scsi.c revision 1.3.2.1
1 1.3.2.1 gehenna /* $NetBSD: scsi.c,v 1.3.2.1 2002/07/16 12:59:01 gehenna Exp $ */ 2 1.1 dbj /* 3 1.1 dbj * Copyright (c) 1994, 1997 Rolf Grossmann 4 1.1 dbj * All rights reserved. 5 1.1 dbj * 6 1.1 dbj * Redistribution and use in source and binary forms, with or without 7 1.1 dbj * modification, are permitted provided that the following conditions 8 1.1 dbj * are met: 9 1.1 dbj * 1. Redistributions of source code must retain the above copyright 10 1.1 dbj * notice, this list of conditions and the following disclaimer. 11 1.1 dbj * 2. Redistributions in binary form must reproduce the above copyright 12 1.1 dbj * notice, this list of conditions and the following disclaimer in the 13 1.1 dbj * documentation and/or other materials provided with the distribution. 14 1.1 dbj * 3. All advertising materials mentioning features or use of this software 15 1.1 dbj * must display the following acknowledgement: 16 1.1 dbj * This product includes software developed by Rolf Grossmann. 17 1.1 dbj * 4. The name of the author may not be used to endorse or promote products 18 1.1 dbj * derived from this software without specific prior written permission 19 1.1 dbj * 20 1.1 dbj * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 21 1.1 dbj * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 22 1.1 dbj * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 23 1.1 dbj * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 24 1.1 dbj * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 25 1.1 dbj * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 26 1.1 dbj * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 27 1.1 dbj * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 28 1.1 dbj * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 29 1.1 dbj * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 30 1.1 dbj */ 31 1.1 dbj 32 1.1 dbj #include <sys/param.h> 33 1.1 dbj #include <next68k/dev/espreg.h> 34 1.3 jdolecek #include <dev/ic/ncr53c9xreg.h> 35 1.1 dbj #include <dev/scsipi/scsi_message.h> 36 1.1 dbj #if 0 37 1.1 dbj #include <next/next/prominfo.h> 38 1.1 dbj #else 39 1.1 dbj #include <next68k/next68k/nextrom.h> 40 1.1 dbj #endif 41 1.1 dbj #include "scsireg.h" 42 1.1 dbj #include "dmareg.h" 43 1.1 dbj #include "scsivar.h" 44 1.1 dbj 45 1.1 dbj #include <lib/libsa/stand.h> 46 1.1 dbj 47 1.1 dbj struct scsi_softc scsi_softc, *sc = &scsi_softc; 48 1.1 dbj char the_dma_buffer[MAX_DMASIZE+DMA_ENDALIGNMENT], *dma_buffer; 49 1.1 dbj 50 1.1 dbj int scsi_msgin(void); 51 1.1 dbj int dma_start(char *addr, int len); 52 1.1 dbj int dma_done(void); 53 1.1 dbj 54 1.2 dbj void scsi_init(void); 55 1.2 dbj void scsierror(char *error); 56 1.2 dbj short scsi_getbyte(volatile caddr_t sr); 57 1.2 dbj int scsi_wait_for_intr(void); 58 1.2 dbj int scsiicmd(char target, char lun, 59 1.3.2.1 