uint_t flags) 915 { 916 opl_probe_t *probe; 917 hwd_cpu_chip_t *chip; 918 opl_range_t range; 919 uint64_t dummy_addr; 920 int ret; 921 922 probe = arg; 923 chip = &probe->pr_sb->sb_cmu.cmu_cpu_chips[probe->pr_cpu_chip]; 924 925 OPL_UPDATE_PROP(string, node, "name", OPL_CPU_CHIP_NODE); 926 927 OPL_UPDATE_PROP(int, node, "portid", chip->chip_portid); 928 OPL_UPDATE_PROP(int, node, "board#", probe->pr_board); 929 930 dummy_addr = OPL_PROC_AS(probe->pr_board, probe->pr_cpu_chip); 931 range.rg_addr_hi = OPL_HI(dummy_addr); 932 range.rg_addr_lo = OPL_LO(dummy_addr); 933 range.rg_size_hi = 0; 934 range.rg_size_lo = 0; 935 OPL_UPDATE_PROP_ARRAY(int, node, "reg", (int *)&range, 4); 936 937 OPL_UPDATE_PROP(int, node, "#address-cells", 1); 938 OPL_UPDATE_PROP(int, node, "#size-cells", 0); 939 940 OPL_UPDATE_PROP(string, node, "status", "okay"); 941 942 return (DDI_WALK_TERMINATE); 943 } 944 945 /* 946 * Create "cmp" nodes as child nodes of the root node. 947 * 948 * Create the branch below each "cmp" node. 949 */ 950 static int 951 opl_probe_cpu_chips(opl_probe_t *probe) 952 { 953 int i; 954 dev_info_t **cfg_cpu_chips; 955 hwd_cpu_chip_t *chips; 956 dev_info_t *node; 957 958 cfg_cpu_chips = opl_boards[probe->pr_board].cfg_cpu_chips; 959 chips = &probe->pr_sb->sb_cmu.cmu_cpu_chips[0]; 960 961 for (i = 0; i < HWD_CPU_CHIPS_PER_CMU; i++) { 962 963 ASSERT(cfg_cpu_chips[i] == NULL); 964 965 if (!HWD_STATUS_OK(chips[i].chip_status)) 966 continue; 967 968 probe->pr_parent = ddi_root_node(); 969 probe->pr_create = opl_create_cpu_chip; 970 probe->pr_cpu_chip = i; 971 probe->pr_hold = 1; 972 node = opl_create_node(probe); 973 if (node == NULL) { 974 975 cmn_err(CE_WARN, "IKP: create chip (%d-%d) failed", 976 probe->pr_board, probe->pr_cpu_chip); 977 return (-1); 978 } 979 980 cfg_cpu_chips[i] = node; 981 982 /* 983 * Create "core" nodes below "cmp". 984 * We hold the "cmp" node. So, there is no need to hold 985 * the "core" and "cpu" nodes below it. 986 */ 987 probe->pr_parent = node; 988 probe->pr_hold = 0; 989 if (opl_probe_cores(probe) != 0) 990 return (-1); 991 } 992 993 return (0); 994 } 995 996 /* 997 * Set the properties for a "pseudo-mc" node. 998 */ 999 /*ARGSUSED*/ 1000 static int 1001 opl_create_pseudo_mc(dev_info_t *node, void *arg, uint_t flags) 1002 { 1003 opl_probe_t *probe; 1004 int board, portid; 1005 hwd_bank_t *bank; 1006 hwd_memory_t *mem; 1007 opl_range_t range; 1008 opl_mc_addr_t mc[HWD_BANKS_PER_CMU]; 1009 int status[2][7]; 1010 int i, j; 1011 int ret; 1012 1013 probe = arg; 1014 board = probe->pr_board; 1015 1016 OPL_UPDATE_PROP(string, node, "name", OPL_PSEUDO_MC_NODE); 1017 OPL_UPDATE_PROP(string, node, "device_type", "memory-controller"); 1018 OPL_UPDATE_PROP(string, node, "compatible", "FJSV,oplmc"); 1019 1020 portid = OPL_LSB_TO_PSEUDOMC_PORTID(board); 1021 OPL_UPDATE_PROP(int, node, "portid", portid); 1022 1023 range.rg_addr_hi = OPL_HI(OPL_MC_AS(board)); 1024 range.rg_addr_lo = 0x200; 1025 range.rg_size_hi = 0; 1026 range.rg_size_lo = 0; 1027 OPL_UPDATE_PROP_ARRAY(int, node, "reg", (int *)&range, 4); 1028 1029 OPL_UPDATE_PROP(int, node, "board#", board); 1030 OPL_UPDATE_PROP(int, node, "physical-board#", 1031 probe->pr_sb->sb_psb_number); 1032 1033 OPL_UPDATE_PROP(int, node, "#address-cells", 1); 1034 OPL_UPDATE_PROP(int, node, "#size-cells", 2); 1035 1036 mem = &probe->pr_sb->sb_cmu.cmu_memory; 1037 1038 range.rg_addr_hi = OPL_HI(mem->mem_start_address); 1039 range.rg_addr_lo = OPL_LO(mem->mem_start_address); 1040 range.rg_size_hi = OPL_HI(mem->mem_size); 1041 range.rg_size_lo = OPL_LO(mem->mem_size); 1042 OPL_UPDATE_PROP_ARRAY(int, node, "sb-mem-ranges", (int *)&range, 4); 1043 1044 bank = probe->pr_sb->sb_cmu.cmu_memory.mem_banks; 1045 for (i = 0, j = 0; i < HWD_BANKS_PER_CMU; i++) { 1046 1047 if (!HWD_STATUS_OK(bank[i].bank_status)) 1048 continue; 1049 1050 mc[j].mc_bank = i; 1051 mc[j].mc_hi = OPL_HI(bank[i].bank_register_address); 1052 mc[j].mc_lo = OPL_LO(bank[i].bank_register_address); 1053 j++; 1054 } 1055 1056 if (j > 0) { 1057 OPL_UPDATE_PROP_ARRAY(int, node, "mc-addr", (int *)mc, j*3); 1058 } else { 1059 /* 1060 * If there is no memory, we need the mc-addr property, but 1061 * it is length 0. The only way to do this using ndi seems 1062 * to be by creating a boolean property. 1063 */ 1064 ret = ndi_prop_create_boolean(DDI_DEV_T_NONE, node, "mc-addr"); 1065 OPL_UPDATE_PROP_ERR(ret, "mc-addr"); 1066 } 1067 1068 OPL_UPDATE_PROP_ARRAY(byte, node, "cs0-mc-pa-trans-table", 1069 mem->mem_cs[0].cs_pa_mac_table, 64); 1070 OPL_UPDATE_PROP_ARRAY(byte, node, "cs1-mc-pa-trans-table", 1071 mem->mem_cs[1].cs_pa_mac_table, 64); 1072 1073 #define CS_PER_MEM 2 1074 1075 for (i = 0, j = 0; i < CS_PER_MEM; i++) { 1076 if (HWD_STATUS_OK(mem->mem_cs[i].cs_status) || 1077 HWD_STATUS_FAILED(mem->mem_cs[i].cs_status)) { 1078 status[j][0] = i; 1079 if (HWD_STATUS_OK(mem->mem_cs[i].cs_status)) 1080 status[j][1] = 0; 1081 else 1082 status[j][1] = 1; 1083 status[j][2] = 1084 OPL_HI(mem->mem_cs[i].cs_available_capacity); 1085 status[j][3] = 1086 OPL_LO(mem->mem_cs[i].cs_available_capacity); 1087 status[j][4] = OPL_HI(mem->mem_cs[i].cs_dimm_capacity); 1088 status[j][5] = OPL_LO(mem->mem_cs[i].cs_dimm_capacity); 1089 status[j][6] = mem->mem_cs[i].cs_number_of_dimms; 1090 j++; 1091 } 1092 } 1093 1094 if (j > 0) { 1095 OPL_UPDATE_PROP_ARRAY(int, node, "cs-status", (int *)status, 1096 j*7); 1097 } else { 1098 /* 1099 * If there is no memory, we need the cs-status property, but 1100 * it is length 0. The only way to do this using ndi seems 1101 * to be by creating a boolean property. 1102 */ 1103 ret = ndi_prop_create_boolean(DDI_DEV_T_NONE, node, 1104 "cs-status"); 1105 OPL_UPDATE_PROP_ERR(ret, "cs-status"); 1106 } 1107 1108 return (DDI_WALK_TERMINATE); 1109 } 1110 1111 /* 1112 * Create "pseudo-mc" nodes 1113 */ 1114 static int 1115 opl_probe_memory(opl_probe_t *probe) 1116 { 1117 int board; 1118 opl_board_cfg_t *board_cfg; 1119 dev_info_t *node; 1120 1121 board = probe->pr_board; 1122 board_cfg = &opl_boards[board]; 1123 1124 ASSERT(board_cfg->cfg_pseudo_mc == NULL); 1125 1126 probe->pr_parent = ddi_root_node(); 1127 probe->pr_create = opl_create_pseudo_mc; 1128 probe->pr_hold = 1; 1129 node = opl_create_node(probe); 1130 if (node == NULL) { 1131 1132 cmn_err(CE_WARN, "IKP: create pseudo-mc (%d) failed", board); 1133 return (-1); 1134 } 1135 1136 board_cfg->cfg_pseudo_mc = node; 1137 1138 return (0); 1139 } 1140 1141 /* 1142 * Allocate the fcode ops handle. 1143 */ 1144 /*ARGSUSED*/ 1145 static 1146 fco_handle_t 1147 opl_fc_ops_alloc_handle(dev_info_t *parent, dev_info_t *child, 1148 void *fcode, size_t fcode_size, char *unit_address, 1149 char *my_args) 1150 { 1151 fco_handle_t rp; 1152 phandle_t h; 1153 char *buf; 1154 1155 rp = kmem_zalloc(sizeof (struct fc_resource_list), KM_SLEEP); 1156 rp->next_handle = fc_ops_alloc_handle(parent, child, fcode, fcode_size, 1157 unit_address, NULL); 1158 rp->ap = parent; 1159 rp->child = child; 1160 rp->fcode = fcode; 1161 rp->fcode_size = fcode_size; 1162 rp->my_args = my_args; 1163 1164 if (unit_address) { 1165 buf = kmem_zalloc(UNIT_ADDR_SIZE, KM_SLEEP); 1166 (void) strcpy(buf, unit_address); 1167 rp->unit_address = buf; 1168 } 1169 1170 /* 1171 * Add the child's nodeid to our table... 