1 1.35 thorpej /* $NetBSD: if_ie_vme.c,v 1.35 2022/07/12 02:10:16 thorpej Exp $ */ 2 1.1 pk 3 1.29 chuck /* 4 1.1 pk * Copyright (c) 1995 Charles D. Cranor 5 1.1 pk * All rights reserved. 6 1.1 pk * 7 1.1 pk * Redistribution and use in source and binary forms, with or without 8 1.1 pk * modification, are permitted provided that the following conditions 9 1.1 pk * are met: 10 1.1 pk * 1. Redistributions of source code must retain the above copyright 11 1.1 pk * notice, this list of conditions and the following disclaimer. 12 1.1 pk * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 pk * notice, this list of conditions and the following disclaimer in the 14 1.1 pk * documentation and/or other materials provided with the distribution. 15 1.1 pk * 16 1.1 pk * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 1.1 pk * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 1.1 pk * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 1.1 pk * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 1.1 pk * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 21 1.1 pk * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 22 1.1 pk * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 23 1.1 pk * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 24 1.1 pk * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 25 1.1 pk * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 26 1.1 pk */ 27 1.1 pk 28 1.1 pk /* 29 1.1 pk * Converted to SUN ie driver by Charles D. Cranor, 30 1.1 pk * October 1994, January 1995. 31 1.1 pk */ 32 1.1 pk 33 1.1 pk /* 34 1.1 pk * The i82586 is a very painful chip, found in sun3's, sun-4/100's 35 1.1 pk * sun-4/200's, and VME based suns. The byte order is all wrong for a 36 1.1 pk * SUN, making life difficult. Programming this chip is mostly the same, 37 1.1 pk * but certain details differ from system to system. This driver is 38 1.34 andvar * written so that different "ie" interfaces can be controlled by the same 39 1.1 pk * driver. 40 1.1 pk */ 41 1.1 pk 42 1.1 pk /* 43 1.1 pk * programming notes: 44 1.1 pk * 45 1.1 pk * the ie chip operates in a 24 bit address space. 46 1.1 pk * 47 1.1 pk * most ie interfaces appear to be divided into two parts: 48 1.1 pk * - generic 586 stuff 49 1.1 pk * - board specific 50 1.1 pk * 51 1.1 pk * generic: 52 1.1 pk * the generic stuff of the ie chip is all done with data structures 53 1.1 pk * that live in the chip's memory address space. the chip expects 54 1.1 pk * its main data structure (the sys conf ptr -- SCP) to be at a fixed 55 1.1 pk * address in its 24 bit space: 0xfffff4 56 1.1 pk * 57 1.1 pk * the SCP points to another structure called the ISCP. 58 1.1 pk * the ISCP points to another structure called the SCB. 59 1.1 pk * the SCB has a status field, a linked list of "commands", and 60 1.1 pk * a linked list of "receive buffers". these are data structures that 61 1.1 pk * live in memory, not registers. 