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kernel / drivers / char / rio / rioboot.c
at v2.6.23-rc1 1114 lines 38 kB view raw
1/* 2** ----------------------------------------------------------------------------- 3** 4** Perle Specialix driver for Linux 5** Ported from existing RIO Driver for SCO sources. 6 * 7 * (C) 1990 - 2000 Specialix International Ltd., Byfleet, Surrey, UK. 8 * 9 * This program is free software; you can redistribute it and/or modify 10 * it under the terms of the GNU General Public License as published by 11 * the Free Software Foundation; either version 2 of the License, or 12 * (at your option) any later version. 13 * 14 * This program is distributed in the hope that it will be useful, 15 * but WITHOUT ANY WARRANTY; without even the implied warranty of 16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 17 * GNU General Public License for more details. 18 * 19 * You should have received a copy of the GNU General Public License 20 * along with this program; if not, write to the Free Software 21 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 22** 23** Module : rioboot.c 24** SID : 1.3 25** Last Modified : 11/6/98 10:33:36 26** Retrieved : 11/6/98 10:33:48 27** 28** ident @(#)rioboot.c 1.3 29** 30** ----------------------------------------------------------------------------- 31*/ 32 33#include <linux/module.h> 34#include <linux/slab.h> 35#include <linux/termios.h> 36#include <linux/serial.h> 37#include <linux/vmalloc.h> 38#include <asm/semaphore.h> 39#include <linux/generic_serial.h> 40#include <linux/errno.h> 41#include <linux/interrupt.h> 42#include <linux/delay.h> 43#include <asm/io.h> 44#include <asm/system.h> 45#include <asm/string.h> 46#include <asm/uaccess.h> 47 48 49#include "linux_compat.h" 50#include "rio_linux.h" 51#include "pkt.h" 52#include "daemon.h" 53#include "rio.h" 54#include "riospace.h" 55#include "cmdpkt.h" 56#include "map.h" 57#include "rup.h" 58#include "port.h" 59#include "riodrvr.h" 60#include "rioinfo.h" 61#include "func.h" 62#include "errors.h" 63#include "pci.h" 64 65#include "parmmap.h" 66#include "unixrup.h" 67#include "board.h" 68#include "host.h" 69#include "phb.h" 70#include "link.h" 71#include "cmdblk.h" 72#include "route.h" 73 74static int RIOBootComplete(struct rio_info *p, struct Host *HostP, unsigned int Rup, struct PktCmd __iomem *PktCmdP); 75 76static const unsigned char RIOAtVec2Ctrl[] = { 77 /* 0 */ INTERRUPT_DISABLE, 78 /* 1 */ INTERRUPT_DISABLE, 79 /* 2 */ INTERRUPT_DISABLE, 80 /* 3 */ INTERRUPT_DISABLE, 81 /* 4 */ INTERRUPT_DISABLE, 82 /* 5 */ INTERRUPT_DISABLE, 83 /* 6 */ INTERRUPT_DISABLE, 84 /* 7 */ INTERRUPT_DISABLE, 85 /* 8 */ INTERRUPT_DISABLE, 86 /* 9 */ IRQ_9 | INTERRUPT_ENABLE, 87 /* 10 */ INTERRUPT_DISABLE, 88 /* 11 */ IRQ_11 | INTERRUPT_ENABLE, 89 /* 12 */ IRQ_12 | INTERRUPT_ENABLE, 90 /* 13 */ INTERRUPT_DISABLE, 91 /* 14 */ INTERRUPT_DISABLE, 92 /* 15 */ IRQ_15 | INTERRUPT_ENABLE 93}; 94 95/** 96 * RIOBootCodeRTA - Load RTA boot code 97 * @p: RIO to load 98 * @rbp: Download descriptor 99 * 100 * Called when the user process initiates booting of the card firmware. 101 * Lads the firmware 102 */ 103 104int RIOBootCodeRTA(struct rio_info *p, struct DownLoad * rbp) 105{ 106 int offset; 107 108 func_enter(); 109 110 rio_dprintk(RIO_DEBUG_BOOT, "Data at user address %p\n", rbp->DataP); 111 112 /* 113 ** Check that we have set asside enough memory for this 114 */ 115 if (rbp->Count > SIXTY_FOUR_K) { 116 rio_dprintk(RIO_DEBUG_BOOT, "RTA Boot Code Too Large!\n"); 117 p->RIOError.Error = HOST_FILE_TOO_LARGE; 118 func_exit(); 119 return -ENOMEM; 120 } 121 122 if (p->RIOBooting) { 123 rio_dprintk(RIO_DEBUG_BOOT, "RTA Boot Code : BUSY BUSY BUSY!\n"); 124 p->RIOError.Error = BOOT_IN_PROGRESS; 125 func_exit(); 126 return -EBUSY; 127 } 128 129 /* 130 ** The data we load in must end on a (RTA_BOOT_DATA_SIZE) byte boundary, 131 ** so calculate how far we have to move the data up the buffer 132 ** to achieve this. 133 */ 134 offset = (RTA_BOOT_DATA_SIZE - (rbp->Count % RTA_BOOT_DATA_SIZE)) % RTA_BOOT_DATA_SIZE; 135 136 /* 137 ** Be clean, and clear the 'unused' portion of the boot buffer, 138 ** because it will (eventually) be part of the Rta run time environment 139 ** and so should be zeroed. 140 */ 141 memset(p->RIOBootPackets, 0, offset); 142 143 /* 144 ** Copy the data from user space into the array 145 */ 146 147 if (copy_from_user(((u8 *)p->RIOBootPackets) + offset, rbp->DataP, rbp->Count)) { 148 rio_dprintk(RIO_DEBUG_BOOT, "Bad data copy from user space\n"); 149 p->RIOError.Error = COPYIN_FAILED; 150 func_exit(); 151 return -EFAULT; 152 } 153 154 /* 155 ** Make sure that our copy of the size includes that offset we discussed 156 ** earlier. 