1172 */ 1173 h = ddi_get_nodeid(rp->child); 1174 fc_add_dip_to_phandle(fc_handle_to_phandle_head(rp), rp->child, h); 1175 1176 return (rp); 1177 } 1178 1179 1180 static void 1181 opl_fc_ops_free_handle(fco_handle_t rp) 1182 { 1183 struct fc_resource *resp, *nresp; 1184 1185 ASSERT(rp); 1186 1187 if (rp->next_handle) 1188 fc_ops_free_handle(rp->next_handle); 1189 if (rp->unit_address) 1190 kmem_free(rp->unit_address, UNIT_ADDR_SIZE); 1191 1192 /* 1193 * Release all the resources from the resource list 1194 */ 1195 for (resp = rp->head; resp != NULL; resp = nresp) { 1196 nresp = resp->next; 1197 switch (resp->type) { 1198 1199 case RT_MAP: 1200 /* 1201 * If this is still mapped, we'd better unmap it now, 1202 * or all our structures that are tracking it will 1203 * be leaked. 1204 */ 1205 if (resp->fc_map_handle != NULL) 1206 opl_unmap_phys(&resp->fc_map_handle); 1207 break; 1208 1209 case RT_DMA: 1210 /* 1211 * DMA has to be freed up at exit time. 1212 */ 1213 cmn_err(CE_CONT, 1214 "opl_fc_ops_free_handle: Unexpected DMA seen!"); 1215 break; 1216 1217 case RT_CONTIGIOUS: 1218 FC_DEBUG2(1, CE_CONT, "opl_fc_ops_free: " 1219 "Free claim-memory resource 0x%lx size 0x%x\n", 1220 resp->fc_contig_virt, resp->fc_contig_len); 1221 1222 (void) ndi_ra_free(ddi_root_node(), 1223 (uint64_t)resp->fc_contig_virt, 1224 resp->fc_contig_len, "opl-fcodemem", 1225 NDI_RA_PASS); 1226 1227 break; 1228 1229 default: 1230 cmn_err(CE_CONT, "opl_fc_ops_free: " 1231 "unknown resource type %d", resp->type); 1232 break; 1233 } 1234 fc_rem_resource(rp, resp); 1235 kmem_free(resp, sizeof (struct fc_resource)); 1236 } 1237 1238 kmem_free(rp, sizeof (struct fc_resource_list)); 1239 } 1240 1241 int 1242 opl_fc_do_op(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1243 { 1244 opl_fc_ops_t *op; 1245 char *service = fc_cell2ptr(cp->svc_name); 1246 1247 ASSERT(rp); 1248 1249 FC_DEBUG1(1, CE_CONT, "opl_fc_do_op: <%s>\n", service); 1250 1251 /* 1252 * First try the generic fc_ops. 1253 */ 1254 if (fc_ops(ap, rp->next_handle, cp) == 0) 1255 return (0); 1256 1257 /* 1258 * Now try the Jupiter-specific ops. 1259 */ 1260 for (op = opl_fc_ops; op->fc_service != NULL; ++op) 1261 if (strcmp(op->fc_service, service) == 0) 1262 return (op->fc_op(ap, rp, cp)); 1263 1264 FC_DEBUG1(9, CE_CONT, "opl_fc_do_op: <%s> not serviced\n", service); 1265 1266 return (-1); 1267 } 1268 1269 /* 1270 * map-in (phys.lo phys.hi size -- virt) 1271 */ 1272 static int 1273 opl_map_in(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1274 { 1275 size_t len; 1276 int error; 1277 caddr_t virt; 1278 struct fc_resource *resp; 1279 struct regspec rspec; 1280 ddi_device_acc_attr_t acc; 1281 ddi_acc_handle_t h; 1282 1283 if (fc_cell2int(cp->nargs) != 3) 1284 return (fc_syntax_error(cp, "nargs must be 3")); 1285 1286 if (fc_cell2int(cp->nresults) < 1) 1287 return (fc_syntax_error(cp, "nresults must be >= 1")); 1288 1289 rspec.regspec_size = len = fc_cell2size(fc_arg(cp, 0)); 1290 rspec.regspec_bustype = fc_cell2uint(fc_arg(cp, 1)); 1291 rspec.regspec_addr = fc_cell2uint(fc_arg(cp, 2)); 1292 1293 acc.devacc_attr_version = DDI_DEVICE_ATTR_V0; 1294 acc.devacc_attr_endian_flags = DDI_STRUCTURE_BE_ACC; 1295 acc.devacc_attr_dataorder = DDI_STRICTORDER_ACC; 1296 1297 FC_DEBUG3(1, CE_CONT, "opl_map_in: attempting map in " 1298 "address 0x%08x.%08x length %x\n", rspec.regspec_bustype, 1299 rspec.regspec_addr, rspec.regspec_size); 1300 1301 error = opl_map_phys(rp->child, &rspec, &virt, &acc, &h); 1302 1303 if (error) { 1304 FC_DEBUG3(1, CE_CONT, "opl_map_in: map in failed - " 1305 "address 0x%08x.%08x length %x\n", rspec.regspec_bustype, 1306 rspec.regspec_addr, rspec.regspec_size); 1307 1308 return (fc_priv_error(cp, "opl map-in failed")); 1309 } 1310 1311 FC_DEBUG1(3, CE_CONT, "opl_map_in: returning virt %p\n", virt); 1312 1313 cp->nresults = fc_int2cell(1); 1314 fc_result(cp, 0) = fc_ptr2cell(virt); 1315 1316 /* 1317 * Log this resource ... 1318 */ 1319 resp = kmem_zalloc(sizeof (struct fc_resource), KM_SLEEP); 1320 resp->type = RT_MAP; 1321 resp->fc_map_virt = virt; 1322 resp->fc_map_len = len; 1323 resp->fc_map_handle = h; 1324 fc_add_resource(rp, resp); 1325 1326 return (fc_success_op(ap, rp, cp)); 1327 } 1328 1329 /* 1330 * map-out (virt size -- ) 1331 */ 1332 static int 1333 opl_map_out(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1334 { 1335 caddr_t virt; 1336 size_t len; 1337 struct fc_resource *resp; 1338 1339 if (fc_cell2int(cp->nargs) != 2) 1340 return (fc_syntax_error(cp, "nargs must be 2")); 1341 1342 virt = fc_cell2ptr(fc_arg(cp, 1)); 1343 1344 len = fc_cell2size(fc_arg(cp, 0)); 1345 1346 FC_DEBUG2(1, CE_CONT, "opl_map_out: attempting map out %p %x\n", 1347 virt, len); 1348 1349 /* 1350 * Find if this request matches a mapping resource we set up. 1351 */ 1352 fc_lock_resource_list(rp); 1353 for (resp = rp->head; resp != NULL; resp = resp->next) { 1354 if (resp->type != RT_MAP) 1355 continue; 1356 if (resp->fc_map_virt != virt) 1357 continue; 1358 if (resp->fc_map_len == len) 1359 break; 1360 } 1361 fc_unlock_resource_list(rp); 1362 1363 if (resp == NULL) 1364 return (fc_priv_error(cp, "request doesn't match a " 1365 "known mapping")); 1366 1367 opl_unmap_phys(&resp->fc_map_handle); 1368 1369 /* 1370 * remove the resource from the list and release it. 1371 */ 1372 fc_rem_resource(rp, resp); 1373 kmem_free(resp, sizeof (struct fc_resource)); 1374 1375 cp->nresults = fc_int2cell(0); 1376 return (fc_success_op(ap, rp, cp)); 1377 } 1378 1379 static int 1380 opl_register_fetch(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1381 { 1382 size_t len; 1383 caddr_t virt; 1384 int error = 0; 1385 uint64_t v; 1386 uint64_t x; 1387 uint32_t l; 1388 uint16_t w; 1389 uint8_t b; 1390 char *service = fc_cell2ptr(cp->svc_name); 1391 struct fc_resource *resp; 1392 1393 if (fc_cell2int(cp->nargs) != 1) 1394 return (fc_syntax_error(cp, "nargs must be 1")); 1395 1396 if (fc_cell2int(cp->nresults) < 1) 1397 return (fc_syntax_error(cp, "nresults must be >= 1")); 1398 1399 virt = fc_cell2ptr(fc_arg(cp, 0)); 1400 1401 /* 1402 * Determine the access width .. we can switch on the 2nd 1403 * character of the name which is "rx@", "rl@", "rb@" or "rw@" 1404 */ 1405 switch (*(service + 1)) { 1406 case 'x': len = sizeof (x); break; 1407 case 'l': len = sizeof (l); break; 1408 case 'w': len = sizeof (w); break; 1409 case 'b': len = sizeof (b); break; 1410 } 1411 1412 /* 1413 * Check the alignment ... 