62 1.1 pk * 63 1.1 pk * board: 64 1.1 pk * to get the chip to do anything, you first put a command in the 65 1.1 pk * command data structure list. then you have to signal "attention" 66 1.1 pk * to the chip to get it to look at the command. how you 67 1.1 pk * signal attention depends on what board you have... on PC's 68 1.1 pk * there is an i/o port number to do this, on sun's there is a 69 1.1 pk * register bit you toggle. 70 1.1 pk * 71 1.1 pk * to get data from the chip you program it to interrupt... 72 1.1 pk * 73 1.1 pk * 74 1.1 pk * sun issues: 75 1.1 pk * 76 1.1 pk * there are 3 kinds of sun "ie" interfaces: 77 1.1 pk * 1 - a VME/multibus card 78 1.1 pk * 2 - an on-board interface (sun3's, sun-4/100's, and sun-4/200's) 79 1.1 pk * 3 - another VME board called the 3E 80 1.1 pk * 81 1.1 pk * the VME boards lives in vme16 space. only 16 and 8 bit accesses 82 1.1 pk * are allowed, so functions that copy data must be aware of this. 83 1.1 pk * 84 1.1 pk * the chip is an intel chip. this means that the byte order 85 1.1 pk * on all the "short"s in the chip's data structures is wrong. 86 1.1 pk * so, constants described in the intel docs are swapped for the sun. 87 1.1 pk * that means that any buffer pointers you give the chip must be 88 1.1 pk * swapped to intel format. yuck. 89 1.1 pk * 90 1.1 pk * VME/multibus interface: 91 1.1 pk * for the multibus interface the board ignores the top 4 bits 92 1.2 pk * of the chip address. the multibus interface has its own 93 1.2 pk * MMU like page map (without protections or valid bits, etc). 94 1.1 pk * there are 256 pages of physical memory on the board (each page 95 1.2 pk * is 1024 bytes). There are 1024 slots in the page map. so, 96 1.1 pk * a 1024 byte page takes up 10 bits of address for the offset, 97 1.1 pk * and if there are 1024 slots in the page that is another 10 bits 98 1.2 pk * of the address. That makes a 20 bit address, and as stated 99 1.1 pk * earlier the board ignores the top 4 bits, so that accounts 100 1.1 pk * for all 24 bits of address. 101 1.1 pk * 102 1.2 pk * Note that the last entry of the page map maps the top of the 103 1.1 pk * 24 bit address space and that the SCP is supposed to be at 104 1.34 andvar * 0xfffff4 (taking into account alignment). so, 105 1.1 pk * for multibus, that entry in the page map has to be used for the SCP. 106 1.1 pk * 107 1.2 pk * The page map effects BOTH how the ie chip sees the 108 1.1 pk * memory, and how the host sees it. 109 1.1 pk * 110 1.2 pk * The page map is part of the "register" area of the board 111 1.2 pk * 112 1.2 pk * The page map to control where ram appears in the address space. 113 1.2 pk * We choose to have RAM start at 0 in the 24 bit address space. 114 1.20 perry * 115 1.34 andvar * to get the physical address of the board's RAM you must take the 116 1.2 pk * top 12 bits of the physical address of the register address and 117 1.2 pk * or in the 4 bits from the status word as bits 17-20 (remember that 118 1.2 pk * the board ignores the chip's top 4 address lines). For example: 119 1.2 pk * if the register is @ 0xffe88000, then the top 12 bits are 0xffe00000. 