157 */ 158 p->RIONumBootPkts = (rbp->Count + offset) / RTA_BOOT_DATA_SIZE; 159 p->RIOBootCount = rbp->Count; 160 161 func_exit(); 162 return 0; 163} 164 165/** 166 * rio_start_card_running - host card start 167 * @HostP: The RIO to kick off 168 * 169 * Start a RIO processor unit running. Encapsulates the knowledge 170 * of the card type. 171 */ 172 173void rio_start_card_running(struct Host *HostP) 174{ 175 switch (HostP->Type) { 176 case RIO_AT: 177 rio_dprintk(RIO_DEBUG_BOOT, "Start ISA card running\n"); 178 writeb(BOOT_FROM_RAM | EXTERNAL_BUS_ON | HostP->Mode | RIOAtVec2Ctrl[HostP->Ivec & 0xF], &HostP->Control); 179 break; 180 case RIO_PCI: 181 /* 182 ** PCI is much the same as MCA. Everything is once again memory 183 ** mapped, so we are writing to memory registers instead of io 184 ** ports. 185 */ 186 rio_dprintk(RIO_DEBUG_BOOT, "Start PCI card running\n"); 187 writeb(PCITpBootFromRam | PCITpBusEnable | HostP->Mode, &HostP->Control); 188 break; 189 default: 190 rio_dprintk(RIO_DEBUG_BOOT, "Unknown host type %d\n", HostP->Type); 191 break; 192 } 193 return; 194} 195 196/* 197** Load in the host boot code - load it directly onto all halted hosts 198** of the correct type. 199** 200** Put your rubber pants on before messing with this code - even the magic 201** numbers have trouble understanding what they are doing here. 202*/ 203 204int RIOBootCodeHOST(struct rio_info *p, struct DownLoad *rbp) 205{ 206 struct Host *HostP; 207 u8 __iomem *Cad; 208 PARM_MAP __iomem *ParmMapP; 209 int RupN; 210 int PortN; 211 unsigned int host; 212 u8 __iomem *StartP; 213 u8 __iomem *DestP; 214 int wait_count; 215 u16 OldParmMap; 216 u16 offset; /* It is very important that this is a u16 */ 217 u8 *DownCode = NULL; 218 unsigned long flags; 219 220 HostP = NULL; /* Assure the compiler we've initialized it */ 221 222 223 /* Walk the hosts */ 224 for (host = 0; host < p->RIONumHosts; host++) { 225 rio_dprintk(RIO_DEBUG_BOOT, "Attempt to boot host %d\n", host); 226 HostP = &p->RIOHosts[host]; 227 228 rio_dprintk(RIO_DEBUG_BOOT, "Host Type = 0x%x, Mode = 0x%x, IVec = 0x%x\n", HostP->Type, HostP->Mode, HostP->Ivec); 229 230 /* Don't boot hosts already running */ 231 if ((HostP->Flags & RUN_STATE) != RC_WAITING) { 232 rio_dprintk(RIO_DEBUG_BOOT, "%s %d already running\n", "Host", host); 233 continue; 234 } 235 236 /* 237 ** Grab a pointer to the card (ioremapped) 238 */ 239 Cad = HostP->Caddr; 240 241 /* 242 ** We are going to (try) and load in rbp->Count bytes. 243 ** The last byte will reside at p->RIOConf.HostLoadBase-1; 244 ** Therefore, we need to start copying at address 245 ** (caddr+p->RIOConf.HostLoadBase-rbp->Count) 246 */ 247 StartP = &Cad[p->RIOConf.HostLoadBase - rbp->Count]; 248 249 rio_dprintk(RIO_DEBUG_BOOT, "kernel virtual address for host is %p\n", Cad); 250 rio_dprintk(RIO_DEBUG_BOOT, "kernel virtual address for download is %p\n", StartP); 251 rio_dprintk(RIO_DEBUG_BOOT, "host loadbase is 0x%x\n", p->RIOConf.HostLoadBase); 252 rio_dprintk(RIO_DEBUG_BOOT, "size of download is 0x%x\n", rbp->Count); 253 254 /* Make sure it fits */ 255 if (p->RIOConf.HostLoadBase < rbp->Count) { 256 rio_dprintk(RIO_DEBUG_BOOT, "Bin too large\n"); 257 p->RIOError.Error = HOST_FILE_TOO_LARGE; 258 func_exit(); 259 return -EFBIG; 260 } 261 /* 262 ** Ensure that the host really is stopped. 263 ** Disable it's external bus & twang its reset line. 264 */ 265 RIOHostReset(HostP->Type, HostP->CardP, HostP->Slot); 266 267 /* 268 ** Copy the data directly from user space to the SRAM. 269 ** This ain't going to be none too clever if the download 270 ** code is bigger than this segment. 271 */ 272 rio_dprintk(RIO_DEBUG_BOOT, "Copy in code\n"); 273 274 /* Buffer to local memory as we want to use I/O space and 275 some cards only do 8 or 16 bit I/O */ 276 277 DownCode = vmalloc(rbp->Count); 278 if (!DownCode) { 279 p->RIOError.Error = NOT_ENOUGH_CORE_FOR_PCI_COPY; 280 func_exit(); 281 return -ENOMEM; 282 } 283 if (copy_from_user(DownCode, rbp->DataP, rbp->Count)) { 284 kfree(DownCode); 285 p->RIOError.Error = COPYIN_FAILED; 286 func_exit(); 287 return -EFAULT; 288 } 289 HostP->Copy(DownCode, StartP, rbp->Count); 290 vfree(DownCode); 291 292 rio_dprintk(RIO_DEBUG_BOOT, "Copy completed\n"); 293 294 /* 295 ** S T O P ! 296 ** 297 ** Upto this point the code has been fairly rational, and possibly 298 ** even straight forward. What follows is a pile of crud that will 299 ** magically turn into six bytes of transputer assembler. Normally 300 ** you would expect an array or something, but, being me, I have 301 ** chosen [been told] to use a technique whereby the startup code 302 ** will be correct if we change the loadbase for the code. Which 303 ** brings us onto another issue - the loadbase is the *end* of the 304 ** code, not the start. 305 ** 306 ** If I were you I wouldn't start from here. 307 */ 308 309 /* 310 ** We now need to insert a short boot section into 311 ** the memory at the end of Sram2. This is normally (de)composed 312 ** of the last eight bytes of the download code. The 313 ** download has been assembled/compiled to expect to be 314 ** loaded from 0x7FFF downwards. We have loaded it 315 ** at some other address. The startup code goes into the small 316 ** ram window at Sram2, in the last 8 bytes, which are really 317 ** at addresses 0x7FF8-0x7FFF. 318 ** 319 ** If the loadbase is, say, 0x7C00, then we need to branch to 320 ** address 0x7BFE to run the host.bin startup code. We assemble 321 ** this jump manually. 