1414 */ 1415 if (((intptr_t)virt & (len - 1)) != 0) 1416 return (fc_priv_error(cp, "unaligned access")); 1417 1418 /* 1419 * Find if this virt is 'within' a request we know about 1420 */ 1421 fc_lock_resource_list(rp); 1422 for (resp = rp->head; resp != NULL; resp = resp->next) { 1423 if (resp->type == RT_MAP) { 1424 if ((virt >= (caddr_t)resp->fc_map_virt) && 1425 ((virt + len) <= 1426 ((caddr_t)resp->fc_map_virt + resp->fc_map_len))) 1427 break; 1428 } else if (resp->type == RT_CONTIGIOUS) { 1429 if ((virt >= (caddr_t)resp->fc_contig_virt) && ((virt + len) 1430 <= ((caddr_t)resp->fc_contig_virt + 1431 resp->fc_contig_len))) 1432 break; 1433 } 1434 } 1435 fc_unlock_resource_list(rp); 1436 1437 if (resp == NULL) { 1438 return (fc_priv_error(cp, "request not within " 1439 "known mappings")); 1440 } 1441 1442 switch (len) { 1443 case sizeof (x): 1444 if (resp->type == RT_MAP) 1445 error = ddi_peek64(rp->child, 1446 (int64_t *)virt, (int64_t *)&x); 1447 else /* RT_CONTIGIOUS */ 1448 x = *(int64_t *)virt; 1449 v = x; 1450 break; 1451 case sizeof (l): 1452 if (resp->type == RT_MAP) 1453 error = ddi_peek32(rp->child, 1454 (int32_t *)virt, (int32_t *)&l); 1455 else /* RT_CONTIGIOUS */ 1456 l = *(int32_t *)virt; 1457 v = l; 1458 break; 1459 case sizeof (w): 1460 if (resp->type == RT_MAP) 1461 error = ddi_peek16(rp->child, 1462 (int16_t *)virt, (int16_t *)&w); 1463 else /* RT_CONTIGIOUS */ 1464 w = *(int16_t *)virt; 1465 v = w; 1466 break; 1467 case sizeof (b): 1468 if (resp->type == RT_MAP) 1469 error = ddi_peek8(rp->child, 1470 (int8_t *)virt, (int8_t *)&b); 1471 else /* RT_CONTIGIOUS */ 1472 b = *(int8_t *)virt; 1473 v = b; 1474 break; 1475 } 1476 1477 if (error == DDI_FAILURE) { 1478 FC_DEBUG2(1, CE_CONT, "opl_register_fetch: access error " 1479 "accessing virt %p len %d\n", virt, len); 1480 return (fc_priv_error(cp, "access error")); 1481 } 1482 1483 FC_DEBUG3(1, CE_CONT, "register_fetch (%s) %llx %llx\n", 1484 service, virt, v); 1485 1486 cp->nresults = fc_int2cell(1); 1487 switch (len) { 1488 case sizeof (x): fc_result(cp, 0) = x; break; 1489 case sizeof (l): fc_result(cp, 0) = fc_uint32_t2cell(l); break; 1490 case sizeof (w): fc_result(cp, 0) = fc_uint16_t2cell(w); break; 1491 case sizeof (b): fc_result(cp, 0) = fc_uint8_t2cell(b); break; 1492 } 1493 return (fc_success_op(ap, rp, cp)); 1494 } 1495 1496 static int 1497 opl_register_store(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1498 { 1499 size_t len; 1500 caddr_t virt; 1501 uint64_t v; 1502 uint64_t x; 1503 uint32_t l; 1504 uint16_t w; 1505 uint8_t b; 1506 char *service = fc_cell2ptr(cp->svc_name); 1507 struct fc_resource *resp; 1508 int error = 0; 1509 1510 if (fc_cell2int(cp->nargs) != 2) 1511 return (fc_syntax_error(cp, "nargs must be 2")); 1512 1513 virt = fc_cell2ptr(fc_arg(cp, 0)); 1514 1515 /* 1516 * Determine the access width .. we can switch on the 2nd 1517 * character of the name which is "rx!", "rl!", "rb!" or "rw!" 1518 */ 1519 switch (*(service + 1)) { 1520 case 'x': 1521 len = sizeof (x); 1522 x = fc_arg(cp, 1); 1523 v = x; 1524 break; 1525 case 'l': 1526 len = sizeof (l); 1527 l = fc_cell2uint32_t(fc_arg(cp, 1)); 1528 v = l; 1529 break; 1530 case 'w': 1531 len = sizeof (w); 1532 w = fc_cell2uint16_t(fc_arg(cp, 1)); 1533 v = w; 1534 break; 1535 case 'b': 1536 len = sizeof (b); 1537 b = fc_cell2uint8_t(fc_arg(cp, 1)); 1538 v = b; 1539 break; 1540 } 1541 1542 FC_DEBUG3(1, CE_CONT, "register_store (%s) %llx %llx\n", 1543 service, virt, v); 1544 1545 /* 1546 * Check the alignment ... 1547 */ 1548 if (((intptr_t)virt & (len - 1)) != 0) 1549 return (fc_priv_error(cp, "unaligned access")); 1550 1551 /* 1552 * Find if this virt is 'within' a request we know about 1553 */ 1554 fc_lock_resource_list(rp); 1555 for (resp = rp->head; resp != NULL; resp = resp->next) { 1556 if (resp->type == RT_MAP) { 1557 if ((virt >= (caddr_t)resp->fc_map_virt) && 1558 ((virt + len) <= 1559 ((caddr_t)resp->fc_map_virt + resp->fc_map_len))) 1560 break; 1561 } else if (resp->type == RT_CONTIGIOUS) { 1562 if ((virt >= (caddr_t)resp->fc_contig_virt) && ((virt + len) 1563 <= ((caddr_t)resp->fc_contig_virt + 1564 resp->fc_contig_len))) 1565 break; 1566 } 1567 } 1568 fc_unlock_resource_list(rp); 1569 1570 if (resp == NULL) 1571 return (fc_priv_error(cp, "request not within" 1572 "known mappings")); 1573 1574 switch (len) { 1575 case sizeof (x): 1576 if (resp->type == RT_MAP) 1577 error = ddi_poke64(rp->child, (int64_t *)virt, x); 1578 else if (resp->type == RT_CONTIGIOUS) 1579 *(uint64_t *)virt = x; 1580 break; 1581 case sizeof (l): 1582 if (resp->type == RT_MAP) 1583 error = ddi_poke32(rp->child, (int32_t *)virt, l); 1584 else if (resp->type == RT_CONTIGIOUS) 1585 *(uint32_t *)virt = l; 1586 break; 1587 case sizeof (w): 1588 if (resp->type == RT_MAP) 1589 error = ddi_poke16(rp->child, (int16_t *)virt, w); 1590 else if (resp->type == RT_CONTIGIOUS) 1591 *(uint16_t *)virt = w; 1592 break; 1593 case sizeof (b): 1594 if (resp->type == RT_MAP) 1595 error = ddi_poke8(rp->child, (int8_t *)virt, b); 1596 else if (resp->type == RT_CONTIGIOUS) 1597 *(uint8_t *)virt = b; 1598 break; 1599 } 1600 1601 if (error == DDI_FAILURE) { 1602 FC_DEBUG2(1, CE_CONT, "opl_register_store: access error " 1603 "accessing virt %p len %d\n", virt, len); 1604 return (fc_priv_error(cp, "access error")); 1605 } 1606 1607 cp->nresults = fc_int2cell(0); 1608 return (fc_success_op(ap, rp, cp)); 1609 } 1610 1611 /* 1612 * opl_claim_memory 1613 * 1614 * claim-memory (align size vhint -- vaddr) 1615 */ 1616 static int 1617 opl_claim_memory(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1618 { 1619 int align, size, vhint; 1620 uint64_t answer, alen; 1621 ndi_ra_request_t request; 1622 struct fc_resource *resp; 1623 1624 if (fc_cell2int(cp->nargs) != 3) 1625 return (fc_syntax_error(cp, "nargs must be 3")); 1626 1627 if (fc_cell2int(cp->nresults) < 1) 1628 return (fc_syntax_error(cp, "nresults must be >= 1")); 1629 1630 vhint = fc_cell2int(fc_arg(cp, 2)); 1631 size = fc_cell2int(fc_arg(cp, 1)); 1632 align = fc_cell2int(fc_arg(cp, 0)); 1633 1634 FC_DEBUG3(1, CE_CONT, "opl_claim_memory: align=0x%x size=0x%x " 1635 "vhint=0x%x\n", align, size, vhint); 1636 1637 if (size == 0) { 1638 cmn_err(CE_WARN, "opl_claim_memory - unable to allocate " 1639 "contiguous memory of size zero\n"); 1640 return (fc_priv_error(cp, "allocation error")); 1641 } 1642 1643 if (vhint) { 1644 cmn_err(CE_WARN, "opl_claim_memory - vhint is not zero " 1645 "vhint=0x%x - Ignoring Argument\n", vhint); 1646 } 1647 1648 bzero((caddr_t)&request, sizeof (ndi_ra_request_t)); 1649 request.ra_flags = NDI_RA_ALLOC_BOUNDED; 1650 request.ra_boundbase = 0; 1651 request.ra_boundlen = 0xffffffff; 1652 request.ra_len = size; 1653 request.ra_align_mask = align - 1; 1654 1655 if (ndi_ra_alloc(ddi_root_node(), &request, &answer, &alen, 1656 "opl-fcodemem", NDI_RA_PASS) != NDI_SUCCESS) { 1657 cmn_err(CE_WARN, "opl_claim_memory - unable to allocate " 1658 "contiguous memory\n"); 1659 return (fc_priv_error(cp, "allocation error")); 1660 } 1661 1662 FC_DEBUG2(1, CE_CONT, "opl_claim_memory: address allocated=0x%lx " 1663 "size=0x%x\n", answer, alen); 1664 1665 cp->nresults = fc_int2cell(1); 1666 fc_result(cp, 0) = answer; 1667 1668 /* 1669 * Log this resource ... 