nextdma.c revision 1.29.16.1
1 1.29.16.1 gehenna /* $NetBSD: nextdma.c,v 1.29.16.1 2002/07/16 12:58:57 gehenna Exp $ */ 2 1.1 dbj /* 3 1.1 dbj * Copyright (c) 1998 Darrin B. Jewell 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 Darrin B. Jewell 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 <sys/systm.h> 34 1.1 dbj #include <sys/mbuf.h> 35 1.1 dbj #include <sys/syslog.h> 36 1.1 dbj #include <sys/socket.h> 37 1.1 dbj #include <sys/device.h> 38 1.1 dbj #include <sys/malloc.h> 39 1.1 dbj #include <sys/ioctl.h> 40 1.1 dbj #include <sys/errno.h> 41 1.1 dbj 42 1.1 dbj #include <machine/autoconf.h> 43 1.1 dbj #include <machine/cpu.h> 44 1.1 dbj #include <machine/intr.h> 45 1.5 dbj 46 1.5 dbj #include <m68k/cacheops.h> 47 1.1 dbj 48 1.1 dbj #include <next68k/next68k/isr.h> 49 1.1 dbj 50 1.16 dbj #define _NEXT68K_BUS_DMA_PRIVATE 51 1.1 dbj #include <machine/bus.h> 52 1.1 dbj 53 1.1 dbj #include "nextdmareg.h" 54 1.1 dbj #include "nextdmavar.h" 55 1.1 dbj 56 1.8 dbj #if 1 57 1.1 dbj #define ND_DEBUG 58 1.1 dbj #endif 59 1.1 dbj 60 1.29.16.1 gehenna /* #define panic __asm __volatile("trap #15"); printf */ 61 1.29.16.1 gehenna 62 1.29.16.1 gehenna #define NEXTDMA_DEBUG nd->nd_continue_cb == esp_dmacb_continue && nextdma_debug 63 1.1 dbj #if defined(ND_DEBUG) 64 1.8 dbj int nextdma_debug = 0; 65 1.29.16.1 gehenna bus_dmamap_t esp_dmacb_continue __P((void *)); 66 1.29.16.1 gehenna #define DPRINTF(x) if (NEXTDMA_DEBUG) printf x; 67 1.1 dbj #else 68 1.1 dbj #define DPRINTF(x) 69 1.1 dbj #endif 70 1.29.16.1 gehenna #define PRINTF printf 71 1.29.16.1 gehenna extern char *esplogp, *esplog; 72 1.29.16.1 gehenna #define ESPLOGIF (10 && nd->nd_intr == NEXT_I_SCSI_DMA && esplogp < (esplog + 8192)) 73 1.1 dbj 74 1.26 dbj #if defined(ND_DEBUG) 75 1.26 dbj int nextdma_debug_enetr_idx = 0; 76 1.26 dbj unsigned int nextdma_debug_enetr_state[100] = { 0 }; 77 1.26 dbj int nextdma_debug_scsi_idx = 0; 78 1.26 dbj unsigned int nextdma_debug_scsi_state[100] = { 0 }; 79 1.26 dbj 80 1.26 dbj void nextdma_debug_initstate(struct nextdma_config *nd); 81 1.26 dbj void nextdma_debug_savestate(struct nextdma_config *nd, unsigned int state); 82 1.26 dbj void nextdma_debug_scsi_dumpstate(void); 83 1.26 dbj void nextdma_debug_enetr_dumpstate(void); 84 1.26 dbj 85 1.26 dbj void 86 1.26 dbj nextdma_debug_initstate(struct nextdma_config *nd) 87 1.26 dbj { 88 1.26 dbj switch(nd->nd_intr) { 89 1.26 dbj case NEXT_I_ENETR_DMA: 90 1.26 dbj memset(nextdma_debug_enetr_state,0,sizeof(nextdma_debug_enetr_state)); 91 1.26 dbj break; 92 1.26 dbj case NEXT_I_SCSI_DMA: 93 1.26 dbj memset(nextdma_debug_scsi_state,0,sizeof(nextdma_debug_scsi_state)); 94 1.26 dbj break; 95 1.26 dbj } 96 1.26 dbj } 97 1.26 dbj 98 1.26 dbj void 99 1.26 dbj nextdma_debug_savestate(struct nextdma_config *nd, unsigned int state) 100 1.26 dbj { 101 1.26 dbj switch(nd->nd_intr) { 102 1.26 dbj case NEXT_I_ENETR_DMA: 103 1.26 dbj nextdma_debug_enetr_state[nextdma_debug_enetr_idx++] = state; 104 1.26 dbj nextdma_debug_enetr_idx %= (sizeof(nextdma_debug_enetr_state)/sizeof(unsigned int)); 105 1.26 dbj break; 106 1.26 dbj case NEXT_I_SCSI_DMA: 107 1.26 dbj nextdma_debug_scsi_state[nextdma_debug_scsi_idx++] = state; 108 1.26 dbj nextdma_debug_scsi_idx %= (sizeof(nextdma_debug_scsi_state)/sizeof(unsigned int)); 109 1.26 dbj break; 110 1.26 dbj } 111 1.26 dbj } 112 1.26 dbj 113 1.26 dbj void 114 1.26 dbj nextdma_debug_enetr_dumpstate(void) 115 1.26 dbj { 116 1.26 dbj int i; 117 1.26 dbj int s; 118 1.26 dbj s = spldma(); 119 1.26 dbj i = nextdma_debug_enetr_idx; 120 1.26 dbj do { 121 1.26 dbj char sbuf[256]; 122 1.26 dbj if (nextdma_debug_enetr_state[i]) { 123 1.26 dbj bitmask_snprintf(nextdma_debug_enetr_state[i], DMACSR_BITS, sbuf, sizeof(sbuf)); 124 1.26 dbj printf("DMA: 0x%02x state 0x%s\n",i,sbuf); 125 1.26 dbj } 126 1.26 dbj i++; 127 1.26 dbj i %= (sizeof(nextdma_debug_enetr_state)/sizeof(unsigned int)); 128 1.26 dbj } while (i != nextdma_debug_enetr_idx); 129 1.26 dbj splx(s); 130 1.26 dbj } 131 1.26 dbj 132 1.26 dbj void 133 1.26 dbj nextdma_debug_scsi_dumpstate(void) 134 1.26 dbj { 135 1.26 dbj int i; 136 1.26 dbj int s; 137 1.26 dbj s = spldma(); 138 1.26 dbj i = nextdma_debug_scsi_idx; 139 1.26 dbj do { 140 1.26 dbj char sbuf[256]; 141 1.26 dbj if (nextdma_debug_scsi_state[i]) { 142 1.26 dbj bitmask_snprintf(nextdma_debug_scsi_state[i], DMACSR_BITS, sbuf, sizeof(sbuf)); 143 1.26 dbj