322 ** 323 ** The two byte sequence 60 08 is loaded into memory at address 324 ** 0x7FFE,F. This is a local branch to location 0x7FF8 (60 is nfix 0, 325 ** which adds '0' to the .O register, complements .O, and then shifts 326 ** it left by 4 bit positions, 08 is a jump .O+8 instruction. This will 327 ** add 8 to .O (which was 0xFFF0), and will branch RELATIVE to the new 328 ** location. Now, the branch starts from the value of .PC (or .IP or 329 ** whatever the bloody register is called on this chip), and the .PC 330 ** will be pointing to the location AFTER the branch, in this case 331 ** .PC == 0x8000, so the branch will be to 0x8000+0xFFF8 = 0x7FF8. 332 ** 333 ** A long branch is coded at 0x7FF8. This consists of loading a four 334 ** byte offset into .O using nfix (as above) and pfix operators. The 335 ** pfix operates in exactly the same way as the nfix operator, but 336 ** without the complement operation. The offset, of course, must be 337 ** relative to the address of the byte AFTER the branch instruction, 338 ** which will be (urm) 0x7FFC, so, our final destination of the branch 339 ** (loadbase-2), has to be reached from here. Imagine that the loadbase 340 ** is 0x7C00 (which it is), then we will need to branch to 0x7BFE (which 341 ** is the first byte of the initial two byte short local branch of the 342 ** download code). 343 ** 344 ** To code a jump from 0x7FFC (which is where the branch will start 345 ** from) to 0x7BFE, we will need to branch 0xFC02 bytes (0x7FFC+0xFC02)= 346 ** 0x7BFE. 347 ** This will be coded as four bytes: 348 ** 60 2C 20 02 349 ** being nfix .O+0 350 ** pfix .O+C 351 ** pfix .O+0 352 ** jump .O+2 353 ** 354 ** The nfix operator is used, so that the startup code will be 355 ** compatible with the whole Tp family. (lies, damn lies, it'll never 356 ** work in a month of Sundays). 357 ** 358 ** The nfix nyble is the 1s complement of the nyble value you 359 ** want to load - in this case we wanted 'F' so we nfix loaded '0'. 360 */ 361 362 363 /* 364 ** Dest points to the top 8 bytes of Sram2. The Tp jumps 365 ** to 0x7FFE at reset time, and starts executing. This is 366 ** a short branch to 0x7FF8, where a long branch is coded. 367 */ 368 369 DestP = &Cad[0x7FF8]; /* <<<---- READ THE ABOVE COMMENTS */ 370 371#define NFIX(N) (0x60 | (N)) /* .O = (~(.O + N))<<4 */ 372#define PFIX(N) (0x20 | (N)) /* .O = (.O + N)<<4 */ 373#define JUMP(N) (0x00 | (N)) /* .PC = .PC + .O */ 374 375 /* 376 ** 0x7FFC is the address of the location following the last byte of 377 ** the four byte jump instruction. 378 ** READ THE ABOVE COMMENTS 379 ** 380 ** offset is (TO-FROM) % MEMSIZE, but with compound buggering about. 381 ** Memsize is 64K for this range of Tp, so offset is a short (unsigned, 382 ** cos I don't understand 2's complement). 383 */ 384 offset = (p->RIOConf.HostLoadBase - 2) - 0x7FFC; 385 386 writeb(NFIX(((unsigned short) (~offset) >> (unsigned short) 12) & 0xF), DestP); 387 writeb(PFIX((offset >> 8) & 0xF), DestP + 1); 388 writeb(PFIX((offset >> 4) & 0xF), DestP + 2); 389 writeb(JUMP(offset & 0xF), DestP + 3); 390 391 writeb(NFIX(0), DestP + 6); 392 writeb(JUMP(8), DestP + 7); 393 394 rio_dprintk(RIO_DEBUG_BOOT, "host loadbase is 0x%x\n", p->RIOConf.HostLoadBase); 395 rio_dprintk(RIO_DEBUG_BOOT, "startup offset is 0x%x\n", offset); 396 397 /* 398 ** Flag what is going on 399 */ 400 HostP->Flags &= ~RUN_STATE; 401 HostP->Flags |= RC_STARTUP; 402 403 /* 404 ** Grab a copy of the current ParmMap pointer, so we 405 ** can tell when it has changed. 406 */ 407 OldParmMap = readw(&HostP->__ParmMapR); 408 409 rio_dprintk(RIO_DEBUG_BOOT, "Original parmmap is 0x%x\n", OldParmMap); 410 411 /* 412 ** And start it running (I hope). 413 ** As there is nothing dodgy or obscure about the 414 ** above code, this is guaranteed to work every time. 415 */ 416 rio_dprintk(RIO_DEBUG_BOOT, "Host Type = 0x%x, Mode = 0x%x, IVec = 0x%x\n", HostP->Type, HostP->Mode, HostP->Ivec); 417 418 rio_start_card_running(HostP); 419 420 rio_dprintk(RIO_DEBUG_BOOT, "Set control port\n"); 421 422 /* 423 ** Now, wait for upto five seconds for the Tp to setup the parmmap 424 ** pointer: 425 */ 426 for (wait_count = 0; (wait_count < p->RIOConf.StartupTime) && (readw(&HostP->__ParmMapR) == OldParmMap); wait_count++) { 427 rio_dprintk(RIO_DEBUG_BOOT, "Checkout %d, 0x%x\n", wait_count, readw(&HostP->__ParmMapR)); 428 mdelay(100); 429 430 } 431 432 /* 433 ** If the parmmap pointer is unchanged, then the host code 434 ** has crashed & burned in a really spectacular way 435 */ 436 if (readw(&HostP->__ParmMapR) == OldParmMap) { 437 rio_dprintk(RIO_DEBUG_BOOT, "parmmap 0x%x\n", readw(&HostP->__ParmMapR)); 438 rio_dprintk(RIO_DEBUG_BOOT, "RIO Mesg Run Fail\n"); 439 HostP->Flags &= ~RUN_STATE; 440 HostP->Flags |= RC_STUFFED; 441 RIOHostReset( HostP->Type, HostP->CardP, HostP->Slot ); 442 continue; 443 } 444 445 rio_dprintk(RIO_DEBUG_BOOT, "Running 