1670 */ 1671 resp = kmem_zalloc(sizeof (struct fc_resource), KM_SLEEP); 1672 resp->type = RT_CONTIGIOUS; 1673 resp->fc_contig_virt = (void *)answer; 1674 resp->fc_contig_len = size; 1675 fc_add_resource(rp, resp); 1676 1677 return (fc_success_op(ap, rp, cp)); 1678 } 1679 1680 /* 1681 * opl_release_memory 1682 * 1683 * release-memory (size vaddr -- ) 1684 */ 1685 static int 1686 opl_release_memory(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1687 { 1688 int32_t vaddr, size; 1689 struct fc_resource *resp; 1690 1691 if (fc_cell2int(cp->nargs) != 2) 1692 return (fc_syntax_error(cp, "nargs must be 2")); 1693 1694 if (fc_cell2int(cp->nresults) != 0) 1695 return (fc_syntax_error(cp, "nresults must be 0")); 1696 1697 vaddr = fc_cell2int(fc_arg(cp, 1)); 1698 size = fc_cell2int(fc_arg(cp, 0)); 1699 1700 FC_DEBUG2(1, CE_CONT, "opl_release_memory: vaddr=0x%x size=0x%x\n", 1701 vaddr, size); 1702 1703 /* 1704 * Find if this request matches a mapping resource we set up. 1705 */ 1706 fc_lock_resource_list(rp); 1707 for (resp = rp->head; resp != NULL; resp = resp->next) { 1708 if (resp->type != RT_CONTIGIOUS) 1709 continue; 1710 if (resp->fc_contig_virt != (void *)(uintptr_t)vaddr) 1711 continue; 1712 if (resp->fc_contig_len == size) 1713 break; 1714 } 1715 fc_unlock_resource_list(rp); 1716 1717 if (resp == NULL) 1718 return (fc_priv_error(cp, "request doesn't match a " 1719 "known mapping")); 1720 1721 (void) ndi_ra_free(ddi_root_node(), vaddr, size, 1722 "opl-fcodemem", NDI_RA_PASS); 1723 1724 /* 1725 * remove the resource from the list and release it. 1726 */ 1727 fc_rem_resource(rp, resp); 1728 kmem_free(resp, sizeof (struct fc_resource)); 1729 1730 cp->nresults = fc_int2cell(0); 1731 1732 return (fc_success_op(ap, rp, cp)); 1733 } 1734 1735 /* 1736 * opl_vtop 1737 * 1738 * vtop (vaddr -- paddr.lo paddr.hi) 1739 */ 1740 static int 1741 opl_vtop(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1742 { 1743 int vaddr; 1744 uint64_t paddr; 1745 struct fc_resource *resp; 1746 1747 if (fc_cell2int(cp->nargs) != 1) 1748 return (fc_syntax_error(cp, "nargs must be 1")); 1749 1750 if (fc_cell2int(cp->nresults) >= 3) 1751 return (fc_syntax_error(cp, "nresults must be less than 2")); 1752 1753 vaddr = fc_cell2int(fc_arg(cp, 0)); 1754 1755 /* 1756 * Find if this request matches a mapping resource we set up. 1757 */ 1758 fc_lock_resource_list(rp); 1759 for (resp = rp->head; resp != NULL; resp = resp->next) { 1760 if (resp->type != RT_CONTIGIOUS) 1761 continue; 1762 if (resp->fc_contig_virt == (void *)(uintptr_t)vaddr) 1763 break; 1764 } 1765 fc_unlock_resource_list(rp); 1766 1767 if (resp == NULL) 1768 return (fc_priv_error(cp, "request doesn't match a " 1769 "known mapping")); 1770 1771 paddr = va_to_pa((void *)(uintptr_t)vaddr); 1772 1773 FC_DEBUG2(1, CE_CONT, "opl_vtop: vaddr=0x%x paddr=0x%x\n", 1774 vaddr, paddr); 1775 1776 cp->nresults = fc_int2cell(2); 1777 1778 fc_result(cp, 0) = paddr; 1779 fc_result(cp, 1) = 0; 1780 1781 return (fc_success_op(ap, rp, cp)); 1782 } 1783 1784 static int 1785 opl_config_child(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1786 { 1787 fc_phandle_t h; 1788 1789 if (fc_cell2int(cp->nargs) != 0) 1790 return (fc_syntax_error(cp, "nargs must be 0")); 1791 1792 if (fc_cell2int(cp->nresults) < 1) 1793 return (fc_syntax_error(cp, "nresults must be >= 1")); 1794 1795 h = fc_dip_to_phandle(fc_handle_to_phandle_head(rp), rp->child); 1796 1797 cp->nresults = fc_int2cell(1); 1798 fc_result(cp, 0) = fc_phandle2cell(h); 1799 1800 return (fc_success_op(ap, rp, cp)); 1801 } 1802 1803 static int 1804 opl_get_fcode(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1805 { 1806 caddr_t dropin_name_virt, fcode_virt; 1807 char *dropin_name, *fcode; 1808 int fcode_len, status; 1809 1810 if (fc_cell2int(cp->nargs) != 3) 1811 return (fc_syntax_error(cp, "nargs must be 3")); 1812 1813 if (fc_cell2int(cp->nresults) < 1) 1814 return (fc_syntax_error(cp, "nresults must be >= 1")); 1815 1816 dropin_name_virt = fc_cell2ptr(fc_arg(cp, 0)); 1817 1818 fcode_virt = fc_cell2ptr(fc_arg(cp, 1)); 1819 1820 fcode_len = fc_cell2int(fc_arg(cp, 2)); 1821 1822 dropin_name = kmem_zalloc(FC_SVC_NAME_LEN, KM_SLEEP); 1823 1824 FC_DEBUG2(1, CE_CONT, "get_fcode: %x %d\n", fcode_virt, fcode_len); 1825 1826 if (copyinstr(fc_cell2ptr(dropin_name_virt), dropin_name, 1827 FC_SVC_NAME_LEN - 1, NULL)) { 1828 FC_DEBUG1(1, CE_CONT, "opl_get_fcode: " 1829 "fault copying in drop in name %p\n", dropin_name_virt); 1830 status = 0; 1831 } else { 1832 FC_DEBUG1(1, CE_CONT, "get_fcode: %s\n", dropin_name); 1833 1834 fcode = kmem_zalloc(fcode_len, KM_SLEEP); 1835 1836 if ((status = prom_get_fcode(dropin_name, fcode)) != 0) { 1837 1838 if (copyout((void *)fcode, (void *)fcode_virt, 1839 fcode_len)) { 1840 cmn_err(CE_WARN, " opl_get_fcode: Unable " 1841 "to copy out fcode image"); 1842 status = 0; 1843 } 1844 } 1845 1846 kmem_free(fcode, fcode_len); 1847 } 1848 1849 kmem_free(dropin_name, FC_SVC_NAME_LEN); 1850 1851 cp->nresults = fc_int2cell(1); 1852 fc_result(cp, 0) = status; 1853 1854 return (fc_success_op(ap, rp, cp)); 1855 } 1856 1857 static int 1858 opl_get_fcode_size(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1859 { 1860 caddr_t virt; 1861 char *dropin_name; 1862 int len; 1863 1864 if (fc_cell2int(cp->nargs) != 1) 1865 return (fc_syntax_error(cp, "nargs must be 1")); 1866 1867 if (fc_cell2int(cp->nresults) < 1) 1868 return (fc_syntax_error(cp, "nresults must be >= 1")); 1869 1870 virt = fc_cell2ptr(fc_arg(cp, 0)); 1871 1872 dropin_name = kmem_zalloc(FC_SVC_NAME_LEN, KM_SLEEP); 1873 1874 FC_DEBUG0(1, CE_CONT, "opl_get_fcode_size:\n"); 1875 1876 if (copyinstr(fc_cell2ptr(virt), dropin_name, 1877 FC_SVC_NAME_LEN - 1, NULL)) { 1878 FC_DEBUG1(1, CE_CONT, "opl_get_fcode_size: " 1879 "fault copying in drop in name %p\n", virt); 1880 len = 0; 1881 } else { 1882 FC_DEBUG1(1, CE_CONT, "opl_get_fcode_size: %s\n", dropin_name); 1883 1884 len = prom_get_fcode_size(dropin_name); 1885 } 1886 1887 kmem_free(dropin_name, FC_SVC_NAME_LEN); 1888 1889 FC_DEBUG1(1, CE_CONT, "opl_get_fcode_size: fcode_len = %d\n", len); 1890 1891 cp->nresults = fc_int2cell(1); 1892 fc_result(cp, 0) = len; 1893 1894 return (fc_success_op(ap, rp, cp)); 1895 } 1896 1897 static int 1898 opl_map_phys(dev_info_t *dip, struct regspec *phys_spec, 1899 caddr_t *addrp, ddi_device_acc_attr_t *accattrp, 1900 ddi_acc_handle_t *handlep) 1901 { 1902 ddi_map_req_t mapreq; 1903 ddi_acc_hdl_t *acc_handlep; 1904 int result; 1905 struct regspec *rspecp; 1906 1907 *handlep = impl_acc_hdl_alloc(KM_SLEEP, NULL); 1908 acc_handlep = impl_acc_hdl_get(*handlep); 1909 acc_handlep->ah_vers = VERS_ACCHDL; 1910 acc_handlep->ah_dip = dip; 1911 acc_handlep->ah_rnumber = 0; 1912 acc_handlep->ah_offset = 0; 1913 acc_handlep->ah_len = 0; 1914 acc_handlep->ah_acc = *accattrp; 1915 rspecp = kmem_zalloc(sizeof (struct regspec), KM_SLEEP); 1916 *rspecp = *phys_spec; 1917 /* 1918 * cache a copy of the reg spec 1919 */ 1920 acc_handlep->ah_bus_private = rspecp; 1921 1922 mapreq.map_op = DDI_MO_MAP_LOCKED; 1923 mapreq.map_type = DDI_MT_REGSPEC; 1924 mapreq.map_obj.rp = (struct regspec *)phys_spec; 1925 mapreq.map_prot = PROT_READ | PROT_WRITE; 1926 mapreq.map_flags = DDI_MF_KERNEL_MAPPING; 1927 mapreq.map_handlep = acc_handlep; 1928 mapreq.map_vers = DDI_MAP_VERSION; 1929 1930 result = ddi_map(dip, &mapreq, 0, 0, addrp); 1931 1932 if (result != DDI_SUCCESS) { 1933 impl_acc_hdl_free(*handlep); 1934 kmem_free(rspecp, sizeof (struct regspec)); 1935 *handlep = (ddi_acc_handle_t)NULL; 1936 } else { 1937 acc_handlep->ah_addr = *addrp; 1938 } 1939 1940 return (result); 1941 } 1942 1943 static void 1944 opl_unmap_phys(ddi_acc_handle_t *handlep) 1945 { 1946 ddi_map_req_t mapreq; 1947 ddi_acc_hdl_t *acc_handlep; 1948 struct regspec *rspecp; 1949 1950 acc_handlep = impl_acc_hdl_get(*handlep); 1951 ASSERT(acc_handlep); 1952 rspecp = acc_handlep->ah_bus_private; 1953 1954 mapreq.map_op = DDI_MO_UNMAP; 1955 mapreq.map_type = DDI_MT_REGSPEC; 1956 mapreq.map_obj.rp = (struct regspec *)rspecp; 1957 mapreq.map_prot = PROT_READ | PROT_WRITE; 1958 mapreq.map_flags = DDI_MF_KERNEL_MAPPING; 1959 mapreq.map_handlep = acc_handlep; 1960 mapreq.map_vers = DDI_MAP_VERSION; 1961 1962 (void) ddi_map(acc_handlep->ah_dip, &mapreq, acc_handlep->ah_offset, 1963 acc_handlep->ah_len, &acc_handlep->ah_addr); 1964 1965 impl_acc_hdl_free(*handlep); 1966 /* 1967 * Free the cached copy 1968 */ 1969 kmem_free(rspecp, sizeof (struct regspec)); 1970 *handlep = (ddi_acc_handle_t)NULL; 1971 } 1972 1973 static int 1974 opl_get_hwd_va(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 1975 { 1976 uint32_t portid; 1977 void *hwd_virt; 1978 hwd_header_t *hwd_h = NULL; 1979 hwd_sb_t *hwd_sb = NULL; 1980 int lsb, ch, leaf; 1981 int status = 1; 1982 1983 /* Check the argument */ 1984 if (fc_cell2int(cp->nargs) != 2) 1985 return (fc_syntax_error(cp, "nargs must be 2")); 1986 1987 if (fc_cell2int(cp->nresults) < 1) 1988 return (fc_syntax_error(cp, "nresults must be >= 1")); 1989 1990 /* Get the parameters */ 1991 portid = fc_cell2uint32_t(fc_arg(cp, 0)); 1992 hwd_virt = (void *)fc_cell2ptr(fc_arg(cp, 1)); 1993 1994 /* Get the ID numbers */ 1995 lsb = OPL_IO_PORTID_TO_LSB(portid); 1996 ch = OPL_PORTID_TO_CHANNEL(portid); 1997 leaf = OPL_PORTID_TO_LEAF(portid); 1998 ASSERT(OPL_IO_PORTID(lsb, ch, leaf) == portid); 1999 2000 /* Set the pointer of hwd. */ 2001 if ((hwd_h = (hwd_header_t *)opl_boards[lsb].cfg_hwd) == NULL) { 2002 return (fc_priv_error(cp, "null hwd header")); 2003 } 2004 /* Set the pointer of hwd sb. */ 2005 if ((hwd_sb = (hwd_sb_t *)((char *)hwd_h + hwd_h->hdr_sb_info_offset)) 2006 == NULL) { 2007 return (fc_priv_error(cp, "null hwd sb")); 2008 } 2009 2010 if (ch == OPL_CMU_CHANNEL) { 2011 /* Copyout CMU-CH HW Descriptor */ 2012 if (copyout((void *)&hwd_sb->sb_cmu.cmu_ch, 2013 (void *)hwd_virt, sizeof (hwd_cmu_chan_t))) { 2014 cmn_err(CE_WARN, "opl_get_hwd_va: " 2015 "Unable to copy out cmuch descriptor for %x", 2016 portid); 2017 status = 0; 2018 } 2019 } else { 2020 /* Copyout PCI-CH HW Descriptor */ 2021 if (copyout((void *)&hwd_sb->sb_pci_ch[ch].pci_leaf[leaf], 2022 (void *)hwd_virt, sizeof (hwd_leaf_t))) { 2023 cmn_err(CE_WARN, "opl_get_hwd_va: " 2024 "Unable to copy out pcich descriptor for %x", 2025 portid); 2026 status = 0; 2027 } 2028 } 2029 2030 cp->nresults = fc_int2cell(1); 2031 fc_result(cp, 0) = status; 2032 2033 return (fc_success_op(ap, rp, cp)); 2034 } 2035 2036 /* 2037 * After Solaris boots, a user can enter OBP using L1A, etc. While in OBP, 2038 * interrupts may be received from PCI devices. These interrupts 2039 * cannot be handled meaningfully since the system is in OBP. These 2040 * interrupts need to be cleared on the CPU side so that the CPU may 2041 * continue with whatever it is doing. Devices that have raised the 2042 * interrupts are expected to reraise the interrupts after sometime 2043 * as they have not been handled. At that time, Solaris will have a 2044 * chance to properly service the interrupts. 2045 * 2046 * The location of the interrupt registers depends on what is present 2047 * at a port. OPL currently supports the Oberon and the CMU channel. 2048 * The following handler handles both kinds of ports and computes 2049 * interrupt register addresses from the specifications and Jupiter Bus 2050 * device bindings. 2051 * 2052 * Fcode drivers install their interrupt handler via a "master-interrupt" 2053 * service. For boot time devices, this takes place within OBP. In the case 2054 * of DR, OPL uses IKP. The Fcode drivers that run within the efcode framework 2055 * attempt to install their handler via the "master-interrupt" service. 2056 * However, we cannot meaningfully install the Fcode driver's handler. 2057 * Instead, we install our own handler in OBP which does the same thing. 2058 * 2059 * Note that the only handling done for interrupts here is to clear it 2060 * on the CPU side. If any device in the future requires more special 2061 * handling, we would have to put in some kind of framework for adding 2062 * device-specific handlers. This is *highly* unlikely, but possible. 2063 * 2064 * Finally, OBP provides a hook called "unix-interrupt-handler" to install 2065 * a Solaris-defined master-interrupt handler for a port. The default 2066 * definition for this method does nothing. Solaris may override this 2067 * with its own definition. This is the way the following handler gets 2068 * control from OBP when interrupts happen at a port after L1A, etc. 2069 */ 2070 2071 static char define_master_interrupt_handler[] = 2072 2073 /* 2074 * This method translates an Oberon port id to the base (physical) address 2075 * of the interrupt clear registers for that port id. 2076 */ 2077 2078 ": pcich-mid>clear-int-pa ( mid -- pa ) " 2079 " dup 1 >> 7 and ( mid ch# ) " 2080 " over 4 >> h# 1f and ( mid ch# lsb# ) " 2081 " 1 d# 46 << ( mid ch# lsb# pa ) " 2082 " swap d# 40 << or ( mid ch# pa ) " 2083 " swap d# 37 << or ( mid pa ) " 2084 " swap 1 and if h# 70.0000 else h# 60.0000 then " 2085 " or h# 1400 or ( pa ) " 2086 "; " 2087 2088 /* 2089 * This method translates a CMU channel port id to the base (physical) address 2090 * of the interrupt clear registers for that port id. There are two classes of 2091 * interrupts that need to be handled for a CMU channel: 2092 * - obio interrupts 2093 * - pci interrupts 2094 * So, there are two addresses that need to be computed. 2095 */ 2096 2097 ": cmuch-mid>clear-int-pa ( mid -- obio-pa pci-pa ) " 2098 " dup 1 >> 7 and ( mid ch# ) " 2099 " over 4 >> h# 1f and ( mid ch# lsb# ) " 2100 " 1 d# 46 << ( mid ch# lsb# pa ) " 2101 " swap d# 40 << or ( mid ch# pa ) " 2102 " swap d# 37 << or ( mid pa ) " 2103 " nip dup h# 1800 + ( pa obio-pa ) " 2104 " swap h# 1400 + ( obio-pa pci-pa ) " 2105 "; " 2106 2107 /* 2108 * This method checks if a given I/O port ID is valid or not. 2109 * For a given LSB, 2110 * Oberon ports range from 0 - 3 2111 * CMU ch ports range from 4 - 4 2112 * 2113 * Also, the Oberon supports leaves 0 and 1. 2114 * The CMU ch supports only one leaf, leaf 0. 