printf("DMA: 0x%02x state 0x%s\n",i,sbuf); 144 1.26 dbj } 145 1.26 dbj i++; 146 1.26 dbj i %= (sizeof(nextdma_debug_scsi_state)/sizeof(unsigned int)); 147 1.26 dbj } while (i != nextdma_debug_scsi_idx); 148 1.26 dbj splx(s); 149 1.26 dbj } 150 1.26 dbj #endif 151 1.26 dbj 152 1.26 dbj 153 1.1 dbj void next_dmamap_sync __P((bus_dma_tag_t, bus_dmamap_t, bus_addr_t, 154 1.1 dbj bus_size_t, int)); 155 1.1 dbj int next_dma_continue __P((struct nextdma_config *)); 156 1.1 dbj void next_dma_rotate __P((struct nextdma_config *)); 157 1.1 dbj 158 1.1 dbj void next_dma_setup_cont_regs __P((struct nextdma_config *)); 159 1.1 dbj void next_dma_setup_curr_regs __P((struct nextdma_config *)); 160 1.1 dbj 161 1.1 dbj void 162 1.1 dbj nextdma_config(nd) 163 1.1 dbj struct nextdma_config *nd; 164 1.1 dbj { 165 1.1 dbj /* Initialize the dma_tag. As a hack, we currently 166 1.1 dbj * put the dma tag in the structure itself. It shouldn't be there. 167 1.1 dbj */ 168 1.1 dbj 169 1.1 dbj { 170 1.1 dbj bus_dma_tag_t t; 171 1.1 dbj t = &nd->_nd_dmat; 172 1.1 dbj t->_cookie = nd; 173 1.1 dbj t->_dmamap_create = _bus_dmamap_create; 174 1.1 dbj t->_dmamap_destroy = _bus_dmamap_destroy; 175 1.1 dbj t->_dmamap_load = _bus_dmamap_load_direct; 176 1.1 dbj t->_dmamap_load_mbuf = _bus_dmamap_load_mbuf_direct; 177 1.1 dbj t->_dmamap_load_uio = _bus_dmamap_load_uio_direct; 178 1.1 dbj t->_dmamap_load_raw = _bus_dmamap_load_raw_direct; 179 1.1 dbj t->_dmamap_unload = _bus_dmamap_unload; 180 1.16 dbj t->_dmamap_sync = _bus_dmamap_sync; 181 1.1 dbj 182 1.1 dbj t->_dmamem_alloc = _bus_dmamem_alloc; 183 1.1 dbj t->_dmamem_free = _bus_dmamem_free; 184 1.1 dbj t->_dmamem_map = _bus_dmamem_map; 185 1.1 dbj t->_dmamem_unmap = _bus_dmamem_unmap; 186 1.1 dbj t->_dmamem_mmap = _bus_dmamem_mmap; 187 1.1 dbj 188 1.1 dbj nd->nd_dmat = t; 189 1.1 dbj } 190 1.1 dbj 191 1.14 dbj isrlink_autovec(nextdma_intr, nd, NEXT_I_IPL(nd->nd_intr), 10); 192 1.14 dbj INTR_ENABLE(nd->nd_intr); 193 1.29.16.1 gehenna 194 1.29.16.1 gehenna nextdma_init(nd); 195 1.29.16.1 gehenna 196 1.1 dbj } 197 1.1 dbj 198 1.1 dbj void 199 1.1 dbj nextdma_init(nd) 200 1.1 dbj struct nextdma_config *nd; 201 1.1 dbj { 202 1.22 tv #ifdef ND_DEBUG 203 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 204 1.22 tv char sbuf[256]; 205 1.22 tv 206 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 207 1.22 tv sbuf, sizeof(sbuf)); 208 1.22 tv printf("DMA init ipl (%ld) intr(0x%s)\n", 209 1.22 tv NEXT_I_IPL(nd->nd_intr), sbuf); 210 1.22 tv } 211 1.22 tv #endif 212 1.1 dbj 213 1.1 dbj nd->_nd_map = NULL; 214 1.1 dbj nd->_nd_idx = 0; 215 1.1 dbj nd->_nd_map_cont = NULL; 216 1.1 dbj nd->_nd_idx_cont = 0; 217 1.1 dbj 218 1.1 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 0); 219 1.1 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 220 1.20 dbj DMACSR_RESET | DMACSR_INITBUF); 221 1.1 dbj 222 1.1 dbj next_dma_setup_curr_regs(nd); 223 1.1 dbj next_dma_setup_cont_regs(nd); 224 1.1 dbj 225 1.20 dbj #if defined(DIAGNOSTIC) 226 1.1 dbj { 227 1.1 dbj u_long state; 228 1.1 dbj state = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_CSR); 229 1.20 dbj 230 1.20 dbj #if 1 231 1.20 dbj /* mourning (a 25Mhz 68040 mono slab) appears to set BUSEXC 232 1.20 dbj * milo (a 25Mhz 68040 mono cube) didn't have this problem 233 1.20 dbj * Darrin B. Jewell <jewell (at) mit.edu> Mon May 25 07:53:05 1998 234 1.20 dbj */ 235 1.20 dbj state &= (DMACSR_COMPLETE | DMACSR_SUPDATE | DMACSR_ENABLE); 236 1.20 dbj #else 237 1.1 dbj state &= (DMACSR_BUSEXC | DMACSR_COMPLETE | 238 1.1 dbj DMACSR_SUPDATE | DMACSR_ENABLE); 239 1.20 dbj #endif 240 1.1 dbj if (state) { 241 1.1 dbj next_dma_print(nd); 242 1.20 dbj panic("DMA did not reset"); 243 1.1 dbj } 244 1.1 dbj } 245 1.1 dbj #endif 246 1.1 dbj } 247 1.1 dbj 248 1.4 dbj 249 1.1 dbj void 250 1.1 dbj nextdma_reset(nd) 251 1.1 dbj struct nextdma_config *nd; 252 1.1 dbj { 253 1.1 dbj int s; 254 1.18 dbj s = spldma(); 255 1.8 dbj 256 1.8 dbj DPRINTF(("DMA reset\n")); 257 1.8 dbj 258 1.8 dbj #if (defined(ND_DEBUG)) 259 1.29.16.1 gehenna if (NEXTDMA_DEBUG) next_dma_print(nd); 260 1.8 dbj #endif 261 1.8 dbj 262 1.29.16.1 gehenna bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, DMACSR_CLRCOMPLETE | DMACSR_RESET); 263 1.26 dbj if ((nd->_nd_map) || (nd->_nd_map_cont)) { 264 1.26 dbj /* @@@ clean up dma maps */ 265 1.29.16.1 gehenna /* panic("DMA abort not implemented\n"); */ 266 