0x%x\n", readw(&HostP->__ParmMapR)); 446 447 /* 448 ** Well, the board thought it was OK, and setup its parmmap 449 ** pointer. For the time being, we will pretend that this 450 ** board is running, and check out what the error flag says. 451 */ 452 453 /* 454 ** Grab a 32 bit pointer to the parmmap structure 455 */ 456 ParmMapP = (PARM_MAP __iomem *) RIO_PTR(Cad, readw(&HostP->__ParmMapR)); 457 rio_dprintk(RIO_DEBUG_BOOT, "ParmMapP : %p\n", ParmMapP); 458 ParmMapP = (PARM_MAP __iomem *)(Cad + readw(&HostP->__ParmMapR)); 459 rio_dprintk(RIO_DEBUG_BOOT, "ParmMapP : %p\n", ParmMapP); 460 461 /* 462 ** The links entry should be 0xFFFF; we set it up 463 ** with a mask to say how many PHBs to use, and 464 ** which links to use. 465 */ 466 if (readw(&ParmMapP->links) != 0xFFFF) { 467 rio_dprintk(RIO_DEBUG_BOOT, "RIO Mesg Run Fail %s\n", HostP->Name); 468 rio_dprintk(RIO_DEBUG_BOOT, "Links = 0x%x\n", readw(&ParmMapP->links)); 469 HostP->Flags &= ~RUN_STATE; 470 HostP->Flags |= RC_STUFFED; 471 RIOHostReset( HostP->Type, HostP->CardP, HostP->Slot ); 472 continue; 473 } 474 475 writew(RIO_LINK_ENABLE, &ParmMapP->links); 476 477 /* 478 ** now wait for the card to set all the parmmap->XXX stuff 479 ** this is a wait of upto two seconds.... 480 */ 481 rio_dprintk(RIO_DEBUG_BOOT, "Looking for init_done - %d ticks\n", p->RIOConf.StartupTime); 482 HostP->timeout_id = 0; 483 for (wait_count = 0; (wait_count < p->RIOConf.StartupTime) && !readw(&ParmMapP->init_done); wait_count++) { 484 rio_dprintk(RIO_DEBUG_BOOT, "Waiting for init_done\n"); 485 mdelay(100); 486 } 487 rio_dprintk(RIO_DEBUG_BOOT, "OK! init_done!\n"); 488 489 if (readw(&ParmMapP->error) != E_NO_ERROR || !readw(&ParmMapP->init_done)) { 490 rio_dprintk(RIO_DEBUG_BOOT, "RIO Mesg Run Fail %s\n", HostP->Name); 491 rio_dprintk(RIO_DEBUG_BOOT, "Timedout waiting for init_done\n"); 492 HostP->Flags &= ~RUN_STATE; 493 HostP->Flags |= RC_STUFFED; 494 RIOHostReset( HostP->Type, HostP->CardP, HostP->Slot ); 495 continue; 496 } 497 498 rio_dprintk(RIO_DEBUG_BOOT, "Got init_done\n"); 499 500 /* 501 ** It runs! It runs! 502 */ 503 rio_dprintk(RIO_DEBUG_BOOT, "Host ID %x Running\n", HostP->UniqueNum); 504 505 /* 506 ** set the time period between interrupts. 507 */ 508 writew(p->RIOConf.Timer, &ParmMapP->timer); 509 510 /* 511 ** Translate all the 16 bit pointers in the __ParmMapR into 512 ** 32 bit pointers for the driver in ioremap space. 513 */ 514 HostP->ParmMapP = ParmMapP; 515 HostP->PhbP = (struct PHB __iomem *) RIO_PTR(Cad, readw(&ParmMapP->phb_ptr)); 516 HostP->RupP = (struct RUP __iomem *) RIO_PTR(Cad, readw(&ParmMapP->rups)); 517 HostP->PhbNumP = (unsigned short __iomem *) RIO_PTR(Cad, readw(&ParmMapP->phb_num_ptr)); 518 HostP->LinkStrP = (struct LPB __iomem *) RIO_PTR(Cad, readw(&ParmMapP->link_str_ptr)); 519 520 /* 521 ** point the UnixRups at the real Rups 522 */ 523 for (RupN = 0; RupN < MAX_RUP; RupN++) { 524 HostP->UnixRups[RupN].RupP = &HostP->RupP[RupN]; 525 HostP->UnixRups[RupN].Id = RupN + 1; 526 HostP->UnixRups[RupN].BaseSysPort = NO_PORT; 527 spin_lock_init(&HostP->UnixRups[RupN].RupLock); 528 } 529 530 for (RupN = 0; RupN < LINKS_PER_UNIT; RupN++) { 531 HostP->UnixRups[RupN + MAX_RUP].RupP = &HostP->LinkStrP[RupN].rup; 532 HostP->UnixRups[RupN + MAX_RUP].Id = 0; 533 HostP->UnixRups[RupN + MAX_RUP].BaseSysPort = NO_PORT; 534 spin_lock_init(&HostP->UnixRups[RupN + MAX_RUP].RupLock); 535 } 536 537 /* 538 ** point the PortP->Phbs at the real Phbs 539 */ 540 for (PortN = p->RIOFirstPortsMapped; PortN < p->RIOLastPortsMapped + PORTS_PER_RTA; PortN++) { 541 if (p->RIOPortp[PortN]->HostP == HostP) { 542 struct Port *PortP = p->RIOPortp[PortN]; 543 struct PHB __iomem *PhbP; 544 /* int oldspl; */ 545 546 if (!PortP->Mapped) 547 continue; 548 549 PhbP = &HostP->PhbP[PortP->HostPort]; 550 rio_spin_lock_irqsave(&PortP->portSem, flags); 551 552 PortP->PhbP = PhbP; 553 554 PortP->TxAdd = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->tx_add)); 555 PortP->TxStart = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->tx_start)); 556 PortP->TxEnd = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->tx_end)); 557 PortP->RxRemove = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->rx_remove)); 558 PortP->RxStart = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->rx_start)); 559 PortP->RxEnd = (u16 __iomem *) RIO_PTR(Cad, readw(&PhbP->rx_end)); 560 561 rio_spin_unlock_irqrestore(&PortP->portSem, flags); 562 /* 563 ** point the UnixRup at the base SysPort 564 */ 565 if (!(PortN % PORTS_PER_RTA)) 566 HostP->UnixRups[PortP->RupNum].BaseSysPort = PortN; 567 } 568 } 569 570 rio_dprintk(RIO_DEBUG_BOOT, "Set the card running... \n"); 571 /* 572 ** last thing - show the world that everything is in place 573 */ 574 HostP->Flags &= ~RUN_STATE; 575 HostP->Flags |= RC_RUNNING; 576 } 577 /* 578 ** MPX always uses a poller. This is actually patched into the system 579 ** configuration and called directly from each clock tick. 580 ** 581 */ 582 p->RIOPolling = 1; 583 584 p->RIOSystemUp++; 585 586 rio_dprintk(RIO_DEBUG_BOOT, "Done everything %x\n", HostP->Ivec); 587 func_exit(); 588 return 0; 589} 590 591 592 593/** 594 * RIOBootRup - Boot an RTA 595 * @p: rio we are working with 596 * @Rup: Rup number 597 * @HostP: host object 598 * @PacketP: packet to use 599 * 600 * If we have successfully processed this boot, then 601 * return 1. If we havent, then return 0. 