2115 */ 2116 2117 ": valid-io-mid? ( mid -- flag ) " 2118 " dup 1 >> 7 and ( mid ch# ) " 2119 " dup 4 > if 2drop false exit then ( mid ch# ) " 2120 " 4 = swap 1 and 1 = and not " 2121 "; " 2122 2123 /* 2124 * This method checks if a given port id is a CMU ch. 2125 */ 2126 2127 ": cmuch? ( mid -- flag ) 1 >> 7 and 4 = ; " 2128 2129 /* 2130 * Given the base address of the array of interrupt clear registers for 2131 * a port id, this method iterates over the given interrupt number bitmap 2132 * and resets the interrupt on the CPU side for every interrupt number 2133 * in the bitmap. Note that physical addresses are used to perform the 2134 * writes, not virtual addresses. This allows the handler to work without 2135 * any involvement from Solaris. 2136 */ 2137 2138 ": clear-ints ( pa bitmap count -- ) " 2139 " 0 do ( pa bitmap ) " 2140 " dup 0= if 2drop unloop exit then " 2141 " tuck ( bitmap pa bitmap ) " 2142 " 1 and if ( bitmap pa ) " 2143 " dup i 8 * + 0 swap ( bitmap pa 0 pa' ) " 2144 " h# 15 spacex! ( bitmap pa ) " 2145 " then ( bitmap pa ) " 2146 " swap 1 >> ( pa bitmap ) " 2147 " loop " 2148 "; " 2149 2150 /* 2151 * This method replaces the master-interrupt handler in OBP. Once 2152 * this method is plumbed into OBP, OBP transfers control to this 2153 * handler while returning to Solaris from OBP after L1A. This method's 2154 * task is to simply reset received interrupts on the CPU side. 2155 * When the devices reassert the interrupts later, Solaris will 2156 * be able to see them and handle them. 2157 * 2158 * For each port ID that has interrupts, this method is called 2159 * once by OBP. The input arguments are: 2160 * mid portid 2161 * bitmap bitmap of interrupts that have happened 2162 * 2163 * This method returns true, if it is able to handle the interrupts. 2164 * OBP does nothing further. 2165 * 2166 * This method returns false, if it encountered a problem. Currently, 2167 * the only problem could be an invalid port id. OBP needs to do 2168 * its own processing in that case. If this method returns false, 2169 * it preserves the mid and bitmap arguments for OBP. 2170 */ 2171 2172 ": unix-resend-mondos ( mid bitmap -- [ mid bitmap false ] | true ) " 2173 2174 /* 2175 * Uncomment the following line if you want to display the input arguments. 2176 * This is meant for debugging. 2177 * " .\" Bitmap=\" dup u. .\" MID=\" over u. cr " 2178 */ 2179 2180 /* 2181 * If the port id is not valid (according to the Oberon and CMU ch 2182 * specifications, then return false to OBP to continue further 2183 * processing. 2184 */ 2185 2186 " over valid-io-mid? not if ( mid bitmap ) " 2187 " false exit " 2188 " then " 2189 2190 /* 2191 * If the port is a CMU ch, then the 64-bit bitmap represents 2192 * 2 32-bit bitmaps: 2193 * - obio interrupt bitmap (20 bits) 2194 * - pci interrupt bitmap (32 bits) 2195 * 2196 * - Split the bitmap into two 2197 * - Compute the base addresses of the interrupt clear registers 2198 * for both pci interrupts and obio interrupts 2199 * - Clear obio interrupts 2200 * - Clear pci interrupts 2201 */ 2202 2203 " over cmuch? if ( mid bitmap ) " 2204 " xlsplit ( mid pci-bit obio-bit ) " 2205 " rot cmuch-mid>clear-int-pa ( pci-bit obio-bit obio-pa pci-pa ) " 2206 " >r ( pci-bit obio-bit obio-pa ) ( r: pci-pa ) " 2207 " swap d# 20 clear-ints ( pci-bit ) ( r: pci-pa ) " 2208 " r> swap d# 32 clear-ints ( ) ( r: ) " 2209 2210 /* 2211 * If the port is an Oberon, then the 64-bit bitmap is used fully. 2212 * 2213 * - Compute the base address of the interrupt clear registers 2214 * - Clear interrupts 2215 */ 2216 2217 " else ( mid bitmap ) " 2218 " swap pcich-mid>clear-int-pa ( bitmap pa ) " 2219 " swap d# 64 clear-ints ( ) " 2220 " then " 2221 2222 /* 2223 * Always return true from here. 2224 */ 2225 2226 " true ( true ) " 2227 "; " 2228 ; 2229 2230 static char install_master_interrupt_handler[] = 2231 "' unix-resend-mondos to unix-interrupt-handler"; 2232 static char handler[] = "unix-interrupt-handler"; 2233 static char handler_defined[] = "p\" %s\" find nip swap l! "; 2234 2235 /*ARGSUSED*/ 2236 static int 2237 master_interrupt_init(uint32_t portid, uint32_t xt) 2238 { 2239 uint_t defined; 2240 char buf[sizeof (handler) + sizeof (handler_defined)]; 2241 2242 if (master_interrupt_inited) 2243 return (1); 2244 2245 /* 2246 * Check if the defer word "unix-interrupt-handler" is defined. 2247 * This must be defined for OPL systems. So, this is only a 2248 * sanity check. 2249 */ 2250 (void) sprintf(buf, handler_defined, handler); 2251 prom_interpret(buf, (uintptr_t)&defined, 0, 0, 0, 0); 2252 if (!defined) { 2253 cmn_err(CE_WARN, "master_interrupt_init: " 2254 "%s is not defined\n", handler); 2255 return (0); 2256 } 2257 2258 /* 2259 * Install the generic master-interrupt handler. Note that 2260 * this is only done one time on the first DR operation. 2261 * This is because, for OPL, one, single generic handler 2262 * handles all ports (Oberon and CMU channel) and all 2263 * interrupt sources within each port. 2264 * 2265 * The current support is only for the Oberon and CMU-channel. 2266 * If any others need to be supported, the handler has to be 2267 * modified accordingly. 2268 */ 2269 2270 /* 2271 * Define the OPL master interrupt handler 2272 */ 2273 prom_interpret(define_master_interrupt_handler, 0, 0, 0, 0, 0); 2274 2275 /* 2276 * Take over the master interrupt handler from OBP. 2277 */ 2278 prom_interpret(install_master_interrupt_handler, 0, 0, 0, 0, 0); 2279 2280 master_interrupt_inited = 1; 2281 2282 /* 2283 * prom_interpret() does not return a status. So, we assume 2284 * that the calls succeeded. In reality, the calls may fail 2285 * if there is a syntax error, etc in the strings. 2286 */ 2287 2288 return (1); 2289 } 2290 2291 /* 2292 * Install the master-interrupt handler for a device. 2293 */ 2294 static int 2295 opl_master_interrupt(dev_info_t *ap, fco_handle_t rp, fc_ci_t *cp) 2296 { 2297 uint32_t portid, xt; 2298 int board, channel, leaf; 2299 int status; 2300 2301 /* Check the argument */ 2302 if (fc_cell2int(cp->nargs) != 2) 2303 return (fc_syntax_error(cp, "nargs must be 2")); 2304 2305 if (fc_cell2int(cp->nresults) < 1) 2306 return (fc_syntax_error(cp, "nresults must be >= 1")); 2307 2308 /* Get the parameters */ 2309 portid = fc_cell2uint32_t(fc_arg(cp, 0)); 2310 xt = fc_cell2uint32_t(fc_arg(cp, 1)); 2311 2312 board = OPL_IO_PORTID_TO_LSB(portid); 2313 channel = OPL_PORTID_TO_CHANNEL(portid); 2314 leaf = OPL_PORTID_TO_LEAF(portid); 2315 2316 if ((board >= HWD_SBS_PER_DOMAIN) || !OPL_VALID_CHANNEL(channel) || 2317 (OPL_OBERON_CHANNEL(channel) && !OPL_VALID_LEAF(leaf)) || 2318 ((channel == OPL_CMU_CHANNEL) && (leaf != 0))) { 2319 FC_DEBUG1(1, CE_CONT, "opl_master_interrupt: invalid port %x\n", 2320 portid); 2321 status = 0; 2322 } else { 2323 status = master_interrupt_init(portid, xt); 2324 } 2325 2326 cp->nresults = fc_int2cell(1); 2327 fc_result(cp, 0) = status; 2328 2329 return (fc_success_op(ap, rp, cp)); 2330 } 2331 2332 /* 2333 * Set the properties for a leaf node (Oberon leaf or CMU channel leaf). 