1.29.16.1 gehenna if (nd->_nd_map_cont) { 267 1.29.16.1 gehenna DPRINTF(("DMA: resetting with non null continue map\n")); 268 1.29.16.1 gehenna if (nd->nd_completed_cb) 269 1.29.16.1 gehenna (*nd->nd_completed_cb)(nd->_nd_map_cont, nd->nd_cb_arg); 270 1.29.16.1 gehenna 271 1.29.16.1 gehenna nd->_nd_map_cont = 0; 272 1.29.16.1 gehenna nd->_nd_idx_cont = 0; 273 1.29.16.1 gehenna } 274 1.29.16.1 gehenna if (nd->nd_shutdown_cb) (*nd->nd_shutdown_cb)(nd->nd_cb_arg); 275 1.29.16.1 gehenna nd->_nd_map = 0; 276 1.29.16.1 gehenna nd->_nd_idx = 0; 277 1.26 dbj } 278 1.20 dbj 279 1.29.16.1 gehenna /* nextdma_init(nd); */ 280 1.1 dbj splx(s); 281 1.1 dbj } 282 1.1 dbj 283 1.1 dbj /****************************************************************/ 284 1.1 dbj 285 1.1 dbj 286 1.1 dbj /* Call the completed and continue callbacks to try to fill 287 1.1 dbj * in the dma continue buffers. 288 1.1 dbj */ 289 1.1 dbj void 290 1.1 dbj next_dma_rotate(nd) 291 1.1 dbj struct nextdma_config *nd; 292 1.1 dbj { 293 1.1 dbj 294 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'r'; 295 1.1 dbj DPRINTF(("DMA next_dma_rotate()\n")); 296 1.1 dbj 297 1.1 dbj /* Rotate the continue map into the current map */ 298 1.1 dbj nd->_nd_map = nd->_nd_map_cont; 299 1.1 dbj nd->_nd_idx = nd->_nd_idx_cont; 300 1.1 dbj 301 1.1 dbj if ((!nd->_nd_map_cont) || 302 1.1 dbj ((nd->_nd_map_cont) && 303 1.1 dbj (++nd->_nd_idx_cont >= nd->_nd_map_cont->dm_nsegs))) { 304 1.1 dbj if (nd->nd_continue_cb) { 305 1.1 dbj nd->_nd_map_cont = (*nd->nd_continue_cb)(nd->nd_cb_arg); 306 1.26 dbj if (nd->_nd_map_cont) { 307 1.26 dbj nd->_nd_map_cont->dm_xfer_len = 0; 308 1.26 dbj } 309 1.1 dbj } else { 310 1.1 dbj nd->_nd_map_cont = 0; 311 1.1 dbj } 312 1.1 dbj nd->_nd_idx_cont = 0; 313 1.1 dbj } 314 1.7 dbj 315 1.29 dbj #if defined(DIAGNOSTIC) && 0 316 1.24 dbj if (nd->_nd_map_cont) { 317 1.12 dbj if (!DMA_BEGINALIGNED(nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_addr)) { 318 1.12 dbj next_dma_print(nd); 319 1.7 dbj panic("DMA request unaligned at start\n"); 320 1.7 dbj } 321 1.12 dbj if (!DMA_ENDALIGNED(nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_addr + 322 1.12 dbj nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_len)) { 323 1.12 dbj next_dma_print(nd); 324 1.7 dbj panic("DMA request unaligned at end\n"); 325 1.7 dbj } 326 1.7 dbj } 327 1.7 dbj #endif 328 1.7 dbj 329 1.1 dbj } 330 1.1 dbj 331 1.1 dbj void 332 1.1 dbj next_dma_setup_cont_regs(nd) 333 1.1 dbj struct nextdma_config *nd; 334 1.1 dbj { 335 1.20 dbj bus_addr_t dd_start; 336 1.20 dbj bus_addr_t dd_stop; 337 1.20 dbj bus_addr_t dd_saved_start; 338 1.20 dbj bus_addr_t dd_saved_stop; 339 1.20 dbj 340 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'c'; 341 1.1 dbj DPRINTF(("DMA next_dma_setup_regs()\n")); 342 1.1 dbj 343 1.1 dbj if (nd->_nd_map_cont) { 344 1.20 dbj dd_start = nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_addr; 345 1.20 dbj dd_stop = (nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_addr + 346 1.20 dbj nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_len); 347 1.1 dbj 348 1.1 dbj if (nd->nd_intr == NEXT_I_ENETX_DMA) { 349 1.20 dbj dd_stop |= 0x80000000; /* Ethernet transmit needs secret magic */ 350 1.29 dbj dd_stop += 15; 351 1.20 dbj } 352 1.20 dbj } else { 353 1.20 dbj dd_start = 0xdeadbeef; 354 1.20 dbj dd_stop = 0xdeadbeef; 355 1.20 dbj } 356 1.1 dbj 357 1.20 dbj dd_saved_start = dd_start; 358 1.20 dbj dd_saved_stop = dd_stop; 359 1.15 dbj 360 1.29.16.1 gehenna if (nd->_nd_map_cont && ESPLOGIF) { 361 1.29.16.1 gehenna sprintf (esplogp, "%ld", nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_len); 362 1.29.16.1 gehenna esplogp += strlen (esplogp); 363 1.29.16.1 gehenna } 364 1.29.16.1 gehenna 365 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_START, dd_start); 366 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_STOP, dd_stop); 367 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_START, dd_saved_start); 368 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_STOP, dd_saved_stop); 369 1.1 dbj 370 1.20 dbj #ifdef DIAGNOSTIC 371 1.24 dbj if ( (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_START) != dd_start) 372 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_STOP) != dd_stop) 373 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_START) != dd_saved_start) 374 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_STOP) != dd_saved_stop) 