602 */ 603 604int RIOBootRup(struct rio_info *p, unsigned int Rup, struct Host *HostP, struct PKT __iomem *PacketP) 605{ 606 struct PktCmd __iomem *PktCmdP = (struct PktCmd __iomem *) PacketP->data; 607 struct PktCmd_M *PktReplyP; 608 struct CmdBlk *CmdBlkP; 609 unsigned int sequence; 610 611 /* 612 ** If we haven't been told what to boot, we can't boot it. 613 */ 614 if (p->RIONumBootPkts == 0) { 615 rio_dprintk(RIO_DEBUG_BOOT, "No RTA code to download yet\n"); 616 return 0; 617 } 618 619 /* 620 ** Special case of boot completed - if we get one of these then we 621 ** don't need a command block. For all other cases we do, so handle 622 ** this first and then get a command block, then handle every other 623 ** case, relinquishing the command block if disaster strikes! 624 */ 625 if ((readb(&PacketP->len) & PKT_CMD_BIT) && (readb(&PktCmdP->Command) == BOOT_COMPLETED)) 626 return RIOBootComplete(p, HostP, Rup, PktCmdP); 627 628 /* 629 ** Try to allocate a command block. This is in kernel space 630 */ 631 if (!(CmdBlkP = RIOGetCmdBlk())) { 632 rio_dprintk(RIO_DEBUG_BOOT, "No command blocks to boot RTA! come back later.\n"); 633 return 0; 634 } 635 636 /* 637 ** Fill in the default info on the command block 638 */ 639 CmdBlkP->Packet.dest_unit = Rup < (unsigned short) MAX_RUP ? Rup : 0; 640 CmdBlkP->Packet.dest_port = BOOT_RUP; 641 CmdBlkP->Packet.src_unit = 0; 642 CmdBlkP->Packet.src_port = BOOT_RUP; 643 644 CmdBlkP->PreFuncP = CmdBlkP->PostFuncP = NULL; 645 PktReplyP = (struct PktCmd_M *) CmdBlkP->Packet.data; 646 647 /* 648 ** process COMMANDS on the boot rup! 649 */ 650 if (readb(&PacketP->len) & PKT_CMD_BIT) { 651 /* 652 ** We only expect one type of command - a BOOT_REQUEST! 653 */ 654 if (readb(&PktCmdP->Command) != BOOT_REQUEST) { 655 rio_dprintk(RIO_DEBUG_BOOT, "Unexpected command %d on BOOT RUP %d of host %Zd\n", readb(&PktCmdP->Command), Rup, HostP - p->RIOHosts); 656 RIOFreeCmdBlk(CmdBlkP); 657 return 1; 658 } 659 660 /* 661 ** Build a Boot Sequence command block 662 ** 663 ** We no longer need to use "Boot Mode", we'll always allow 664 ** boot requests - the boot will not complete if the device 665 ** appears in the bindings table. 666 ** 667 ** We'll just (always) set the command field in packet reply 668 ** to allow an attempted boot sequence : 669 */ 670 PktReplyP->Command = BOOT_SEQUENCE; 671 672 PktReplyP->BootSequence.NumPackets = p->RIONumBootPkts; 673 PktReplyP->BootSequence.LoadBase = p->RIOConf.RtaLoadBase; 674 PktReplyP->BootSequence.CodeSize = p->RIOBootCount; 675 676 CmdBlkP->Packet.len = BOOT_SEQUENCE_LEN | PKT_CMD_BIT; 677 678 memcpy((void *) &CmdBlkP->Packet.data[BOOT_SEQUENCE_LEN], "BOOT", 4); 679 680 rio_dprintk(RIO_DEBUG_BOOT, "Boot RTA on Host %Zd Rup %d - %d (0x%x) packets to 0x%x\n", HostP - p->RIOHosts, Rup, p->RIONumBootPkts, p->RIONumBootPkts, p->RIOConf.RtaLoadBase); 681 682 /* 683 ** If this host is in slave mode, send the RTA an invalid boot 684 ** sequence command block to force it to kill the boot. We wait 685 ** for half a second before sending this packet to prevent the RTA 686 ** attempting to boot too often. The master host should then grab 687 ** the RTA and make it its own. 688 */ 689 p->RIOBooting++; 690 RIOQueueCmdBlk(HostP, Rup, CmdBlkP); 691 return 1; 692 } 693 694 /* 695 ** It is a request for boot data. 696 */ 697 sequence = readw(&PktCmdP->Sequence); 698 699 rio_dprintk(RIO_DEBUG_BOOT, "Boot block %d on Host %Zd Rup%d\n", sequence, HostP - p->RIOHosts, Rup); 700 701 if (sequence >= p->RIONumBootPkts) { 702 rio_dprintk(RIO_DEBUG_BOOT, "Got a request for packet %d, max is %d\n", sequence, p->RIONumBootPkts); 703 } 704 705 PktReplyP->Sequence = sequence; 706 memcpy(PktReplyP->BootData, p->RIOBootPackets[p->RIONumBootPkts - sequence - 1], RTA_BOOT_DATA_SIZE); 707 CmdBlkP->Packet.len = PKT_MAX_DATA_LEN; 708 RIOQueueCmdBlk(HostP, Rup, CmdBlkP); 709 return 1; 710} 711 712/** 713 * RIOBootComplete - RTA boot is done 714 * @p: RIO we are working with 715 * @HostP: Host structure 716 * @Rup: RUP being used 717 * @PktCmdP: Packet command that was used 718 * 719 * This function is called when an RTA been booted. 720 * If booted by a host, HostP->HostUniqueNum is the booting host. 721 * If booted by an RTA, HostP->Mapping[Rup].RtaUniqueNum is the booting RTA. 722 * RtaUniq is the booted RTA. 723 */ 724 725static int RIOBootComplete(struct rio_info *p, struct Host *HostP, unsigned int Rup, struct PktCmd __iomem *PktCmdP) 726{ 727 struct Map *MapP = NULL; 728 struct Map *MapP2 = NULL; 729 int Flag; 730 int found; 731 int host, rta; 732 int EmptySlot = -1; 733 int entry, entry2; 734 char *MyType, *MyName; 735 unsigned int MyLink; 736 unsigned short RtaType; 737 u32 RtaUniq = (readb(&PktCmdP->UniqNum[0])) + (readb(&PktCmdP->UniqNum[1]) << 8) + (readb(&PktCmdP->UniqNum[2]) << 16) + (readb(&PktCmdP->UniqNum[3]) << 24); 738 739 p->RIOBooting = 0; 740 741 rio_dprintk(RIO_DEBUG_BOOT, "RTA Boot completed - BootInProgress now %d\n", p->RIOBooting); 742 743 /* 744 ** Determine type of unit (16/8 port RTA). 