gehenna u_char *cbuf, int clen, char *addr, int *len); 60 1.2 dbj 61 1.3.2.1 gehenna #define NDPRINTF(x) 62 1.3.2.1 gehenna #define PRINTF(x) 63 1.3.2.1 gehenna /* printf x; */ 64 1.3.2.1 gehenna #ifdef xSCSI_DEBUG 65 1.1 dbj #define DPRINTF(x) printf x; 66 1.1 dbj #else 67 1.1 dbj #define DPRINTF(x) 68 1.1 dbj #endif 69 1.1 dbj 70 1.1 dbj void 71 1.1 dbj scsi_init(void) 72 1.1 dbj { 73 1.1 dbj volatile caddr_t sr; 74 1.1 dbj struct dma_dev *dma; 75 1.1 dbj 76 1.1 dbj sr = P_SCSI; 77 1.1 dbj dma = (struct dma_dev *)P_SCSI_CSR; 78 1.1 dbj 79 1.1 dbj dma_buffer = DMA_ALIGN(char *, the_dma_buffer); 80 1.1 dbj 81 1.1 dbj P_FLOPPY[FLP_CTRL] &= ~FLC_82077_SEL; /* select SCSI chip */ 82 1.1 dbj 83 1.1 dbj /* first reset dma */ 84 1.1 dbj dma->dd_csr = DMACSR_RESET; 85 1.1 dbj DELAY(200); 86 1.1 dbj sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_RESET; 87 1.1 dbj DELAY(10); 88 1.1 dbj sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB; 89 1.1 dbj DELAY(10); 90 1.1 dbj 91 1.1 dbj /* then reset the SCSI chip */ 92 1.3 jdolecek sr[NCR_CMD] = NCRCMD_RSTCHIP; 93 1.3 jdolecek sr[NCR_CMD] = NCRCMD_NOP; 94 1.1 dbj DELAY(500); 95 1.1 dbj 96 1.1 dbj /* now reset the SCSI bus */ 97 1.3 jdolecek sr[NCR_CMD] = NCRCMD_RSTSCSI; 98 1.3.2.1 gehenna DELAY(4000000); /* XXX should be about 2-3 seconds at least */ 99 1.1 dbj 100 1.1 dbj /* then reset the SCSI chip again and initialize it properly */ 101 1.3 jdolecek sr[NCR_CMD] = NCRCMD_RSTCHIP; 102 1.3 jdolecek sr[NCR_CMD] = NCRCMD_NOP; 103 1.1 dbj DELAY(500); 104 1.3 jdolecek sr[NCR_CFG1] = NCRCFG1_SLOW | NCRCFG1_BUSID; 105 1.3 jdolecek sr[NCR_CFG2] = 0; 106 1.3 jdolecek sr[NCR_CCF] = 4; /* S5RCLKCONV_FACTOR(20); */ 107 1.3 jdolecek sr[NCR_TIMEOUT] = 152; /* S5RSELECT_TIMEOUT(20,250); */ 108 1.3 jdolecek sr[NCR_SYNCOFF] = 0; 109 1.3 jdolecek sr[NCR_SYNCTP] = 5; 110 1.1 dbj /* 111 1.1 dbj sc->sc_intrstatus = sr->s5r_intrstatus; 112 1.1 dbj sc->sc_intrstatus = sr->s5r_intrstatus; 113 1.1 dbj */ 114 1.3 jdolecek sr[NCR_CFG1] = NCRCFG1_PARENB | NCRCFG1_BUSID; 115 1.1 dbj 116 1.1 dbj sc->sc_state = SCSI_IDLE; 117 1.1 dbj } 118 1.1 dbj 119 1.1 dbj void 120 1.1 dbj scsierror(char *error) 121 1.1 dbj { 122 1.1 dbj printf("scsierror: %s.\n", error); 123 1.1 dbj } 124 1.1 dbj 125 1.1 dbj short 126 1.1 dbj scsi_getbyte(volatile caddr_t sr) 127 1.1 dbj { 128 1.3 jdolecek if ((sr[NCR_FFLAG] & NCRFIFO_FF) == 0) 129 1.1 dbj { 130 1.1 dbj printf("getbyte: no data!