375 1.24 dbj ) { 376 1.20 dbj next_dma_print(nd); 377 1.20 dbj panic("DMA failure writing to continue regs"); 378 1.1 dbj } 379 1.7 dbj #endif 380 1.1 dbj } 381 1.1 dbj 382 1.1 dbj void 383 1.1 dbj next_dma_setup_curr_regs(nd) 384 1.1 dbj struct nextdma_config *nd; 385 1.1 dbj { 386 1.20 dbj bus_addr_t dd_next; 387 1.20 dbj bus_addr_t dd_limit; 388 1.20 dbj bus_addr_t dd_saved_next; 389 1.20 dbj bus_addr_t dd_saved_limit; 390 1.20 dbj 391 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'C'; 392 1.1 dbj DPRINTF(("DMA next_dma_setup_curr_regs()\n")); 393 1.1 dbj 394 1.15 dbj 395 1.15 dbj if (nd->_nd_map) { 396 1.20 dbj dd_next = nd->_nd_map->dm_segs[nd->_nd_idx].ds_addr; 397 1.20 dbj dd_limit = (nd->_nd_map->dm_segs[nd->_nd_idx].ds_addr + 398 1.20 dbj nd->_nd_map->dm_segs[nd->_nd_idx].ds_len); 399 1.24 dbj 400 1.15 dbj if (nd->nd_intr == NEXT_I_ENETX_DMA) { 401 1.20 dbj dd_limit |= 0x80000000; /* Ethernet transmit needs secret magic */ 402 1.29 dbj dd_limit += 15; 403 1.20 dbj } 404 1.20 dbj } else { 405 1.20 dbj dd_next = 0xdeadbeef; 406 1.20 dbj dd_limit = 0xdeadbeef; 407 1.20 dbj } 408 1.1 dbj 409 1.20 dbj dd_saved_next = dd_next; 410 1.20 dbj dd_saved_limit = dd_limit; 411 1.1 dbj 412 1.29.16.1 gehenna if (nd->_nd_map && ESPLOGIF) { 413 1.29.16.1 gehenna sprintf (esplogp, "%ld", nd->_nd_map->dm_segs[nd->_nd_idx].ds_len); 414 1.29.16.1 gehenna esplogp += strlen (esplogp); 415 1.29.16.1 gehenna } 416 1.29.16.1 gehenna 417 1.20 dbj if (nd->nd_intr == NEXT_I_ENETX_DMA) { 418 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_NEXT_INITBUF, dd_next); 419 1.15 dbj } else { 420 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_NEXT, dd_next); 421 1.15 dbj } 422 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_LIMIT, dd_limit); 423 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_NEXT, dd_saved_next); 424 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT, dd_saved_limit); 425 1.1 dbj 426 1.20 dbj #ifdef DIAGNOSTIC 427 1.24 dbj if ( (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_NEXT_INITBUF) != dd_next) 428 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_NEXT) != dd_next) 429 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_LIMIT) != dd_limit) 430 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_NEXT) != dd_saved_next) 431 1.24 dbj || (bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT) != dd_saved_limit) 432 1.24 dbj ) { 433 1.20 dbj next_dma_print(nd); 434 1.20 dbj panic("DMA failure writing to current regs"); 435 1.20 dbj } 436 1.7 dbj #endif 437 1.1 dbj } 438 1.1 dbj 439 1.1 dbj 440 1.1 dbj /* This routine is used for debugging */ 441 1.1 dbj 442 1.1 dbj void 443 1.1 dbj next_dma_print(nd) 444 1.1 dbj struct nextdma_config *nd; 445 1.1 dbj { 446 1.1 dbj u_long dd_csr; 447 1.1 dbj u_long dd_next; 448 1.1 dbj u_long dd_next_initbuf; 449 1.1 dbj u_long dd_limit; 450 1.1 dbj u_long dd_start; 451 1.1 dbj u_long dd_stop; 452 1.1 dbj u_long dd_saved_next; 453 1.1 dbj u_long dd_saved_limit; 454 1.1 dbj u_long dd_saved_start; 455 1.1 dbj u_long dd_saved_stop; 456 1.22 tv char sbuf[256]; 457 1.1 dbj 458 1.22 tv /* Read all of the registers before we print anything out, 459 1.1 dbj * in case something changes 460 1.1 dbj */ 461 1.1 dbj dd_csr = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_CSR); 462 1.1 dbj dd_next = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_NEXT); 463 1.1 dbj dd_next_initbuf = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_NEXT_INITBUF); 464 1.1 dbj dd_limit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_LIMIT); 465 1.1 dbj dd_start = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_START); 466 1.1 dbj dd_stop = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_STOP); 467 1.1 dbj dd_saved_next = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_NEXT); 468 1.1 dbj dd_saved_limit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT); 469 1.1 dbj dd_saved_start = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_START); 470 1.1 dbj dd_saved_stop = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_STOP); 471 1.1 dbj 472 1.22 tv bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRSTAT)), 473 1.22 tv NEXT_INTR_BITS, sbuf, sizeof(sbuf)); 474 1.22 tv printf("NDMAP: *intrstat = 0x%s\n", sbuf); 475 1.22 tv 476 1.22 tv bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRMASK)), 477 1.22 tv