2334 */ 2335 /*ARGSUSED*/ 2336 static int 2337 opl_create_leaf(dev_info_t *node, void *arg, uint_t flags) 2338 { 2339 int ret; 2340 2341 OPL_UPDATE_PROP(string, node, "name", OPL_PCI_LEAF_NODE); 2342 2343 OPL_UPDATE_PROP(string, node, "status", "okay"); 2344 2345 return (DDI_WALK_TERMINATE); 2346 } 2347 2348 static char * 2349 opl_get_probe_string(opl_probe_t *probe, int channel, int leaf) 2350 { 2351 char *probe_string; 2352 int portid; 2353 2354 probe_string = kmem_zalloc(PROBE_STR_SIZE, KM_SLEEP); 2355 2356 if (channel == OPL_CMU_CHANNEL) 2357 portid = probe->pr_sb->sb_cmu.cmu_ch.chan_portid; 2358 else 2359 portid = probe-> 2360 pr_sb->sb_pci_ch[channel].pci_leaf[leaf].leaf_port_id; 2361 2362 (void) sprintf(probe_string, "%x", portid); 2363 2364 return (probe_string); 2365 } 2366 2367 static int 2368 opl_probe_leaf(opl_probe_t *probe) 2369 { 2370 int channel, leaf, portid, error, circ; 2371 int board; 2372 fco_handle_t fco_handle, *cfg_handle; 2373 dev_info_t *parent, *leaf_node; 2374 char unit_address[UNIT_ADDR_SIZE]; 2375 char *probe_string; 2376 opl_board_cfg_t *board_cfg; 2377 2378 board = probe->pr_board; 2379 channel = probe->pr_channel; 2380 leaf = probe->pr_leaf; 2381 parent = ddi_root_node(); 2382 board_cfg = &opl_boards[board]; 2383 2384 ASSERT(OPL_VALID_CHANNEL(channel)); 2385 ASSERT(OPL_VALID_LEAF(leaf)); 2386 2387 if (channel == OPL_CMU_CHANNEL) { 2388 portid = probe->pr_sb->sb_cmu.cmu_ch.chan_portid; 2389 cfg_handle = &board_cfg->cfg_cmuch_handle; 2390 } else { 2391 portid = probe-> 2392 pr_sb->sb_pci_ch[channel].pci_leaf[leaf].leaf_port_id; 2393 cfg_handle = &board_cfg->cfg_pcich_handle[channel][leaf]; 2394 } 2395 2396 /* 2397 * Prevent any changes to leaf_node until we have bound 2398 * it to the correct driver. 2399 */ 2400 ndi_devi_enter(parent, &circ); 2401 2402 /* 2403 * Ideally, fcode would be run from the "sid_branch_create" 2404 * callback (that is the primary purpose of that callback). 2405 * However, the fcode interpreter was written with the 2406 * assumption that the "new_child" was linked into the 2407 * device tree. The callback is invoked with the devinfo node 2408 * in the DS_PROTO state. More investigation is needed before 2409 * we can invoke the interpreter from the callback. For now, 2410 * we create the "new_child" in the BOUND state, invoke the 2411 * fcode interpreter and then rebind the dip to use any 2412 * compatible properties created by fcode. 2413 */ 2414 2415 probe->pr_parent = parent; 2416 probe->pr_create = opl_create_leaf; 2417 probe->pr_hold = 1; 2418 2419 leaf_node = opl_create_node(probe); 2420 if (leaf_node == NULL) { 2421 2422 cmn_err(CE_WARN, "IKP: create leaf (%d-%d-%d) failed", 2423 probe->pr_board, probe->pr_channel, probe->pr_leaf); 2424 ndi_devi_exit(parent, circ); 2425 return (-1); 2426 } 2427 2428 /* 2429 * The platform DR interfaces created the dip in 2430 * bound state. Bring devinfo node down to linked 2431 * state and hold it there until compatible 2432 * properties are created. 2433 */ 2434 e_ddi_branch_rele(leaf_node); 2435 (void) i_ndi_unconfig_node(leaf_node, DS_LINKED, 0); 2436 ASSERT(i_ddi_node_state(leaf_node) == DS_LINKED); 2437 e_ddi_branch_hold(leaf_node); 2438 2439 mutex_enter(&DEVI(leaf_node)->devi_lock); 2440 DEVI(leaf_node)->devi_flags |= DEVI_NO_BIND; 2441 mutex_exit(&DEVI(leaf_node)->devi_lock); 2442 2443 /* 2444 * Drop the busy-hold on parent before calling 2445 * fcode_interpreter to prevent potential deadlocks 2446 */ 2447 ndi_devi_exit(parent, circ); 2448 2449 (void) sprintf(unit_address, "%x", portid); 2450 2451 /* 2452 * Get the probe string 2453 */ 2454 probe_string = opl_get_probe_string(probe, channel, leaf); 2455 2456 /* 2457 * The fcode pointer specified here is NULL and the fcode 2458 * size specified here is 0. This causes the user-level 2459 * fcode interpreter to issue a request to the fcode 2460 * driver to get the Oberon/cmu-ch fcode. 2461 */ 2462 fco_handle = opl_fc_ops_alloc_handle(parent, leaf_node, 2463 NULL, 0, unit_address, probe_string); 2464 2465 error = fcode_interpreter(parent, &opl_fc_do_op, fco_handle); 2466 2467 if (error != 0) { 2468 cmn_err(CE_WARN, "IKP: Unable to probe PCI leaf (%d-%d-%d)", 2469 probe->pr_board, probe->pr_channel, probe->pr_leaf); 2470 2471 opl_fc_ops_free_handle(fco_handle); 2472 2473 if (probe_string != NULL) 2474 kmem_free(probe_string, PROBE_STR_SIZE); 2475 2476 (void) opl_destroy_node(leaf_node); 2477 } else { 2478 *cfg_handle = fco_handle; 2479 2480 if (channel == OPL_CMU_CHANNEL) 2481 board_cfg->cfg_cmuch_probe_str = probe_string; 2482 else 2483 board_cfg->cfg_pcich_probe_str[channel][leaf] 2484 = probe_string; 2485 2486 /* 2487 * Compatible properties (if any) have been created, 2488 * so bind driver. 2489 */ 2490 ndi_devi_enter(parent, &circ); 2491 ASSERT(i_ddi_node_state(leaf_node) <= DS_LINKED); 2492 2493 mutex_enter(&DEVI(leaf_node)->devi_lock); 2494 DEVI(leaf_node)->devi_flags &= ~DEVI_NO_BIND; 2495 mutex_exit(&DEVI(leaf_node)->devi_lock); 2496 2497 ndi_devi_exit(parent, circ); 2498 2499 if (ndi_devi_bind_driver(leaf_node, 0) != 2500 DDI_SUCCESS) { 2501 cmn_err(CE_WARN, 2502 "IKP: Unable to bind PCI leaf (%d-%d-%d)", 2503 probe->pr_board, probe->pr_channel, 2504 probe->pr_leaf); 2505 } 2506 } 2507 2508 if ((error != 0) && (channel == OPL_CMU_CHANNEL)) 2509 return (-1); 2510 2511 return (0); 2512 } 2513 2514 static void 2515 opl_init_leaves(int myboard) 2516 { 2517 dev_info_t *parent, *node; 2518 char *name; 2519 int circ, ret; 2520 int len, portid, board, channel, leaf; 2521 opl_board_cfg_t *cfg; 2522 2523 parent = ddi_root_node(); 2524 2525 /* 2526 * Hold parent node busy to walk its child list 2527 */ 2528 ndi_devi_enter(parent, &circ); 2529 2530 for (node = ddi_get_child(parent); 2531 (node != NULL); 2532 node = ddi_get_next_sibling(node)) { 2533 2534 ret = OPL_GET_PROP(string, node, "name", &name, &len); 2535 if (ret != DDI_PROP_SUCCESS) { 2536 /* 2537 * The property does not exist for this node. 2538 */ 2539 continue; 2540 } 2541 2542 if (strncmp(name, OPL_PCI_LEAF_NODE, len) == 0) { 2543 2544 ret = OPL_GET_PROP(int, node, "portid", &portid, -1); 2545 if (ret == DDI_PROP_SUCCESS) { 2546 2547 ret = OPL_GET_PROP(int, node, "board#", 2548 &board, -1); 2549 if ((ret != DDI_PROP_SUCCESS) || 2550 (board != myboard)) { 2551 kmem_free(name, len); 2552 continue; 2553 } 2554 2555 cfg = &opl_boards[board]; 2556 channel = OPL_PORTID_TO_CHANNEL(portid); 2557 if (channel == OPL_CMU_CHANNEL) { 2558 2559 if (cfg->cfg_cmuch_handle != NULL) 2560 cfg->cfg_cmuch_leaf = node; 2561 2562 } else { 2563 2564 leaf = OPL_PORTID_TO_LEAF(portid); 2565 if (cfg->cfg_pcich_handle 2566 [channel][leaf] != NULL) 2567 cfg->cfg_pcich_leaf 2568 [channel][leaf] = node; 2569 } 2570 } 2571 } 2572 2573 kmem_free(name, len); 2574 if (ret != DDI_PROP_SUCCESS) 2575 break; 2576 } 2577 2578 ndi_devi_exit(parent, circ); 2579 } 2580 2581 /* 2582 * Create "pci" node and hierarchy for the Oberon channels and the 2583 * CMU channel. 