\n"); 131 1.1 dbj return -1; 132 1.1 dbj } 133 1.3 jdolecek return sr[NCR_FIFO]; 134 1.1 dbj } 135 1.1 dbj 136 1.1 dbj int 137 1.1 dbj scsi_wait_for_intr(void) 138 1.1 dbj { 139 1.1 dbj #if 0 140 1.1 dbj extern struct prominfo *pi; 141 1.1 dbj volitle int = pi->pi_intrstat; /* ### use constant? */ 142 1.1 dbj #else 143 1.1 dbj extern char *mg; 144 1.1 dbj #define MON(type, off) (*(type *)((u_int) (mg) + off)) 145 1.1 dbj volatile int *intrstat = MON(volatile int *,MG_intrstat); 146 1.3.2.1 gehenna #ifdef SCSI_DEBUG 147 1.3.2.1 gehenna /* volatile int *intrmask = MON(volatile int *,MG_intrmask); */ 148 1.3.2.1 gehenna #endif 149 1.1 dbj #endif 150 1.1 dbj int count; 151 1.1 dbj 152 1.2 dbj for(count = 0; count < SCSI_TIMEOUT; count++) { 153 1.3.2.1 gehenna NDPRINTF((" *intrstat = 0x%x\t*intrmask = 0x%x\n",*intrstat,*intrmask)); 154 1.2 dbj 155 1.1 dbj if (*intrstat & SCSI_INTR) 156 1.1 dbj return 0; 157 1.2 dbj } 158 1.1 dbj 159 1.1 dbj printf("scsiicmd: timed out.\n"); 160 1.1 dbj return -1; 161 1.1 dbj } 162 1.1 dbj 163 1.1 dbj int 164 1.1 dbj scsiicmd(char target, char lun, 165 1.1 dbj u_char *cbuf, int clen, 166 1.3.2.1 gehenna char *addr, int *len) 167 1.1 dbj { 168 1.1 dbj volatile caddr_t sr; 169 1.1 dbj int i; 170 1.1 dbj 171 1.1 dbj DPRINTF(("scsiicmd: [%x, %d] -> %d (%lx, %d)\n",*cbuf, clen, 172 1.3.2.1 gehenna target, (long)addr, *len)); 173 1.1 dbj sr = P_SCSI; 174 1.1 dbj 175 1.1 dbj if (sc->sc_state != SCSI_IDLE) { 176 1.1 dbj scsierror("scsiiscmd: bad state"); 177 1.1 dbj return EIO; 178 1.1 dbj } 179 1.1 dbj sc->sc_result = 0; 180 1.1 dbj 181 1.1 dbj /* select target */ 182 1.3 jdolecek sr[NCR_CMD] = NCRCMD_FLUSH; 183 1.1 dbj DELAY(10); 184 1.3 jdolecek sr[NCR_SELID] = target; 185 1.3 jdolecek sr[NCR_FIFO] = MSG_IDENTIFY(lun, 0); 186 1.1 dbj for (i=0; i<clen; i++) 187 1.3 jdolecek sr[NCR_FIFO] = cbuf[i]; 188 1.3 jdolecek sr[NCR_CMD] = NCRCMD_SELATN; 189 1.1 dbj sc->sc_state = SCSI_SELECTING; 190 1.1 dbj 191 1.1 dbj while(sc->sc_state != SCSI_DONE) { 192 1.1 dbj if (scsi_wait_for_intr()) /* maybe we'd better use real intrs ? */ 193 1.1 dbj return EIO; 194 1.1 dbj 195 1.1 dbj if (sc->sc_state == SCSI_DMA) 196 1.1 dbj { 197 1.1 dbj /* registers are not valid on dma intr */ 198 1.1 dbj sc->sc_status = sc->sc_seqstep = sc->sc_intrstatus = 0; 199 1.1 dbj DPRINTF(("scsiicmd: dma intr\n")); 200 1.3.2.1 gehenna sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD; 201 1.1 dbj } 202 1.3.2.1 gehenna 203 1.3.2.1 gehenna /* scsi processing */ 204 1.3.2.1 gehenna sc->sc_status = sr[NCR_STAT]; 205 1.3.2.1 gehenna sc->sc_seqstep = sr[NCR_STEP]; 206 1.3.2.1 gehenna sc->sc_intrstatus = sr[NCR_INTR]; 207 1.3.2.1 gehenna redo: 208 1.3.2.1 gehenna DPRINTF(("scsiicmd: regs[intr=%x, stat=%x, step=%x]\n", 209 1.3.2.1 gehenna sc->sc_intrstatus, sc->sc_status, sc->sc_seqstep)); 210 1.1 dbj 211 1.3 jdolecek if (sc->sc_intrstatus & NCRINTR_SBR) { 212 1.1 dbj scsierror("scsi bus reset"); 213 1.1 dbj return EIO; 214 1.1 dbj } 215 1.1 dbj 216 1.3 jdolecek if ((sc->sc_status & NCRSTAT_GE) 217 1.3 jdolecek || (sc->sc_intrstatus & NCRINTR_ILL)) { 218 1.1 dbj scsierror("software error"); 219 1.1 dbj return EIO; 220 1.1 dbj } 221 1.3 jdolecek if (sc->sc_status & NCRSTAT_PE) 222 1.1 dbj { 223 1.1 dbj scsierror("parity