120 1.8 soren * to get the 4 bits from the status word just do status & IEVME_HADDR. 121 1.2 pk * suppose the value is "4". Then just shift it left 16 bits to get 122 1.2 pk * it into bits 17-20 (e.g. 0x40000). Then or it to get the 123 1.2 pk * address of RAM (in our example: 0xffe40000). see the attach routine! 124 1.2 pk * 125 1.1 pk * 126 1.1 pk * on-board interface: 127 1.1 pk * 128 1.2 pk * on the onboard ie interface the 24 bit address space is hardwired 129 1.2 pk * to be 0xff000000 -> 0xffffffff of KVA. this means that sc_iobase 130 1.2 pk * will be 0xff000000. sc_maddr will be where ever we allocate RAM 131 1.2 pk * in KVA. note that since the SCP is at a fixed address it means 132 1.2 pk * that we have to allocate a fixed KVA for the SCP. 133 1.1 pk * <fill in useful info later> 134 1.1 pk * 135 1.1 pk * 136 1.1 pk * VME3E interface: 137 1.1 pk * 138 1.1 pk * <fill in useful info later> 139 1.1 pk * 140 1.1 pk */ 141 1.14 lukem 142 1.14 lukem #include <sys/cdefs.h> 143 1.35 thorpej __KERNEL_RCSID(0, "$NetBSD: if_ie_vme.c,v 1.35 2022/07/12 02:10:16 thorpej Exp $"); 144 1.1 pk 145 1.1 pk #include <sys/param.h> 146 1.1 pk #include <sys/systm.h> 147 1.1 pk #include <sys/errno.h> 148 1.1 pk #include <sys/device.h> 149 1.1 pk #include <sys/protosw.h> 150 1.1 pk #include <sys/socket.h> 151 1.1 pk 152 1.1 pk #include <net/if.h> 153 1.1 pk #include <net/if_types.h> 154 1.1 pk #include <net/if_dl.h> 155 1.2 pk #include <net/if_media.h> 156 1.1 pk #include <net/if_ether.h> 157 1.1 pk 158 1.23 ad #include <sys/bus.h> 159 1.23 ad #include <sys/intr.h> 160 1.1 pk #include <dev/vme/vmevar.h> 161 1.1 pk 162 1.1 pk #include <dev/ic/i82586reg.h> 163 1.1 pk #include <dev/ic/i82586var.h> 164 1.1 pk 165 1.7 drochner #include "locators.h" 166 1.1 pk 167 1.1 pk /* 168 1.1 pk * VME/multibus definitions 169 1.1 pk */ 170 1.1 pk #define IEVME_PAGESIZE 1024 /* bytes */ 171 1.1 pk #define IEVME_PAGSHIFT 10 /* bits */ 172 1.1 pk #define IEVME_NPAGES 256 /* number of pages on chip */ 173 1.1 pk #define IEVME_MAPSZ 1024 /* number of entries in the map */ 174 1.1 pk 175 1.1 pk /* 176 1.1 pk * PTE for the page map 177 1.1 pk */ 178 1.1 pk #define IEVME_SBORDR 0x8000 /* sun byte order */ 179 1.34 andvar #define IEVME_IBORDR 0x0000 /* intel byte order */ 180 1.1 pk 181 1.1 pk #define IEVME_P2MEM 0x2000 /* memory is on P2 */ 182 1.1 pk #define IEVME_OBMEM 0x0000 /* memory is on board */ 183 1.1 pk 184 1.1 pk #define IEVME_PGMASK 0x0fff /* gives the physical page frame number */ 185 1.1 pk 186 1.1 pk struct ievme { 187 1.32 msaitoh uint16_t pgmap[IEVME_MAPSZ]; 188 1.32 msaitoh uint16_t xxx[32]; /* prom */ 189 1.32 msaitoh uint16_t status; /* see below for bits */ 190 1.32 msaitoh uint16_t xxx2; /* filler */ 191 1.32 msaitoh uint16_t pectrl; /* parity control (see below) */ 192 1.32 msaitoh uint16_t peaddr; /* low 16 bits of address */ 193 1.1 pk }; 194 1.1 pk 195 1.1 pk /* 196 1.1 pk * status bits 197 1.1 pk */ 198 1.1 pk #define IEVME_RESET 0x8000 /* reset board */ 199 1.1 pk #define IEVME_ONAIR 0x4000 /* go out of loopback 'on-air' */ 200 1.1 pk #define IEVME_ATTEN 0x2000 /* attention */ 201 1.1 pk #define IEVME_IENAB 0x1000 /* interrupt enable */ 202 1.1 pk #define IEVME_PEINT 0x0800 /* parity error interrupt enable */ 203 1.1 pk #define IEVME_PERR 0x0200 /* parity error flag */ 204 1.1 pk #define IEVME_INT 0x0100 /* interrupt flag */ 205 1.1 pk #define IEVME_P2EN 0x0020 /* enable p2 bus */ 206 1.1 pk #define IEVME_256K 0x0010 /* 256kb rams */ 207 1.1 pk #define IEVME_HADDR 0x000f /* mask for bits 17-20 of address */ 208 1.1 pk 209 1.1 pk /* 210 1.1 pk * parity control 211 1.1 pk */ 212 1.1 pk #define IEVME_PARACK 0x0100 /* parity error ack */ 213 1.1 pk #define IEVME_PARSRC 0x0080 /* parity error source */ 214 1.1 pk #define IEVME_PAREND 0x0040 /* which end of the data got the error */ 215 1.1 pk #define IEVME_PARADR 0x000f /* mask to get bits 17-20 of parity address */ 216 1.1 pk 217 1.2 pk /* Supported media */ 218 1.2 pk static int media[] = { 219 1.2 pk IFM_ETHER | IFM_10_2, 220 1.20 perry }; 221 1.32 msaitoh #define NMEDIA __arraycount(media) 222 1.1 pk 223 1.1 pk /* 224 1.1 pk * the 3E board not supported (yet?) 225 1.1 pk */ 226 1.1 pk 227 1.1 pk 228 1.19 perry static void ie_vmereset(struct ie_softc *, int); 229 1.19 perry static void ie_vmeattend(struct ie_softc *, int); 230 1.19 perry static void ie_vmerun(struct ie_softc *); 231 1.19 perry static int ie_vmeintr(struct ie_softc *, int); 232 1.1 pk 233 1.27 cegger int ie_vme_match(device_t, cfdata_t, void *); 234 1.27 cegger void ie_vme_attach(device_t, device_t, void *); 235 1.1 pk 236 1.7 drochner struct ie_vme_softc { 237 1.7 drochner struct ie_softc ie; 238 1.7 drochner bus_space_tag_t ievt; 239 1.7 drochner bus_space_handle_t ievh; 240 1.7 drochner }; 241 1.7 drochner 242 1.30 tsutsui CFATTACH_DECL_NEW(ie_vme, sizeof(struct ie_vme_softc), 243 1.17 thorpej ie_vme_match, ie_vme_attach, NULL, NULL); 244 1.1 pk 245 1.7 drochner #define read_iev(sc, reg) \ 246 1.7 drochner bus_space_read_2(sc->ievt, sc->ievh, offsetof(struct ievme, reg)) 247 1.7 drochner #define write_iev(sc, reg, val) \ 248 1.7 drochner bus_space_write_2(sc->ievt, sc->ievh, offsetof(struct ievme, reg), val) 249 1.2 pk 250 1.1 pk /* 251 1.1 pk * MULTIBUS/VME support routines 252 1.1 pk */ 253 1.1 pk void 254 1.25 dsl ie_vmereset(struct ie_softc *sc, int what) 255 1.1 pk { 256 1.7 drochner struct ie_vme_softc *vsc = (struct ie_vme_softc *)sc; 257 1.32 msaitoh 258 1.7 drochner write_iev(vsc, status, IEVME_RESET); 259 1.1 pk delay(100); /* XXX could be shorter? */ 260 1.7 drochner write_iev(vsc, status, 0); 261 1.1 pk } 262 1.1 pk 263 1.1 pk void 264 1.25 dsl ie_vmeattend(struct ie_softc *sc, int why) 265 1.1 pk { 266 