2584 */ 2585 /*ARGSUSED*/ 2586 static int 2587 opl_probe_io(opl_probe_t *probe) 2588 { 2589 2590 int i, j; 2591 hwd_pci_ch_t *channels; 2592 2593 if (HWD_STATUS_OK(probe->pr_sb->sb_cmu.cmu_ch.chan_status)) { 2594 2595 probe->pr_channel = HWD_CMU_CHANNEL; 2596 probe->pr_channel_status = 2597 probe->pr_sb->sb_cmu.cmu_ch.chan_status; 2598 probe->pr_leaf = 0; 2599 probe->pr_leaf_status = probe->pr_channel_status; 2600 2601 if (opl_probe_leaf(probe) != 0) 2602 return (-1); 2603 } 2604 2605 channels = &probe->pr_sb->sb_pci_ch[0]; 2606 2607 for (i = 0; i < HWD_PCI_CHANNELS_PER_SB; i++) { 2608 2609 if (!HWD_STATUS_OK(channels[i].pci_status)) 2610 continue; 2611 2612 probe->pr_channel = i; 2613 probe->pr_channel_status = channels[i].pci_status; 2614 2615 for (j = 0; j < HWD_LEAVES_PER_PCI_CHANNEL; j++) { 2616 2617 probe->pr_leaf = j; 2618 probe->pr_leaf_status = 2619 channels[i].pci_leaf[j].leaf_status; 2620 2621 if (!HWD_STATUS_OK(probe->pr_leaf_status)) 2622 continue; 2623 2624 (void) opl_probe_leaf(probe); 2625 } 2626 } 2627 opl_init_leaves(probe->pr_board); 2628 return (0); 2629 } 2630 2631 /* 2632 * Perform the probe in the following order: 2633 * 2634 * processors 2635 * memory 2636 * IO 2637 * 2638 * Each probe function returns 0 on sucess and a non-zero value on failure. 2639 * What is a failure is determined by the implementor of the probe function. 2640 * For example, while probing CPUs, any error encountered during probe 2641 * is considered a failure and causes the whole probe operation to fail. 2642 * However, for I/O, an error encountered while probing one device 2643 * should not prevent other devices from being probed. It should not cause 2644 * the whole probe operation to fail. 2645 */ 2646 int 2647 opl_probe_sb(int board) 2648 { 2649 opl_probe_t *probe; 2650 int ret; 2651 2652 if ((board < 0) || (board >= HWD_SBS_PER_DOMAIN)) 2653 return (-1); 2654 2655 ASSERT(opl_cfg_inited != 0); 2656 2657 /* 2658 * If the previous probe failed and left a partially configured 2659 * board, we need to unprobe the board and start with a clean slate. 2660 */ 2661 if ((opl_boards[board].cfg_hwd != NULL) && 2662 (opl_unprobe_sb(board) != 0)) 2663 return (-1); 2664 2665 ret = 0; 2666 2667 probe = kmem_zalloc(sizeof (opl_probe_t), KM_SLEEP); 2668 probe->pr_board = board; 2669 2670 if ((opl_probe_init(probe) != 0) || 2671 2672 (opl_probe_cpu_chips(probe) != 0) || 2673 2674 (opl_probe_memory(probe) != 0) || 2675 2676 (opl_probe_io(probe) != 0)) { 2677 2678 /* 2679 * Probe failed. Perform cleanup. 2680 */ 2681 (void) opl_unprobe_sb(board); 2682 ret = -1; 2683 } 2684 2685 kmem_free(probe, sizeof (opl_probe_t)); 2686 2687 return (ret); 2688 } 2689 2690 /* 2691 * This unprobing also includes CMU-CH. 2692 */ 2693 /*ARGSUSED*/ 2694 static int 2695 opl_unprobe_io(int board) 2696 { 2697 int i, j, ret; 2698 opl_board_cfg_t *board_cfg; 2699 dev_info_t **node; 2700 fco_handle_t *hand; 2701 char **probe_str; 2702 2703 board_cfg = &opl_boards[board]; 2704 2705 for (i = 0; i < HWD_PCI_CHANNELS_PER_SB; i++) { 2706 2707 for (j = 0; j < HWD_LEAVES_PER_PCI_CHANNEL; j++) { 2708 2709 node = &board_cfg->cfg_pcich_leaf[i][j]; 2710 hand = &board_cfg->cfg_pcich_handle[i][j]; 2711 probe_str = &board_cfg->cfg_pcich_probe_str[i][j]; 2712 2713 if (*node == NULL) 2714 continue; 2715 2716 if (*hand != NULL) { 2717 opl_fc_ops_free_handle(*hand); 2718 *hand = NULL; 2719 } 2720 2721 if (*probe_str != NULL) { 2722 kmem_free(*probe_str, PROBE_STR_SIZE); 2723 *probe_str = NULL; 2724 } 2725 2726 ret = opl_destroy_node(*node); 2727 if (ret != 0) { 2728 2729 cmn_err(CE_WARN, 2730 "IKP: destroy pci (%d-%d-%d) failed", 2731 board, i, j); 2732 return (-1); 2733 } 2734 2735 *node = NULL; 2736 2737 } 2738 } 2739 2740 node = &board_cfg->cfg_cmuch_leaf; 2741 hand = &board_cfg->cfg_cmuch_handle; 2742 probe_str = &board_cfg->cfg_cmuch_probe_str; 2743 2744 if (*node == NULL) 2745 return (0); 2746 2747 if (*hand != NULL) { 2748 opl_fc_ops_free_handle(*hand); 2749 *hand = NULL; 2750 } 2751 2752 if (*probe_str != NULL) { 2753 kmem_free(*probe_str, PROBE_STR_SIZE); 2754 *probe_str = NULL; 2755 } 2756 2757 if (opl_destroy_node(*node) != 0) { 2758 2759 cmn_err(CE_WARN, "IKP: destroy pci (%d-%d-%d) failed", 2760 board, OPL_CMU_CHANNEL, 0); 2761 return (-1); 2762 } 2763 2764 *node = NULL; 2765 2766 return (0); 2767 } 2768 2769 /* 2770 * Destroy the "pseudo-mc" node for a board. 2771 */ 2772 static int 2773 opl_unprobe_memory(int board) 2774 { 2775 opl_board_cfg_t *board_cfg; 2776 2777 board_cfg = &opl_boards[board]; 2778 2779 if (board_cfg->cfg_pseudo_mc == NULL) 2780 return (0); 2781 2782 if (opl_destroy_node(board_cfg->cfg_pseudo_mc) != 0) { 2783 2784 cmn_err(CE_WARN, "IKP: destroy pseudo-mc (%d) failed", board); 2785 return (-1); 2786 } 2787 2788 board_cfg->cfg_pseudo_mc = NULL; 2789 2790 return (0); 2791 } 2792 2793 /* 2794 * Destroy the "cmp" nodes for a board. This also destroys the "core" 2795 * and "cpu" nodes below the "cmp" nodes. 2796 */ 2797 static int 2798 opl_unprobe_processors(int board) 2799 { 2800 int i; 2801 dev_info_t **cfg_cpu_chips; 2802 2803 cfg_cpu_chips = opl_boards[board].cfg_cpu_chips; 2804 2805 for (i = 0; i < HWD_CPU_CHIPS_PER_CMU; i++) { 2806 2807 if (cfg_cpu_chips[i] == NULL) 2808 continue; 2809 2810 if (opl_destroy_node(cfg_cpu_chips[i]) != 0) { 2811 2812 cmn_err(CE_WARN, 2813 "IKP: destroy chip (%d-%d) failed", board, i); 2814 return (-1); 2815 } 2816 2817 cfg_cpu_chips[i] = NULL; 2818 } 2819 2820 return (0); 2821 } 2822 2823 /* 2824 * Perform the unprobe in the following order: 2825 * 2826 * IO 2827 * memory 2828 * processors 2829 */ 2830 int 2831 opl_unprobe_sb(int board) 2832 { 2833 if ((board < 0) || (board >= HWD_SBS_PER_DOMAIN)) 2834 return (-1); 2835 2836 ASSERT(opl_cfg_inited != 0); 2837 2838 if ((opl_unprobe_io(board) != 0) || 2839 2840 (opl_unprobe_memory(board) != 0) || 2841 2842 (opl_unprobe_processors(board) != 0)) 2843 2844 return (-1); 2845 2846 if (opl_boards[board].cfg_hwd != NULL) { 2847 #ifdef UCTEST 2848 size_t size = 0xA000; 2849 #endif 2850 /* Release the memory for the HWD */ 2851 void *hwdp = opl_boards[board].cfg_hwd; 2852 opl_boards[board].cfg_hwd = NULL; 2853 #ifdef UCTEST 2854 hwdp = (void *)((char *)hwdp - 0x1000); 2855 hat_unload(kas.a_hat, hwdp, size, HAT_UNLOAD_UNLOCK); 2856 vmem_free(heap_arena, hwdp, size); 2857 #else 2858 kmem_free(hwdp, HWD_DATA_SIZE); 2859 #endif 2860 } 2861 return (0); 2862 } 2863 2864 /* 2865 * For MAC patrol support, we need to update the PA-related properties 2866 * when there is a copy-rename event. This should be called after the 2867 * physical copy and rename has been done by DR, and before the MAC 2868 * patrol is restarted. 2869 */ 2870 int 2871 oplcfg_pa_swap(int from, int to) 2872 { 2873 dev_info_t *from_node = opl_boards[from].cfg_pseudo_mc; 2874 dev_info_t *to_node = opl_boards[to].cfg_pseudo_mc; 2875 opl_range_t *rangef, *ranget; 2876 int elems; 2877 int ret; 2878 2879 if ((OPL_GET_PROP_ARRAY(int, from_node, "sb-mem-ranges", rangef, 2880 elems) != DDI_SUCCESS) || (elems != 4)) { 2881 /* XXX -- bad news */ 2882 return (-1); 2883 } 2884 if ((OPL_GET_PROP_ARRAY(int, to_node, "sb-mem-ranges", ranget, 2885 elems) != DDI_SUCCESS) || (elems != 4)) { 2886 /* XXX -- bad news */ 2887 return (-1); 2888 } 2889 OPL_UPDATE_PROP_ARRAY(int, from_node, "sb-mem-ranges", (int *)ranget, 2890 4); 2891 OPL_UPDATE_PROP_ARRAY(int, to_node, "sb-mem-ranges", (int *)rangef, 2892 4); 2893 2894 OPL_FREE_PROP(ranget); 2895 OPL_FREE_PROP(rangef); 2896 2897 return (0); 2898 } 2899