error"); 224 1.1 dbj return EIO; 225 1.1 dbj } 226 1.1 dbj 227 1.1 dbj switch(sc->sc_state) 228 1.1 dbj { 229 1.1 dbj case SCSI_SELECTING: 230 1.3 jdolecek if (sc->sc_intrstatus & NCRINTR_DIS) 231 1.1 dbj { 232 1.1 dbj sc->sc_state = SCSI_IDLE; 233 1.1 dbj return EUNIT; /* device not present */ 234 1.1 dbj } 235 1.1 dbj 236 1.3 jdolecek #define NCRINTR_DONE (NCRINTR_BS | NCRINTR_FC) 237 1.3 jdolecek if ((sc->sc_intrstatus & NCRINTR_DONE) != NCRINTR_DONE) 238 1.1 dbj { 239 1.1 dbj scsierror("selection failed"); 240 1.1 dbj return EIO; 241 1.1 dbj } 242 1.1 dbj sc->sc_state = SCSI_HASBUS; 243 1.1 dbj break; 244 1.1 dbj case SCSI_HASBUS: 245 1.3 jdolecek if (sc->sc_intrstatus & NCRINTR_DIS) 246 1.1 dbj { 247 1.1 dbj scsierror("target disconnected"); 248 1.1 dbj return EIO; 249 1.1 dbj } 250 1.1 dbj break; 251 1.1 dbj case SCSI_DMA: 252 1.3 jdolecek if (sc->sc_intrstatus & NCRINTR_DIS) 253 1.1 dbj { 254 1.1 dbj scsierror("target disconnected"); 255 1.1 dbj return EIO; 256 1.1 dbj } 257 1.3.2.1 gehenna *len = dma_done(); 258 1.3.2.1 gehenna if (*len < 0) { 259 1.3.2.1 gehenna *len = 0; 260 1.3.2.1 gehenna return EIO; 261 1.3.2.1 gehenna } 262 1.3.2.1 gehenna /* continue; */ 263 1.3.2.1 gehenna sc->sc_status = sr[NCR_STAT]; 264 1.3.2.1 gehenna goto redo; 265 1.3.2.1 gehenna break; 266 1.1 dbj case SCSI_CLEANUP: 267 1.3 jdolecek if (sc->sc_intrstatus & NCRINTR_DIS) 268 1.1 dbj { 269 1.1 dbj sc->sc_state = SCSI_DONE; 270 1.1 dbj continue; 271 1.1 dbj } 272 1.1 dbj DPRINTF(("hmm ... no disconnect on cleanup?\n")); 273 1.1 dbj sc->sc_state = SCSI_DONE; /* maybe ... */ 274 1.1 dbj break; 275 1.1 dbj } 276 1.1 dbj 277 1.1 dbj /* transfer information now */ 278 1.3 jdolecek switch(sc->sc_status & NCRSTAT_PHASE) 279 1.1 dbj { 280 1.1 dbj case DATA_IN_PHASE: 281 1.3.2.1 gehenna sr[NCR_CMD] = NCRCMD_FLUSH; 282 1.3.2.1 gehenna if (dma_start(addr, *len) != 0) 283 1.1 dbj return EIO; 284 1.1 dbj break; 285 1.1 dbj case DATA_OUT_PHASE: 286 1.1 dbj scsierror("data out phase not implemented"); 287 1.1 dbj return EIO; 288 1.1 dbj case STATUS_PHASE: 289 1.1 dbj DPRINTF(("status phase: ")); 290 1.3 jdolecek sr[NCR_CMD] = NCRCMD_ICCS; 291 1.1 dbj sc->sc_result = scsi_getbyte(sr); 292 1.1 dbj DPRINTF(("status is 0x%x.\n", sc->sc_result)); 293 1.1 dbj break; 294 1.1 dbj case MSG_IN_PHASE: 295 1.3.2.1 gehenna if ((sc->sc_intrstatus & NCRINTR_BS) != 0) { 296 1.3.2.1 gehenna sr[NCR_CMD] = NCRCMD_FLUSH; 297 1.3.2.1 gehenna sr[NCR_CMD] = NCRCMD_TRANS; 298 1.3.2.1 gehenna } else 299 1.3.2.1 gehenna if (scsi_msgin() != 0) 300 1.3.2.1 gehenna return EIO; 301 1.3.2.1 gehenna break; 302 1.1 dbj default: 303 1.1 dbj DPRINTF(("phase not implemented: 0x%x.