NEXT_INTR_BITS, sbuf, sizeof(sbuf)); 478 1.22 tv printf("NDMAP: *intrmask = 0x%s\n", sbuf); 479 1.20 dbj 480 1.12 dbj /* NDMAP is Next DMA Print (really!) */ 481 1.12 dbj 482 1.1 dbj if (nd->_nd_map) { 483 1.28 chs printf("NDMAP: nd->_nd_map->dm_mapsize = %ld\n", 484 1.11 dbj nd->_nd_map->dm_mapsize); 485 1.11 dbj printf("NDMAP: nd->_nd_map->dm_nsegs = %d\n", 486 1.11 dbj nd->_nd_map->dm_nsegs); 487 1.28 chs printf("NDMAP: nd->_nd_map->dm_xfer_len = %ld\n", 488 1.26 dbj nd->_nd_map->dm_xfer_len); 489 1.1 dbj printf("NDMAP: nd->_nd_map->dm_segs[%d].ds_addr = 0x%08lx\n", 490 1.1 dbj nd->_nd_idx,nd->_nd_map->dm_segs[nd->_nd_idx].ds_addr); 491 1.28 chs printf("NDMAP: nd->_nd_map->dm_segs[%d].ds_len = %ld\n", 492 1.1 dbj nd->_nd_idx,nd->_nd_map->dm_segs[nd->_nd_idx].ds_len); 493 1.24 dbj { 494 1.24 dbj int i; 495 1.24 dbj printf("NDMAP: Entire map;\n"); 496 1.24 dbj for(i=0;i<nd->_nd_map->dm_nsegs;i++) { 497 1.24 dbj printf("NDMAP: nd->_nd_map->dm_segs[%d].ds_addr = 0x%08lx\n", 498 1.24 dbj i,nd->_nd_map->dm_segs[i].ds_addr); 499 1.28 chs printf("NDMAP: nd->_nd_map->dm_segs[%d].ds_len = %ld\n", 500 1.24 dbj i,nd->_nd_map->dm_segs[i].ds_len); 501 1.24 dbj } 502 1.24 dbj } 503 1.1 dbj } else { 504 1.1 dbj printf("NDMAP: nd->_nd_map = NULL\n"); 505 1.1 dbj } 506 1.1 dbj if (nd->_nd_map_cont) { 507 1.28 chs printf("NDMAP: nd->_nd_map_cont->dm_mapsize = %ld\n", 508 1.11 dbj nd->_nd_map_cont->dm_mapsize); 509 1.11 dbj printf("NDMAP: nd->_nd_map_cont->dm_nsegs = %d\n", 510 1.11 dbj nd->_nd_map_cont->dm_nsegs); 511 1.28 chs printf("NDMAP: nd->_nd_map_cont->dm_xfer_len = %ld\n", 512 1.26 dbj nd->_nd_map_cont->dm_xfer_len); 513 1.1 dbj printf("NDMAP: nd->_nd_map_cont->dm_segs[%d].ds_addr = 0x%08lx\n", 514 1.1 dbj nd->_nd_idx_cont,nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_addr); 515 1.28 chs printf("NDMAP: nd->_nd_map_cont->dm_segs[%d].ds_len = %ld\n", 516 1.1 dbj nd->_nd_idx_cont,nd->_nd_map_cont->dm_segs[nd->_nd_idx_cont].ds_len); 517 1.24 dbj if (nd->_nd_map_cont != nd->_nd_map) { 518 1.24 dbj int i; 519 1.24 dbj printf("NDMAP: Entire map;\n"); 520 1.24 dbj for(i=0;i<nd->_nd_map_cont->dm_nsegs;i++) { 521 1.24 dbj printf("NDMAP: nd->_nd_map_cont->dm_segs[%d].ds_addr = 0x%08lx\n", 522 1.24 dbj i,nd->_nd_map_cont->dm_segs[i].ds_addr); 523 1.28 chs printf("NDMAP: nd->_nd_map_cont->dm_segs[%d].ds_len = %ld\n", 524 1.24 dbj i,nd->_nd_map_cont->dm_segs[i].ds_len); 525 1.24 dbj } 526 1.24 dbj } 527 1.1 dbj } else { 528 1.1 dbj printf("NDMAP: nd->_nd_map_cont = NULL\n"); 529 1.1 dbj } 530 1.1 dbj 531 1.22 tv bitmask_snprintf(dd_csr, DMACSR_BITS, sbuf, sizeof(sbuf)); 532 1.22 tv printf("NDMAP: dd->dd_csr = 0x%s\n", sbuf); 533 1.22 tv 534 1.28 chs printf("NDMAP: dd->dd_saved_next = 0x%08lx\n", dd_saved_next); 535 1.28 chs printf("NDMAP: dd->dd_saved_limit = 0x%08lx\n", dd_saved_limit); 536 1.28 chs printf("NDMAP: dd->dd_saved_start = 0x%08lx\n", dd_saved_start); 537 1.28 chs printf("NDMAP: dd->dd_saved_stop = 0x%08lx\n", dd_saved_stop); 538 1.28 chs printf("NDMAP: dd->dd_next = 0x%08lx\n", dd_next); 539 1.28 chs printf("NDMAP: dd->dd_next_initbuf = 0x%08lx\n", dd_next_initbuf); 540 1.28 chs printf("NDMAP: dd->dd_limit = 0x%08lx\n", dd_limit); 541 1.28 chs printf("NDMAP: dd->dd_start = 0x%08lx\n", dd_start); 542 1.28 chs printf("NDMAP: dd->dd_stop = 0x%08lx\n", dd_stop); 543 1.1 dbj 544 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 545 1.22 tv sbuf, sizeof(sbuf)); 546 1.22 tv printf("NDMAP: interrupt ipl (%ld) intr(0x%s)\n", 547 1.22 tv NEXT_I_IPL(nd->nd_intr), sbuf); 548 1.1 dbj } 549 1.1 dbj 550 1.1 dbj /****************************************************************/ 551 1.1 dbj 552 1.1 dbj int 553 1.1 dbj nextdma_intr(arg) 554 1.1 dbj void *arg; 555 1.1 dbj { 556 1.1 dbj /* @@@ This is bogus, we can't be certain of arg's type 557 1.18 dbj * unless the interrupt is for us. For now we successfully 558 1.18 dbj * cheat because DMA interrupts are the only things invoked 559 1.18 dbj * at this interrupt level. 