1.7 drochner struct ie_vme_softc *vsc = (struct ie_vme_softc *)sc; 267 1.1 pk 268 1.32 msaitoh /* Flag! */ 269 1.7 drochner write_iev(vsc, status, read_iev(vsc, status) | IEVME_ATTEN); 270 1.32 msaitoh /* Down. */ 271 1.7 drochner write_iev(vsc, status, read_iev(vsc, status) & ~IEVME_ATTEN); 272 1.1 pk } 273 1.1 pk 274 1.1 pk void 275 1.25 dsl ie_vmerun(struct ie_softc *sc) 276 1.1 pk { 277 1.7 drochner struct ie_vme_softc *vsc = (struct ie_vme_softc *)sc; 278 1.1 pk 279 1.7 drochner write_iev(vsc, status, read_iev(vsc, status) 280 1.7 drochner | IEVME_ONAIR | IEVME_IENAB | IEVME_PEINT); 281 1.1 pk } 282 1.1 pk 283 1.1 pk int 284 1.25 dsl ie_vmeintr(struct ie_softc *sc, int where) 285 1.1 pk { 286 1.7 drochner struct ie_vme_softc *vsc = (struct ie_vme_softc *)sc; 287 1.1 pk 288 1.2 pk if (where != INTR_ENTER) 289 1.32 msaitoh return 0; 290 1.2 pk 291 1.32 msaitoh /* 292 1.32 msaitoh * check for parity error 293 1.32 msaitoh */ 294 1.7 drochner if (read_iev(vsc, status) & IEVME_PERR) { 295 1.32 msaitoh aprint_error_dev(sc->sc_dev, 296 1.32 msaitoh "parity error (ctrl 0x%x @ 0x%02x%04x)\n", 297 1.32 msaitoh read_iev(vsc, pectrl), 298 1.32 msaitoh read_iev(vsc, pectrl) & IEVME_HADDR, 299 1.32 msaitoh read_iev(vsc, peaddr)); 300 1.7 drochner write_iev(vsc, pectrl, read_iev(vsc, pectrl) | IEVME_PARACK); 301 1.1 pk } 302 1.32 msaitoh return 0; 303 1.1 pk } 304 1.1 pk 305 1.19 perry void ie_memcopyin(struct ie_softc *, void *, int, size_t); 306 1.19 perry void ie_memcopyout(struct ie_softc *, const void *, int, size_t); 307 1.2 pk 308 1.2 pk /* 309 1.2 pk * Copy board memory to kernel. 310 1.2 pk */ 311 1.2 pk void 312 1.25 dsl ie_memcopyin(struct ie_softc *sc, void *p, int offset, size_t size) 313 1.2 pk { 314 1.7 drochner size_t help; 315 1.7 drochner 316 1.7 drochner if ((offset & 1) && ((u_long)p & 1) && size > 0) { 317 1.32 msaitoh *(uint8_t *)p = bus_space_read_1(sc->bt, sc->bh, offset); 318 1.7 drochner offset++; 319 1.32 msaitoh p = (uint8_t *)p + 1; 320 1.7 drochner size--; 321 1.7 drochner } 322 1.7 drochner 323 1.7 drochner if ((offset & 1) || ((u_long)p & 1)) { 324 1.7 drochner bus_space_read_region_1(sc->bt, sc->bh, offset, p, size); 325 1.7 drochner return; 326 1.7 drochner } 327 1.7 drochner 328 1.7 drochner help = size / 2; 329 1.7 drochner bus_space_read_region_2(sc->bt, sc->bh, offset, p, help); 330 1.7 drochner if (2 * help == size) 331 1.7 drochner return; 332 1.7 drochner 333 1.7 drochner offset += 2 * help; 334 1.32 msaitoh p = (uint16_t *)p + help; 335 1.32 msaitoh *(uint8_t *)p = bus_space_read_1(sc->bt, sc->bh, offset); 336 1.2 pk } 337 1.2 pk 338 1.2 pk /* 339 1.7 drochner * Copy from kernel space to board memory. 