745 */ 746 747 RtaType = GetUnitType(RtaUniq); 748 if (Rup >= (unsigned short) MAX_RUP) 749 rio_dprintk(RIO_DEBUG_BOOT, "RIO: Host %s has booted an RTA(%d) on link %c\n", HostP->Name, 8 * RtaType, readb(&PktCmdP->LinkNum) + 'A'); 750 else 751 rio_dprintk(RIO_DEBUG_BOOT, "RIO: RTA %s has booted an RTA(%d) on link %c\n", HostP->Mapping[Rup].Name, 8 * RtaType, readb(&PktCmdP->LinkNum) + 'A'); 752 753 rio_dprintk(RIO_DEBUG_BOOT, "UniqNum is 0x%x\n", RtaUniq); 754 755 if (RtaUniq == 0x00000000 || RtaUniq == 0xffffffff) { 756 rio_dprintk(RIO_DEBUG_BOOT, "Illegal RTA Uniq Number\n"); 757 return 1; 758 } 759 760 /* 761 ** If this RTA has just booted an RTA which doesn't belong to this 762 ** system, or the system is in slave mode, do not attempt to create 763 ** a new table entry for it. 764 */ 765 766 if (!RIOBootOk(p, HostP, RtaUniq)) { 767 MyLink = readb(&PktCmdP->LinkNum); 768 if (Rup < (unsigned short) MAX_RUP) { 769 /* 770 ** RtaUniq was clone booted (by this RTA). Instruct this RTA 771 ** to hold off further attempts to boot on this link for 30 772 ** seconds. 773 */ 774 if (RIOSuspendBootRta(HostP, HostP->Mapping[Rup].ID, MyLink)) { 775 rio_dprintk(RIO_DEBUG_BOOT, "RTA failed to suspend booting on link %c\n", 'A' + MyLink); 776 } 777 } else 778 /* 779 ** RtaUniq was booted by this host. Set the booting link 780 ** to hold off for 30 seconds to give another unit a 781 ** chance to boot it. 782 */ 783 writew(30, &HostP->LinkStrP[MyLink].WaitNoBoot); 784 rio_dprintk(RIO_DEBUG_BOOT, "RTA %x not owned - suspend booting down link %c on unit %x\n", RtaUniq, 'A' + MyLink, HostP->Mapping[Rup].RtaUniqueNum); 785 return 1; 786 } 787 788 /* 789 ** Check for a SLOT_IN_USE entry for this RTA attached to the 790 ** current host card in the driver table. 791 ** 792 ** If it exists, make a note that we have booted it. Other parts of 793 ** the driver are interested in this information at a later date, 794 ** in particular when the booting RTA asks for an ID for this unit, 795 ** we must have set the BOOTED flag, and the NEWBOOT flag is used 796 ** to force an open on any ports that where previously open on this 797 ** unit. 798 */ 799 for (entry = 0; entry < MAX_RUP; entry++) { 800 unsigned int sysport; 801 802 if ((HostP->Mapping[entry].Flags & SLOT_IN_USE) && (HostP->Mapping[entry].RtaUniqueNum == RtaUniq)) { 803 HostP->Mapping[entry].Flags |= RTA_BOOTED | RTA_NEWBOOT; 804 if ((sysport = HostP->Mapping[entry].SysPort) != NO_PORT) { 805 if (sysport < p->RIOFirstPortsBooted) 806 p->RIOFirstPortsBooted = sysport; 807 if (sysport > p->RIOLastPortsBooted) 808 p->RIOLastPortsBooted = sysport; 809 /* 810 ** For a 16 port RTA, check the second bank of 8 ports 811 */ 812 if (RtaType == TYPE_RTA16) { 813 entry2 = HostP->Mapping[entry].ID2 - 1; 814 HostP->Mapping[entry2].Flags |= RTA_BOOTED | RTA_NEWBOOT; 815 sysport = HostP->Mapping[entry2].SysPort; 816 if (sysport < p->RIOFirstPortsBooted) 817 p->RIOFirstPortsBooted = sysport; 818 if (sysport > p->RIOLastPortsBooted) 819 p->RIOLastPortsBooted = sysport; 820 } 821 } 822 if (RtaType == TYPE_RTA16) 823 rio_dprintk(RIO_DEBUG_BOOT, "RTA will be given IDs %d+%d\n", entry + 1, entry2 + 1); 824 else 825 rio_dprintk(RIO_DEBUG_BOOT, "RTA will be given ID %d\n", entry + 1); 826 return 1; 827 } 828 } 829 830 rio_dprintk(RIO_DEBUG_BOOT, "RTA not configured for this host\n"); 831 832 if (Rup >= (unsigned short) MAX_RUP) { 833 /* 834 ** It was a host that did the booting 835 */ 836 MyType = "Host"; 837 MyName = HostP->Name; 838 } else { 839 /* 840 ** It was an RTA that did the booting 841 */ 842 MyType = "RTA"; 843 MyName = HostP->Mapping[Rup].Name; 844 } 845 MyLink = readb(&PktCmdP->LinkNum); 846 847 /* 848 ** There is no SLOT_IN_USE entry for this RTA attached to the current 849 ** host card in the driver table. 850 ** 851 ** Check for a SLOT_TENTATIVE entry for this RTA attached to the 852 ** current host card in the driver table. 853 ** 854 ** If we find one, then we re-use that slot. 855 */ 856 for (entry = 0; entry < MAX_RUP; entry++) { 857 if ((HostP->Mapping[entry].Flags & SLOT_TENTATIVE) && (HostP->Mapping[entry].RtaUniqueNum == RtaUniq)) { 858 if (RtaType == TYPE_RTA16) { 859 entry2 = HostP->Mapping[entry].ID2 - 1; 860 if ((HostP->Mapping[entry2].Flags & SLOT_TENTATIVE) && (HostP->Mapping[entry2].RtaUniqueNum == RtaUniq)) 861 rio_dprintk(RIO_DEBUG_BOOT, "Found previous tentative slots (%d+%d)\n", entry, entry2); 862 else 863 continue; 864 } else 865 rio_dprintk(RIO_DEBUG_BOOT, "Found previous tentative slot (%d)\n", entry); 866 if (!p->RIONoMessage) 867 printk("RTA connected to %s '%s' (%c) not configured.