560 1.1 dbj */ 561 1.18 dbj struct nextdma_config *nd = arg; 562 1.1 dbj 563 1.1 dbj if (!INTR_OCCURRED(nd->nd_intr)) return 0; 564 1.1 dbj /* Handle dma interrupts */ 565 1.1 dbj 566 1.29.16.1 gehenna #if 01 567 1.29.16.1 gehenna if (nd->nd_intr == NEXT_I_SCSI_DMA) { 568 1.29.16.1 gehenna int esp_dma_int __P((void *)); 569 1.29.16.1 gehenna return esp_dma_int (nd->nd_cb_arg); 570 1.29.16.1 gehenna } 571 1.29.16.1 gehenna #endif 572 1.29.16.1 gehenna 573 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'D'; 574 1.22 tv #ifdef ND_DEBUG 575 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 576 1.22 tv char sbuf[256]; 577 1.22 tv 578 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 579 1.22 tv sbuf, sizeof(sbuf)); 580 1.22 tv printf("DMA interrupt ipl (%ld) intr(0x%s)\n", 581 1.22 tv NEXT_I_IPL(nd->nd_intr), sbuf); 582 1.22 tv } 583 1.22 tv #endif 584 1.1 dbj 585 1.7 dbj #ifdef DIAGNOSTIC 586 1.7 dbj if (!nd->_nd_map) { 587 1.7 dbj next_dma_print(nd); 588 1.7 dbj panic("DMA missing current map in interrupt!\n"); 589 1.7 dbj } 590 1.7 dbj #endif 591 1.7 dbj 592 1.1 dbj { 593 1.24 dbj unsigned int state = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_CSR); 594 1.26 dbj 595 1.26 dbj #if defined(ND_DEBUG) 596 1.26 dbj nextdma_debug_savestate(nd,state); 597 1.26 dbj #endif 598 1.26 dbj 599 1.26 dbj #ifdef DIAGNOSTIC 600 1.26 dbj if (!(state & DMACSR_COMPLETE)) { 601 1.26 dbj char sbuf[256]; 602 1.26 dbj next_dma_print(nd); 603 1.26 dbj bitmask_snprintf(state, DMACSR_BITS, sbuf, sizeof(sbuf)); 604 1.26 dbj printf("DMA: state 0x%s\n",sbuf); 605 1.26 dbj panic("DMA complete not set in interrupt\n"); 606 1.26 dbj } 607 1.26 dbj #endif 608 1.26 dbj 609 1.26 dbj { 610 1.23 dbj bus_addr_t onext; 611 1.23 dbj bus_addr_t olimit; 612 1.23 dbj bus_addr_t slimit; 613 1.1 dbj 614 1.23 dbj DPRINTF(("DMA: finishing xfer\n")); 615 1.23 dbj 616 1.23 dbj onext = nd->_nd_map->dm_segs[nd->_nd_idx].ds_addr; 617 1.23 dbj olimit = onext + nd->_nd_map->dm_segs[nd->_nd_idx].ds_len; 618 1.23 dbj 619 1.24 dbj { 620 1.24 dbj int result = 0; 621 1.24 dbj if (state & DMACSR_ENABLE) { 622 1.24 dbj /* enable bit was set */ 623 1.24 dbj result |= 0x01; 624 1.24 dbj } 625 1.23 dbj if (state & DMACSR_SUPDATE) { 626 1.24 dbj /* supdate bit was set */ 627 1.24 dbj result |= 0x02; 628 1.24 dbj } 629 1.26 dbj if (nd->_nd_map_cont == NULL) { 630 1.27 dbj KASSERT(nd->_nd_idx+1 == nd->_nd_map->dm_nsegs); 631 1.24 dbj /* Expecting a shutdown, didn't SETSUPDATE last turn */ 632 1.24 dbj result |= 0x04; 633 1.24 dbj } 634 1.24 dbj if (state & DMACSR_BUSEXC) { 635 1.24 dbj /* bus exception bit was set */ 636 1.24 dbj result |= 0x08; 637 1.24 dbj } 638 1.24 dbj switch (result) { 639 1.24 dbj case 0x00: /* !BUSEXC && !expecting && !SUPDATE && !ENABLE */ 640 1.24 dbj case 0x08: /* BUSEXC && !expecting && !SUPDATE && !ENABLE */ 641 1.27 dbj if (nd->nd_intr == NEXT_I_SCSI_DMA) { 642 1.27 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_LIMIT); 643 1.27 dbj } else { 644 1.27 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT); 645 1.27 dbj } 646 1.24 dbj break; 647 1.24 dbj case 0x01: /* !BUSEXC && !expecting && !SUPDATE && ENABLE */ 648 1.24 dbj case 0x09: /* BUSEXC && !expecting && !SUPDATE && ENABLE */ 649 1.26 dbj if (nd->nd_intr == NEXT_I_SCSI_DMA) { 650 1.26 dbj bus_addr_t snext; 651 1.26 dbj snext = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_NEXT); 652 1.26 dbj if (snext != onext) { 653 1.26 dbj slimit = olimit; 654 1.26 dbj } else { 655 1.26 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT); 656 1.26 dbj } 657 1.26 dbj } else { 658 1.26 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_SAVED_LIMIT); 659 1.24 dbj } 660 1.24 dbj break; 661 1.24 dbj case 0x02: /* !BUSEXC && !expecting && SUPDATE && !ENABLE */ 662 1.24 dbj case 0x0a: /* BUSEXC && !expecting && SUPDATE && !ENABLE */ 663 1.24 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_NEXT); 664 1.24 dbj break; 665 1.24 dbj case 0x04: /* !BUSEXC && expecting && !SUPDATE && !ENABLE */ 666 1.24 dbj case 0x0c: /* BUSEXC && expecting && !SUPDATE && !ENABLE */ 667 1.24 dbj slimit = bus_space_read_4(nd->nd_bst, nd->nd_bsh, DD_LIMIT); 668 1.24 dbj break; 669 1.24 dbj default: 670 1.7 dbj #ifdef DIAGNOSTIC 671 1.26 dbj { 672 1.26 dbj char sbuf[256]; 673 1.26 dbj printf("DMA: please send this output to port-next68k-maintainer (at) netbsd.org:\n"); 674 1.26 dbj bitmask_snprintf(state, DMACSR_BITS, sbuf, sizeof(sbuf)); 675 1.26 dbj printf("DMA: state 0x%s\n",sbuf); 676 1.26 dbj next_dma_print(nd); 677 1.26 dbj panic("DMA: condition 0x%02x not yet documented to occur\n",result); 678 1.26 dbj } 679 1.23 dbj #endif 680 1.24 dbj slimit = olimit; 681 1.24 dbj break; 682 1.23 dbj } 683 1.23 dbj } 684 1.22 tv 685 1.23 dbj if (nd->nd_intr == NEXT_I_ENETX_DMA) { 686 1.23 dbj slimit &= ~0x80000000; 