340 1.2 pk */ 341 1.2 pk void 342 1.25 dsl ie_memcopyout(struct ie_softc *sc, const void *p, int offset, size_t size) 343 1.2 pk { 344 1.7 drochner size_t help; 345 1.7 drochner 346 1.7 drochner if ((offset & 1) && ((u_long)p & 1) && size > 0) { 347 1.32 msaitoh bus_space_write_1(sc->bt, sc->bh, offset, *(const uint8_t *)p); 348 1.7 drochner offset++; 349 1.32 msaitoh p = (const uint8_t *)p + 1; 350 1.7 drochner size--; 351 1.7 drochner } 352 1.7 drochner 353 1.7 drochner if ((offset & 1) || ((u_long)p & 1)) { 354 1.7 drochner bus_space_write_region_1(sc->bt, sc->bh, offset, p, size); 355 1.7 drochner return; 356 1.7 drochner } 357 1.7 drochner 358 1.7 drochner help = size / 2; 359 1.7 drochner bus_space_write_region_2(sc->bt, sc->bh, offset, p, help); 360 1.7 drochner if (2 * help == size) 361 1.7 drochner return; 362 1.7 drochner 363 1.7 drochner offset += 2 * help; 364 1.32 msaitoh p = (const uint16_t *)p + help; 365 1.32 msaitoh bus_space_write_1(sc->bt, sc->bh, offset, *(const uint8_t *)p); 366 1.2 pk } 367 1.2 pk 368 1.2 pk /* read a 16-bit value at BH offset */ 369 1.32 msaitoh uint16_t ie_vme_read16(struct ie_softc *, int offset); 370 1.2 pk /* write a 16-bit value at BH offset */ 371 1.32 msaitoh void ie_vme_write16(struct ie_softc *, int offset, uint16_t value); 372 1.19 perry void ie_vme_write24(struct ie_softc *, int offset, int addr); 373 1.2 pk 374 1.32 msaitoh uint16_t 375 1.25 dsl ie_vme_read16(struct ie_softc *sc, int offset) 376 1.2 pk { 377 1.32 msaitoh uint16_t v; 378 1.2 pk 379 1.2 pk v = bus_space_read_2(sc->bt, sc->bh, offset); 380 1.2 pk return (((v&0xff)<<8) | ((v>>8)&0xff)); 381 1.2 pk } 382 1.2 pk 383 1.2 pk void 384 1.32 msaitoh ie_vme_write16(struct ie_softc *sc, int offset, uint16_t v) 385 1.2 pk { 386 1.2 pk int v0 = ((((v)&0xff)<<8) | (((v)>>8)&0xff)); 387 1.2 pk bus_space_write_2(sc->bt, sc->bh, offset, v0); 388 1.2 pk } 389 1.2 pk 390 1.2 pk void 391 1.25 dsl ie_vme_write24(struct ie_softc *sc, int offset, int addr) 392 1.1 pk { 393 1.2 pk u_char *f = (u_char *)&addr; 394 1.32 msaitoh uint16_t v0, v1; 395 1.3 pk u_char *t; 396 1.3 pk 397 1.3 pk t = (u_char *)&v0; 398 1.3 pk t[0] = f[3]; t[1] = f[2]; 399 1.3 pk bus_space_write_2(sc->bt, sc->bh, offset, v0); 400 1.3 pk 401 1.3 pk t = (u_char *)&v1; 402 1.3 pk t[0] = f[1]; t[1] = 0; 403 1.3 pk bus_space_write_2(sc->bt, sc->bh, offset+2, v1); 404 1.1 pk } 405 1.1 pk 406 1.1 pk int 407 1.27 cegger ie_vme_match(device_t parent, cfdata_t cf, void *aux) 408 1.1 pk { 409 1.1 pk struct vme_attach_args *va = aux; 410 1.7 drochner vme_chipset_tag_t ct = va->va_vct; 411 1.7 drochner vme_am_t mod; 412 1.7 drochner int error; 413 1.7 drochner 414 1.7 drochner if (va->numcfranges < 2) { 415 1.7 drochner printf("ie_vme_match: need 2 ranges\n"); 416 1.32 msaitoh return 0; 417 1.7 drochner } 418 1.7 drochner if ((va->r[1].offset & 0xff0fffff) || 419 1.7 drochner ((va->r[0].offset & 0xfff00000) 420 1.7 drochner != (va->r[1].offset & 0xfff00000))) { 421 1.7 drochner printf("ie_vme_match: base address mismatch\n"); 422 1.32 msaitoh return 0; 423 1.7 drochner } 424 1.7 drochner if (va->r[0].size != VMECF_LEN_DEFAULT && 425 1.31 riastrad va->r[0].size != sizeof(struct ievme)) { 426 1.7 drochner