\n", 304 1.3 jdolecek sc->sc_status & NCRSTAT_PHASE)); 305 1.1 dbj scsierror("bad phase"); 306 1.1 dbj return EIO; 307 1.1 dbj } 308 1.1 dbj } 309 1.1 dbj 310 1.1 dbj sc->sc_state = SCSI_IDLE; 311 1.1 dbj return -sc->sc_result; 312 1.1 dbj } 313 1.1 dbj 314 1.1 dbj int 315 1.1 dbj scsi_msgin(void) 316 1.1 dbj { 317 1.1 dbj volatile caddr_t sr; 318 1.1 dbj u_char msg; 319 1.1 dbj 320 1.1 dbj sr = P_SCSI; 321 1.1 dbj 322 1.1 dbj msg = scsi_getbyte(sr); 323 1.1 dbj if (msg) 324 1.1 dbj { 325 1.1 dbj printf("unexpected msg: 0x%x.\n",msg); 326 1.1 dbj return -1; 327 1.1 dbj } 328 1.3 jdolecek if ((sc->sc_intrstatus & NCRINTR_FC) == 0) 329 1.1 dbj { 330 1.1 dbj printf("not function complete.\n"); 331 1.1 dbj return -1; 332 1.1 dbj } 333 1.1 dbj sc->sc_state = SCSI_CLEANUP; 334 1.3 jdolecek sr[NCR_CMD] = NCRCMD_MSGOK; 335 1.1 dbj return 0; 336 1.1 dbj } 337 1.1 dbj 338 1.1 dbj int 339 1.1 dbj dma_start(char *addr, int len) 340 1.1 dbj { 341 1.1 dbj volatile caddr_t sr; 342 1.1 dbj struct dma_dev *dma; 343 1.1 dbj 344 1.1 dbj 345 1.1 dbj sr = P_SCSI; 346 1.1 dbj dma = (struct dma_dev *)P_SCSI_CSR; 347 1.1 dbj 348 1.1 dbj if (len > MAX_DMASIZE) 349 1.1 dbj { 350 1.1 dbj scsierror("dma too long"); 351 1.1 dbj return -1; 352 1.1 dbj } 353 1.1 dbj 354 1.1 dbj if (addr == NULL || len == 0) 355 1.1 dbj { 356 1.1 dbj #if 0 /* I'd take that as an error in my code */ 357 1.1 dbj DPRINTF(("hmm ... no dma requested.\n")); 358 1.3 jdolecek sr[NCR_TCL] = 0; 359 1.3 jdolecek sr[NCR_TCM] = 1; 360 1.3 jdolecek sr[NCR_CMD] = NCRCMD_NOP; 361 1.3 jdolecek sr[NCR_CMD] = NCRCMD_DMA | NCRCMD_TRPAD; 362 1.1 dbj return 0; 363 1.1 dbj #else 364 1.1 dbj scsierror("unrequested dma"); 365 1.1 dbj return -1; 366 1.1 dbj #endif 367 1.1 dbj } 368 1.1 dbj 369 1.3.2.1 gehenna PRINTF(("dma start: %lx, %d byte.\n", (long)addr, len)); 370 1.2 dbj 371 1.2 dbj DPRINTF(("dma_bufffer: start: 0x%lx end: 0x%lx \n", 372 1.2 dbj (long)dma_buffer,(long)DMA_ENDALIGN(char *, dma_buffer+len))); 373 1.2 dbj 374 1.1 dbj sc->dma_addr = addr; 375 1.1 dbj sc->dma_len = len; 376 1.1 dbj 377 1.3 jdolecek sr[NCR_TCL] = len & 0xff; 378 1.3 jdolecek sr[NCR_TCM] = len >> 8; 379 1.3 jdolecek sr[NCR_CMD] = NCRCMD_DMA | NCRCMD_NOP; 380 1.3 jdolecek sr[NCR_CMD] = NCRCMD_DMA | NCRCMD_TRANS; 381 1.2 dbj 382 1.2 dbj #if 0 383 1.1 dbj dma->dd_csr = DMACSR_READ | DMACSR_RESET; 384 1.1 dbj dma->dd_next_initbuf = dma_buffer; 385 1.1 dbj dma->dd_limit = DMA_ENDALIGN(char *, dma_buffer+len); 386 1.1 dbj dma->dd_csr = DMACSR_READ | DMACSR_SETENABLE; 387 1.2 dbj #else 388 1.2 dbj dma->dd_csr = 0; 389 1.2 dbj dma->dd_csr = DMACSR_INITBUF | DMACSR_READ | DMACSR_RESET; 390 1.3.2.1 gehenna dma->dd_next = dma_buffer; 391 1.2 dbj dma->dd_limit = DMA_ENDALIGN(char *, dma_buffer+len); 392 1.2 dbj dma->dd_csr = DMACSR_READ | DMACSR_SETENABLE; 393 1.2 dbj #endif 394 1.2 dbj 395 1.1 dbj sr[ESP_DCTL] = ESPDCTL_20MHZ|ESPDCTL_INTENB|ESPDCTL_DMAMOD|ESPDCTL_DMARD; 396 1.1 dbj 397 1.1 dbj sc->sc_state = SCSI_DMA; 398 1.1 dbj return 0; 399 1.1 dbj } 400 1.1 