687 1.29 dbj slimit -= 15; 688 1.23 dbj } 689 1.22 tv 690 1.23 dbj #ifdef DIAGNOSTIC 691 1.23 dbj if ((slimit < onext) || (slimit > olimit)) { 692 1.26 dbj char sbuf[256]; 693 1.26 dbj bitmask_snprintf(state, DMACSR_BITS, sbuf, sizeof(sbuf)); 694 1.26 dbj printf("DMA: state 0x%s\n",sbuf); 695 1.23 dbj next_dma_print(nd); 696 1.28 chs panic("DMA: Unexpected limit register (0x%08lx) in finish_xfer\n",slimit); 697 1.23 dbj } 698 1.1 dbj #endif 699 1.1 dbj 700 1.26 dbj #ifdef DIAGNOSTIC 701 1.26 dbj if ((state & DMACSR_ENABLE) && ((nd->_nd_idx+1) != nd->_nd_map->dm_nsegs)) { 702 1.26 dbj if (slimit != olimit) { 703 1.26 dbj char sbuf[256]; 704 1.26 dbj bitmask_snprintf(state, DMACSR_BITS, sbuf, sizeof(sbuf)); 705 1.26 dbj printf("DMA: state 0x%s\n",sbuf); 706 1.26 dbj next_dma_print(nd); 707 1.28 chs panic("DMA: short limit register (0x%08lx) w/o finishing map.\n",slimit); 708 1.26 dbj } 709 1.26 dbj } 710 1.26 dbj #endif 711 1.26 dbj 712 1.23 dbj #if (defined(ND_DEBUG)) 713 1.29.16.1 gehenna if (NEXTDMA_DEBUG > 2) next_dma_print(nd); 714 1.23 dbj #endif 715 1.7 dbj 716 1.26 dbj nd->_nd_map->dm_xfer_len += slimit-onext; 717 1.12 dbj 718 1.23 dbj /* If we've reached the end of the current map, then inform 719 1.23 dbj * that we've completed that map. 720 1.23 dbj */ 721 1.26 dbj if ((nd->_nd_idx+1) == nd->_nd_map->dm_nsegs) { 722 1.23 dbj if (nd->nd_completed_cb) 723 1.23 dbj (*nd->nd_completed_cb)(nd->_nd_map, nd->nd_cb_arg); 724 1.27 dbj } else { 725 1.27 dbj KASSERT(nd->_nd_map == nd->_nd_map_cont); 726 1.27 dbj KASSERT(nd->_nd_idx+1 == nd->_nd_idx_cont); 727 1.23 dbj } 728 1.23 dbj nd->_nd_map = 0; 729 1.23 dbj nd->_nd_idx = 0; 730 1.23 dbj } 731 1.23 dbj 732 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 733 1.29.16.1 gehenna char sbuf[256]; 734 1.29.16.1 gehenna bitmask_snprintf(state, DMACSR_BITS, sbuf, sizeof(sbuf)); 735 1.29.16.1 gehenna printf("CLNDMAP: dd->dd_csr = 0x%s\n", sbuf); 736 1.29.16.1 gehenna } 737 1.23 dbj if (state & DMACSR_ENABLE) { 738 1.22 tv 739 1.23 dbj next_dma_rotate(nd); 740 1.23 dbj next_dma_setup_cont_regs(nd); 741 1.22 tv 742 1.23 dbj { 743 1.23 dbj u_long dmadir; /* DMACSR_SETREAD or DMACSR_SETWRITE */ 744 1.23 dbj 745 1.23 dbj if (state & DMACSR_READ) { 746 1.23 dbj dmadir = DMACSR_SETREAD; 747 1.23 dbj } else { 748 1.23 dbj dmadir = DMACSR_SETWRITE; 749 1.23 dbj } 750 1.23 dbj 751 1.26 dbj if (nd->_nd_map_cont == NULL) { 752 1.27 dbj KASSERT(nd->_nd_idx+1 == nd->_nd_map->dm_nsegs); 753 1.23 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 754 1.23 dbj DMACSR_CLRCOMPLETE | dmadir); 755 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'g'; 756 1.23 dbj } else { 757 1.23 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 758 1.23 dbj DMACSR_CLRCOMPLETE | dmadir | DMACSR_SETSUPDATE); 759 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'G'; 760 1.23 dbj } 761 1.7 dbj } 762 1.7 dbj 763 1.23 dbj } else { 764 1.7 dbj 765 1.25 dbj DPRINTF(("DMA: a shutdown occurred\n")); 766 1.25 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, DMACSR_CLRCOMPLETE | DMACSR_RESET); 767 1.25 dbj 768 1.23 dbj /* Cleanup more incomplete transfers */ 769 1.26 dbj #if 1 770 1.26 dbj /* cleanup continue map */ 771 1.23 dbj if (nd->_nd_map_cont) { 772 1.23 dbj DPRINTF(("DMA: shutting down with non null continue map\n")); 773 1.23 dbj if (nd->nd_completed_cb) 774 1.23 dbj (*nd->nd_completed_cb)(nd->_nd_map_cont, nd->nd_cb_arg); 775 1.23 dbj 776 1.23 dbj nd->_nd_map_cont = 0; 777 1.23 dbj nd->_nd_idx_cont = 0; 778 1.20 dbj } 779 1.25 dbj #else 780 1.26 dbj /* Do an automatic dma restart */ 781 1.26 dbj if (nd->_nd_map_cont) { 782 1.26 dbj u_long dmadir; /* DMACSR_SETREAD or DMACSR_SETWRITE */ 783 1.26 dbj 784 1.25 dbj next_dma_rotate(nd); 785 1.27 dbj 786 1.25 dbj if (state & DMACSR_READ) { 787 1.25 dbj dmadir = DMACSR_SETREAD; 788 1.25 dbj } else { 789 1.25 dbj dmadir = DMACSR_SETWRITE; 790 1.25 dbj } 791 1.25 dbj 792 1.25 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 0); 793 1.25 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 794 1.25 dbj DMACSR_INITBUF | DMACSR_RESET | dmadir); 795 1.25 dbj 796 1.25 dbj next_dma_setup_curr_regs(nd); 797 1.25 dbj next_dma_setup_cont_regs(nd); 798 1.25 dbj 799 1.26 dbj if (nd->_nd_map_cont == NULL) { 800 1.27 dbj KASSERT(nd->_nd_idx+1 == nd->_nd_map->dm_nsegs); 801 1.25 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 802 1.25 dbj