printf("ie_vme_match: bad csr size\n"); 427 1.32 msaitoh return 0; 428 1.7 drochner } 429 1.7 drochner if (va->r[1].size == VMECF_LEN_DEFAULT) { 430 1.7 drochner printf("ie_vme_match: must specify memory size\n"); 431 1.32 msaitoh return 0; 432 1.7 drochner } 433 1.7 drochner 434 1.7 drochner mod = 0x3d; /* VME_AM_A24|VME_AM_MBO|VME_AM_SUPER|VME_AM_DATA */ 435 1.7 drochner 436 1.7 drochner if (va->r[0].am != VMECF_AM_DEFAULT && 437 1.7 drochner va->r[0].am != mod) 438 1.32 msaitoh return 0; 439 1.1 pk 440 1.7 drochner if (vme_space_alloc(va->va_vct, va->r[0].offset, 441 1.7 drochner sizeof(struct ievme), mod)) 442 1.32 msaitoh return 0; 443 1.32 msaitoh if (vme_space_alloc(va->va_vct, va->r[1].offset, va->r[1].size, mod)) { 444 1.7 drochner vme_space_free(va->va_vct, va->r[0].offset, 445 1.7 drochner sizeof(struct ievme), mod); 446 1.32 msaitoh return 0; 447 1.7 drochner } 448 1.7 drochner error = vme_probe(ct, va->r[0].offset, 2, mod, VME_D16, 0, 0); 449 1.7 drochner vme_space_free(va->va_vct, va->r[0].offset, sizeof(struct ievme), mod); 450 1.7 drochner vme_space_free(va->va_vct, va->r[1].offset, va->r[1].size, mod); 451 1.7 drochner 452 1.7 drochner return (error == 0); 453 1.1 pk } 454 1.1 pk 455 1.1 pk void 456 1.27 cegger ie_vme_attach(device_t parent, device_t self, void *aux) 457 1.1 pk { 458 1.32 msaitoh uint8_t myaddr[ETHER_ADDR_LEN]; 459 1.30 tsutsui struct ie_vme_softc *vsc = device_private(self); 460 1.1 pk struct vme_attach_args *va = aux; 461 1.7 drochner vme_chipset_tag_t ct = va->va_vct; 462 1.7 drochner struct ie_softc *sc; 463 1.1 pk vme_intr_handle_t ih; 464 1.7 drochner vme_addr_t rampaddr; 465 1.7 drochner vme_size_t memsize; 466 1.7 drochner vme_mapresc_t resc; 467 1.7 drochner int lcv; 468 1.28 martin prop_data_t eaddrprop; 469 1.7 drochner vme_am_t mod; 470 1.1 pk 471 1.1 pk /* 472 1.32 msaitoh * *note*: We don't detect the difference between a VME3E and a 473 1.32 msaitoh * multibus/vme card. If you want to use a 3E you'll have to fix this. 474 1.1 pk */ 475 1.7 drochner mod = 0x3d; /* VME_AM_A24|VME_AM_MBO|VME_AM_SUPER|VME_AM_DATA */ 476 1.7 drochner if (vme_space_alloc(va->va_vct, va->r[0].offset, 477 1.7 drochner sizeof(struct ievme), mod) || 478 1.7 drochner vme_space_alloc(va->va_vct, va->r[1].offset, 479 1.7 drochner va->r[1].size, mod)) 480 1.7 drochner panic("if_ie: vme alloc"); 481 1.1 pk 482 1.7 drochner sc = &vsc->ie; 483 1.30 tsutsui sc->sc_dev = self; 484 1.1 pk 485 1.1 pk sc->hwreset = ie_vmereset; 486 1.1 pk sc->hwinit = ie_vmerun; 487 1.1 pk sc->chan_attn = ie_vmeattend; 488 1.1 pk sc->intrhook = ie_vmeintr; 489 1.2 pk sc->memcopyout = ie_memcopyout; 490 1.2 pk sc->memcopyin = ie_memcopyin; 491 1.12 bjh21 492 1.12 bjh21 sc->ie_bus_barrier = NULL; 493 1.2 pk sc->ie_bus_read16 = ie_vme_read16; 494 1.2 pk sc->ie_bus_write16 = ie_vme_write16; 495 1.2 pk sc->ie_bus_write24 = ie_vme_write24; 496 1.1 pk 497 1.7 drochner memsize = va->r[1].size; 498 1.7 