\n", MyType, MyName, MyLink + 'A'); 868 return 1; 869 } 870 } 871 872 /* 873 ** There is no SLOT_IN_USE or SLOT_TENTATIVE entry for this RTA 874 ** attached to the current host card in the driver table. 875 ** 876 ** Check if there is a SLOT_IN_USE or SLOT_TENTATIVE entry on another 877 ** host for this RTA in the driver table. 878 ** 879 ** For a SLOT_IN_USE entry on another host, we need to delete the RTA 880 ** entry from the other host and add it to this host (using some of 881 ** the functions from table.c which do this). 882 ** For a SLOT_TENTATIVE entry on another host, we must cope with the 883 ** following scenario: 884 ** 885 ** + Plug 8 port RTA into host A. (This creates SLOT_TENTATIVE entry 886 ** in table) 887 ** + Unplug RTA and plug into host B. (We now have 2 SLOT_TENTATIVE 888 ** entries) 889 ** + Configure RTA on host B. (This slot now becomes SLOT_IN_USE) 890 ** + Unplug RTA and plug back into host A. 891 ** + Configure RTA on host A. We now have the same RTA configured 892 ** with different ports on two different hosts. 893 */ 894 rio_dprintk(RIO_DEBUG_BOOT, "Have we seen RTA %x before?\n", RtaUniq); 895 found = 0; 896 Flag = 0; /* Convince the compiler this variable is initialized */ 897 for (host = 0; !found && (host < p->RIONumHosts); host++) { 898 for (rta = 0; rta < MAX_RUP; rta++) { 899 if ((p->RIOHosts[host].Mapping[rta].Flags & (SLOT_IN_USE | SLOT_TENTATIVE)) && (p->RIOHosts[host].Mapping[rta].RtaUniqueNum == RtaUniq)) { 900 Flag = p->RIOHosts[host].Mapping[rta].Flags; 901 MapP = &p->RIOHosts[host].Mapping[rta]; 902 if (RtaType == TYPE_RTA16) { 903 MapP2 = &p->RIOHosts[host].Mapping[MapP->ID2 - 1]; 904 rio_dprintk(RIO_DEBUG_BOOT, "This RTA is units %d+%d from host %s\n", rta + 1, MapP->ID2, p->RIOHosts[host].Name); 905 } else 906 rio_dprintk(RIO_DEBUG_BOOT, "This RTA is unit %d from host %s\n", rta + 1, p->RIOHosts[host].Name); 907 found = 1; 908 break; 909 } 910 } 911 } 912 913 /* 914 ** There is no SLOT_IN_USE or SLOT_TENTATIVE entry for this RTA 915 ** attached to the current host card in the driver table. 916 ** 917 ** If we have not found a SLOT_IN_USE or SLOT_TENTATIVE entry on 918 ** another host for this RTA in the driver table... 919 ** 920 ** Check for a SLOT_IN_USE entry for this RTA in the config table. 921 */ 922 if (!MapP) { 923 rio_dprintk(RIO_DEBUG_BOOT, "Look for RTA %x in RIOSavedTable\n", RtaUniq); 924 for (rta = 0; rta < TOTAL_MAP_ENTRIES; rta++) { 925 rio_dprintk(RIO_DEBUG_BOOT, "Check table entry %d (%x)", rta, p->RIOSavedTable[rta].RtaUniqueNum); 926 927 if ((p->RIOSavedTable[rta].Flags & SLOT_IN_USE) && (p->RIOSavedTable[rta].RtaUniqueNum == RtaUniq)) { 928 MapP = &p->RIOSavedTable[rta]; 929 Flag = p->RIOSavedTable[rta].Flags; 930 if (RtaType == TYPE_RTA16) { 931 for (entry2 = rta + 1; entry2 < TOTAL_MAP_ENTRIES; entry2++) { 932 if (p->RIOSavedTable[entry2].RtaUniqueNum == RtaUniq) 933 break; 934 } 935 MapP2 = &p->RIOSavedTable[entry2]; 936 rio_dprintk(RIO_DEBUG_BOOT, "This RTA is from table entries %d+%d\n", rta, entry2); 937 } else 938 rio_dprintk(RIO_DEBUG_BOOT, "This RTA is from table entry %d\n", rta); 939 break; 940 } 941 } 942 } 943 944 /* 945 ** There is no SLOT_IN_USE or SLOT_TENTATIVE entry for this RTA 946 ** attached to the current host card in the driver table. 947 ** 948 ** We may have found a SLOT_IN_USE entry on another host for this 949 ** RTA in the config table, or a SLOT_IN_USE or SLOT_TENTATIVE entry 950 ** on another host for this RTA in the driver table. 951 ** 952 ** Check the driver table for room to fit this newly discovered RTA. 953 ** RIOFindFreeID() first looks for free slots and if it does not 954 ** find any free slots it will then attempt to oust any 955 ** tentative entry in the table. 956 */ 957 EmptySlot = 1; 958 if (RtaType == TYPE_RTA16) { 959 if (RIOFindFreeID(p, HostP, &entry, &entry2) == 0) { 960 RIODefaultName(p, HostP, entry); 961 rio_fill_host_slot(entry, entry2, RtaUniq, HostP); 962 EmptySlot = 0; 963 } 964 } else { 965 if (RIOFindFreeID(p, HostP, &entry, NULL) == 0) { 966 RIODefaultName(p, HostP, entry); 967 rio_fill_host_slot(entry, 0, RtaUniq, HostP); 968 EmptySlot = 0; 969 } 970 } 971 972 /* 973 ** There is no SLOT_IN_USE or SLOT_TENTATIVE entry for this RTA 974 ** attached to the current host card in the driver table. 975 ** 976 ** If we found a SLOT_IN_USE entry on another host for this 977 ** RTA in the config or driver table, and there are enough free 978 ** slots in the driver table, then we need to move it over and 979 ** delete it from the other host. 980 ** If we found a SLOT_TENTATIVE entry on another host for this 981 ** RTA in the driver table, just delete the other host entry. 