dbj 401 1.1 dbj int 402 1.1 dbj dma_done(void) 403 1.1 dbj { 404 1.1 dbj volatile caddr_t sr; 405 1.1 dbj struct dma_dev *dma; 406 1.3.2.1 gehenna int resid, state; 407 1.3.2.1 gehenna int flushcount = 0; 408 1.1 dbj 409 1.1 dbj sr = P_SCSI; 410 1.1 dbj dma = (struct dma_dev *)P_SCSI_CSR; 411 1.1 dbj 412 1.1 dbj state = dma->dd_csr & (DMACSR_BUSEXC | DMACSR_COMPLETE 413 1.1 dbj | DMACSR_SUPDATE | DMACSR_ENABLE); 414 1.1 dbj 415 1.3.2.1 gehenna sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD; 416 1.3.2.1 gehenna resid = sr[NCR_TCM]<<8 | sr[NCR_TCL]; 417 1.3.2.1 gehenna DPRINTF(("dma state = 0x%x, remain = %d.\n", state, resid)); 418 1.3.2.1 gehenna 419 1.3.2.1 gehenna if (!(sr[NCR_FFLAG] & NCRFIFO_FF)) { 420 1.3.2.1 gehenna sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD 421 1.3.2.1 gehenna | ESPDCTL_DMARD; 422 1.3.2.1 gehenna while (!(state & DMACSR_COMPLETE) && (state & DMACSR_ENABLE) && flushcount < 16) 423 1.3.2.1 gehenna { 424 1.3.2.1 gehenna 425 1.3.2.1 gehenna DPRINTF(("dma still enabled, flushing DCTL.\n")); 426 1.3.2.1 gehenna 427 1.3.2.1 gehenna sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD 428 1.3.2.1 gehenna | ESPDCTL_DMARD | ESPDCTL_FLUSH; 429 1.3.2.1 gehenna sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD 430 1.3.2.1 gehenna | ESPDCTL_DMARD; 431 1.3.2.1 gehenna 432 1.3.2.1 gehenna flushcount++; 433 1.3.2.1 gehenna state = dma->dd_csr & (DMACSR_BUSEXC | DMACSR_COMPLETE 434 1.3.2.1 gehenna | DMACSR_SUPDATE | DMACSR_ENABLE); 435 1.3.2.1 gehenna } 436 1.1 dbj } 437 1.1 dbj sr[ESP_DCTL] = ESPDCTL_20MHZ | ESPDCTL_INTENB; 438 1.3.2.1 gehenna resid = (sr[NCR_TCM]<<8) + sr[NCR_TCL]; 439 1.3.2.1 gehenna 440 1.3.2.1 gehenna dma->dd_csr = DMACSR_CLRCOMPLETE | DMACSR_RESET; 441 1.1 dbj 442 1.3.2.1 gehenna DPRINTF(("dma done. remain = %d, state = 0x%x, fifo = 0x%x.\n", resid, state, sr[NCR_FFLAG] & NCRFIFO_FF)); 443 1.1 dbj 444 1.3.2.1 gehenna if (resid != 0) 445 1.1 dbj { 446 1.1 dbj #if 0 447 1.3.2.1 gehenna printf("WARNING: unexpected %d characters remain in dma\n",resid); 448 1.3.2.1 gehenna scsierror("dma transfer incomplete"); 449 1.1 dbj return -1; 450 1.1 dbj #endif 451 1.1 dbj } 452 1.1 dbj 453 1.1 dbj if (state & DMACSR_BUSEXC) 454 1.1 dbj { 455 1.1 dbj scsierror("dma failed"); 456 1.1 dbj return -1; 457 1.1 dbj } 458 1.3.2.1 gehenna 459 1.3.2.1 gehenna sc->dma_len -= resid; 460 1.3.2.1 gehenna if (sc->dma_len < 0) 461 1.3.2.1 gehenna sc->dma_len = 0; 462 1.3.2.1 gehenna bcopy(dma_buffer, sc->dma_addr, sc->dma_len); 463 1.3.2.1 gehenna sc->sc_state = SCSI_HASBUS; 464 1.3.2.1 gehenna DPRINTF(("dma done. got %d.\n", sc->dma_len)); 465 1.3.2.1 gehenna return sc->dma_len; 466 1.3.2.1 gehenna 467 1.3.2.1 gehenna /* scsierror("dma not completed\n"); */ 468 1.1 dbj 469 1.3.2.1 gehenna return 0; 470 1.1 dbj } 471
Indexes created Thu Oct 02 14:10:14 GMT 2025