drochner 499 1.7 drochner if (vme_space_map(ct, va->r[0].offset, sizeof(struct ievme), mod, 500 1.32 msaitoh VME_D16 | VME_D8, 0, &vsc->ievt, &vsc->ievh, &resc) != 0) 501 1.7 drochner panic("if_ie: vme map csr"); 502 1.7 drochner 503 1.7 drochner rampaddr = va->r[1].offset; 504 1.1 pk 505 1.1 pk /* 4 more */ 506 1.7 drochner rampaddr = rampaddr | ((read_iev(vsc, status) & IEVME_HADDR) << 16); 507 1.7 drochner if (vme_space_map(ct, rampaddr, memsize, mod, VME_D16 | VME_D8, 0, 508 1.7 drochner &sc->bt, &sc->bh, &resc) != 0) 509 1.7 drochner panic("if_ie: vme map mem"); 510 1.1 pk 511 1.7 drochner write_iev(vsc, pectrl, read_iev(vsc, pectrl) | IEVME_PARACK); 512 1.1 pk 513 1.1 pk /* 514 1.1 pk * Set up mappings, direct map except for last page 515 1.1 pk * which is mapped at zero and at high address (for scp) 516 1.1 pk */ 517 1.1 pk for (lcv = 0; lcv < IEVME_MAPSZ - 1; lcv++) 518 1.7 drochner write_iev(vsc, pgmap[lcv], IEVME_SBORDR | IEVME_OBMEM | lcv); 519 1.7 drochner write_iev(vsc, pgmap[IEVME_MAPSZ - 1], IEVME_SBORDR | IEVME_OBMEM | 0); 520 1.1 pk 521 1.1 pk /* Clear all ram */ 522 1.7 drochner bus_space_set_region_2(sc->bt, sc->bh, 0, 0, memsize/2); 523 1.1 pk 524 1.1 pk /* 525 1.2 pk * We use the first page to set up SCP, ICSP and SCB data 526 1.2 pk * structures. The remaining pages become the buffer area 527 1.2 pk * (managed in i82586.c). 528 1.2 pk * SCP is in double-mapped page, so the 586 can see it at 529 1.2 pk * the mandatory magic address (IE_SCP_ADDR). 530 1.1 pk */ 531 1.2 pk sc->scp = (IE_SCP_ADDR & (IEVME_PAGESIZE - 1)); 532 1.1 pk 533 1.1 pk /* iscp at location zero */ 534 1.2 pk sc->iscp = 0; 535 1.1 pk 536 1.1 pk /* scb follows iscp */ 537 1.2 pk sc->scb = IE_ISCP_SZ; 538 1.2 pk 539 1.2 pk ie_vme_write16(sc, IE_ISCP_SCB((long)sc->iscp), sc->scb); 540 1.2 pk ie_vme_write16(sc, IE_ISCP_BASE((u_long)sc->iscp), 0); 541 1.2 pk ie_vme_write24(sc, IE_SCP_ISCP((u_long)sc->scp), 0); 542 1.2 pk 543 1.2 pk if (i82586_proberam(sc) == 0) { 544 1.2 pk printf(": memory probe failed\n"); 545 1.2 pk return; 546 1.2 pk } 547 1.1 pk 548 1.32 msaitoh /* Rest of first page is unused; rest of ram for buffers. */ 549 1.2 pk sc->buf_area = IEVME_PAGESIZE; 550 1.7 drochner sc->buf_area_sz = memsize - IEVME_PAGESIZE; 551 1.1 pk 552 1.2 pk sc->do_xmitnopchain = 0; 553 1.2 pk 554 1.24 cegger printf("\n%s:", device_xname(self)); 555 1.7 drochner 556 1.28 martin eaddrprop = prop_dictionary_get(device_properties(self), "mac-address"); 557 1.28 martin if (eaddrprop != NULL && prop_data_size(eaddrprop) == ETHER_ADDR_LEN) 558 1.33 martin memcpy(myaddr, prop_data_value(eaddrprop), 559 1.28 martin ETHER_ADDR_LEN); 560 1.28 martin 561 1.2 pk i82586_attach(sc, "multibus/vme", myaddr, media, NMEDIA, media[0]); 562 1.1 pk 563 1.7 drochner vme_intr_map(ct, va->ilevel, va->ivector, &ih); 564 1.7 drochner vme_intr_establish(ct, ih, IPL_NET, i82586_intr, sc); 565 1.1 pk } 566
Indexes created Thu Oct 02 01:09:59 GMT 2025