982 */ 983 if (EmptySlot == 0) { 984 if (MapP) { 985 if (Flag & SLOT_IN_USE) { 986 rio_dprintk(RIO_DEBUG_BOOT, "This RTA configured on another host - move entry to current host (1)\n"); 987 HostP->Mapping[entry].SysPort = MapP->SysPort; 988 memcpy(HostP->Mapping[entry].Name, MapP->Name, MAX_NAME_LEN); 989 HostP->Mapping[entry].Flags = SLOT_IN_USE | RTA_BOOTED | RTA_NEWBOOT; 990 RIOReMapPorts(p, HostP, &HostP->Mapping[entry]); 991 if (HostP->Mapping[entry].SysPort < p->RIOFirstPortsBooted) 992 p->RIOFirstPortsBooted = HostP->Mapping[entry].SysPort; 993 if (HostP->Mapping[entry].SysPort > p->RIOLastPortsBooted) 994 p->RIOLastPortsBooted = HostP->Mapping[entry].SysPort; 995 rio_dprintk(RIO_DEBUG_BOOT, "SysPort %d, Name %s\n", (int) MapP->SysPort, MapP->Name); 996 } else { 997 rio_dprintk(RIO_DEBUG_BOOT, "This RTA has a tentative entry on another host - delete that entry (1)\n"); 998 HostP->Mapping[entry].Flags = SLOT_TENTATIVE | RTA_BOOTED | RTA_NEWBOOT; 999 } 1000 if (RtaType == TYPE_RTA16) { 1001 if (Flag & SLOT_IN_USE) { 1002 HostP->Mapping[entry2].Flags = SLOT_IN_USE | RTA_BOOTED | RTA_NEWBOOT | RTA16_SECOND_SLOT; 1003 HostP->Mapping[entry2].SysPort = MapP2->SysPort; 1004 /* 1005 ** Map second block of ttys for 16 port RTA 1006 */ 1007 RIOReMapPorts(p, HostP, &HostP->Mapping[entry2]); 1008 if (HostP->Mapping[entry2].SysPort < p->RIOFirstPortsBooted) 1009 p->RIOFirstPortsBooted = HostP->Mapping[entry2].SysPort; 1010 if (HostP->Mapping[entry2].SysPort > p->RIOLastPortsBooted) 1011 p->RIOLastPortsBooted = HostP->Mapping[entry2].SysPort; 1012 rio_dprintk(RIO_DEBUG_BOOT, "SysPort %d, Name %s\n", (int) HostP->Mapping[entry2].SysPort, HostP->Mapping[entry].Name); 1013 } else 1014 HostP->Mapping[entry2].Flags = SLOT_TENTATIVE | RTA_BOOTED | RTA_NEWBOOT | RTA16_SECOND_SLOT; 1015 memset(MapP2, 0, sizeof(struct Map)); 1016 } 1017 memset(MapP, 0, sizeof(struct Map)); 1018 if (!p->RIONoMessage) 1019 printk("An orphaned RTA has been adopted by %s '%s' (%c).\n", MyType, MyName, MyLink + 'A'); 1020 } else if (!p->RIONoMessage) 1021 printk("RTA connected to %s '%s' (%c) not configured.\n", MyType, MyName, MyLink + 'A'); 1022 RIOSetChange(p); 1023 return 1; 1024 } 1025 1026 /* 1027 ** There is no room in the driver table to make an entry for the 1028 ** booted RTA. Keep a note of its Uniq Num in the overflow table, 1029 ** so we can ignore it's ID requests. 1030 */ 1031 if (!p->RIONoMessage) 1032 printk("The RTA connected to %s '%s' (%c) cannot be configured. You cannot configure more than 128 ports to one host card.\n", MyType, MyName, MyLink + 'A'); 1033 for (entry = 0; entry < HostP->NumExtraBooted; entry++) { 1034 if (HostP->ExtraUnits[entry] == RtaUniq) { 1035 /* 1036 ** already got it! 1037 */ 1038 return 1; 1039 } 1040 } 1041 /* 1042 ** If there is room, add the unit to the list of extras 1043 */ 1044 if (HostP->NumExtraBooted < MAX_EXTRA_UNITS) 1045 HostP->ExtraUnits[HostP->NumExtraBooted++] = RtaUniq; 1046 return 1; 1047} 1048 1049 1050/* 1051** If the RTA or its host appears in the RIOBindTab[] structure then 1052** we mustn't boot the RTA and should return 0. 1053** This operation is slightly different from the other drivers for RIO 1054** in that this is designed to work with the new utilities 1055** not config.rio and is FAR SIMPLER. 1056** We no longer support the RIOBootMode variable. It is all done from the 1057** "boot/noboot" field in the rio.cf file. 1058*/ 1059int RIOBootOk(struct rio_info *p, struct Host *HostP, unsigned long RtaUniq) 1060{ 1061 int Entry; 1062 unsigned int HostUniq = HostP->UniqueNum; 1063 1064 /* 1065 ** Search bindings table for RTA or its parent. 1066 ** If it exists, return 0, else 1. 1067 */ 1068 for (Entry = 0; (Entry < MAX_RTA_BINDINGS) && (p->RIOBindTab[Entry] != 0); Entry++) { 1069 if ((p->RIOBindTab[Entry] == HostUniq) || (p->RIOBindTab[Entry] == RtaUniq)) 1070 return 0; 1071 } 1072 return 1; 1073} 1074 1075/* 1076** Make an empty slot tentative. If this is a 16 port RTA, make both 1077** slots tentative, and the second one RTA_SECOND_SLOT as well. 1078*/ 1079 1080void rio_fill_host_slot(int entry, int entry2, unsigned int rta_uniq, struct Host *host) 1081{ 1082 int link; 1083 1084 rio_dprintk(RIO_DEBUG_BOOT, "rio_fill_host_slot(%d, %d, 0x%x...)\n", entry, entry2, rta_uniq); 1085 1086 host->Mapping[entry].Flags = (RTA_BOOTED | RTA_NEWBOOT | SLOT_TENTATIVE); 1087 host->Mapping[entry].SysPort = NO_PORT; 1088 host->Mapping[entry].RtaUniqueNum = rta_uniq; 1089 host->Mapping[entry].HostUniqueNum = host->UniqueNum; 1090 host->Mapping[entry].ID = entry + 1; 1091 host->Mapping[entry].ID2 = 0; 1092 if (entry2) { 1093 host->Mapping[entry2].Flags = (RTA_BOOTED | RTA_NEWBOOT | SLOT_TENTATIVE | RTA16_SECOND_SLOT); 1094 host->Mapping[entry2].SysPort = NO_PORT; 1095 host->Mapping[entry2].RtaUniqueNum = rta_uniq; 1096 host->Mapping[entry2].HostUniqueNum = host->UniqueNum; 1097 host->Mapping[entry2].Name[0] = '\0'; 1098 host->Mapping[entry2].ID = entry2 + 1; 1099 host->Mapping[entry2].ID2 = entry + 1; 1100 host->Mapping[entry].ID2 = entry2 + 1; 1101 } 1102 /* 1103 ** Must set these up, so that utilities show 1104 ** topology of 16 port RTAs correctly 1105 */ 1106 for (link = 0; link < LINKS_PER_UNIT; link++) { 1107 host->Mapping[entry].Topology[link].Unit = ROUTE_DISCONNECT; 1108 host->Mapping[entry].Topology[link].Link = NO_LINK; 1109 if (entry2) { 1110 host->Mapping[entry2].Topology[link].Unit = ROUTE_DISCONNECT; 1111 host->Mapping[entry2].Topology[link].Link = NO_LINK; 1112 } 1113 } 1114}