DMACSR_SETENABLE | dmadir); 803 1.25 dbj } else { 804 1.25 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 805 1.25 dbj DMACSR_SETSUPDATE | DMACSR_SETENABLE | dmadir); 806 1.25 dbj } 807 1.25 dbj return 1; 808 1.25 dbj } 809 1.25 dbj #endif 810 1.23 dbj if (nd->nd_shutdown_cb) (*nd->nd_shutdown_cb)(nd->nd_cb_arg); 811 1.1 dbj } 812 1.1 dbj } 813 1.29.16.1 gehenna 814 1.22 tv #ifdef ND_DEBUG 815 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 816 1.22 tv char sbuf[256]; 817 1.22 tv 818 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 819 1.22 tv sbuf, sizeof(sbuf)); 820 1.22 tv printf("DMA exiting interrupt ipl (%ld) intr(0x%s)\n", 821 1.22 tv NEXT_I_IPL(nd->nd_intr), sbuf); 822 1.22 tv } 823 1.22 tv #endif 824 1.1 dbj 825 1.1 dbj return(1); 826 1.1 dbj } 827 1.1 dbj 828 1.1 dbj /* 829 1.1 dbj * Check to see if dma has finished for a channel */ 830 1.1 dbj int 831 1.1 dbj nextdma_finished(nd) 832 1.1 dbj struct nextdma_config *nd; 833 1.1 dbj { 834 1.1 dbj int r; 835 1.1 dbj int s; 836 1.1 dbj s = spldma(); /* @@@ should this be splimp()? */ 837 1.1 dbj r = (nd->_nd_map == NULL) && (nd->_nd_map_cont == NULL); 838 1.1 dbj splx(s); 839 1.1 dbj return(r); 840 1.1 dbj } 841 1.1 dbj 842 1.1 dbj void 843 1.1 dbj nextdma_start(nd, dmadir) 844 1.1 dbj struct nextdma_config *nd; 845 1.19 dbj u_long dmadir; /* DMACSR_SETREAD or DMACSR_SETWRITE */ 846 1.1 dbj { 847 1.1 dbj 848 1.29.16.1 gehenna if (ESPLOGIF) *esplogp++ = 'n'; 849 1.1 dbj #ifdef DIAGNOSTIC 850 1.1 dbj if (!nextdma_finished(nd)) { 851 1.22 tv char sbuf[256]; 852 1.22 tv 853 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 854 1.22 tv sbuf, sizeof(sbuf)); 855 1.22 tv panic("DMA trying to start before previous finished on intr(0x%s)\n", sbuf); 856 1.1 dbj } 857 1.1 dbj #endif 858 1.1 dbj 859 1.22 tv #ifdef ND_DEBUG 860 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 861 1.22 tv char sbuf[256]; 862 1.22 tv 863 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 864 1.22 tv sbuf, sizeof(sbuf)); 865 1.22 tv printf("DMA start (%ld) intr(0x%s)\n", 866 1.22 tv NEXT_I_IPL(nd->nd_intr), sbuf); 867 1.22 tv } 868 1.22 tv #endif 869 1.1 dbj 870 1.1 dbj #ifdef DIAGNOSTIC 871 1.1 dbj if (nd->_nd_map) { 872 1.1 dbj next_dma_print(nd); 873 1.1 dbj panic("DMA: nextdma_start() with non null map\n"); 874 1.1 dbj } 875 1.1 dbj if (nd->_nd_map_cont) { 876 1.1 dbj next_dma_print(nd); 877 1.1 dbj panic("DMA: nextdma_start() with non null continue map\n"); 878 1.1 dbj } 879 1.1 dbj #endif 880 1.1 dbj 881 1.9 dbj #ifdef DIAGNOSTIC 882 1.19 dbj if ((dmadir != DMACSR_SETREAD) && (dmadir != DMACSR_SETWRITE)) { 883 1.19 dbj panic("DMA: nextdma_start(), dmadir arg must be DMACSR_SETREAD or DMACSR_SETWRITE\n"); 884 1.9 dbj } 885 1.9 dbj #endif 886 1.9 dbj 887 1.26 dbj #if defined(ND_DEBUG) 888 1.26 dbj nextdma_debug_initstate(nd); 889 1.26 dbj #endif 890 1.26 dbj 891 1.7 dbj /* preload both the current and the continue maps */ 892 1.1 dbj next_dma_rotate(nd); 893 1.1 dbj 894 1.1 dbj #ifdef DIAGNOSTIC 895 1.1 dbj if (!nd->_nd_map_cont) { 896 1.1 dbj panic("No map available in nextdma_start()"); 897 1.1 dbj } 898 1.1 dbj #endif 899 1.1 dbj 900 1.7 dbj next_dma_rotate(nd); 901 1.7 dbj 902 1.22 tv #ifdef ND_DEBUG 903 1.29.16.1 gehenna if (NEXTDMA_DEBUG) { 904 1.22 tv char sbuf[256]; 905 1.22 tv 906 1.22 tv bitmask_snprintf(NEXT_I_BIT(nd->nd_intr), NEXT_INTR_BITS, 907 1.22 tv sbuf, sizeof(sbuf)); 908 1.22 tv printf("DMA initiating DMA %s of %d segments on intr(0x%s)\n", 909 1.22 tv (dmadir == DMACSR_SETREAD ? "read" : "write"), nd->_nd_map->dm_nsegs, sbuf); 910 1.22 tv } 911 1.22 tv #endif 912 1.1 dbj 913 1.1 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 0); 914 1.1 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 915 1.20 dbj DMACSR_INITBUF | DMACSR_RESET | dmadir); 916 1.1 dbj 917 1.7 dbj next_dma_setup_curr_regs(nd); 918 1.1 dbj next_dma_setup_cont_regs(nd); 919 1.1 dbj 920 1.4 dbj #if (defined(ND_DEBUG)) 921 1.29.16.1 gehenna if (NEXTDMA_DEBUG > 2) next_dma_print(nd); 922 1.4 dbj #endif 923 1.1 dbj 924 1.26 dbj if (nd->_nd_map_cont == NULL) { 925 1.20 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 926 1.20 dbj DMACSR_SETENABLE | dmadir); 927 1.20 dbj } else { 928 1.1 dbj bus_space_write_4(nd->nd_bst, nd->nd_bsh, DD_CSR, 929 1.20 dbj DMACSR_SETSUPDATE | DMACSR_SETENABLE | dmadir); 930 1.1 dbj } 931 1.1 dbj } 932
Indexes created Thu Oct 02 14:10:14 GMT 2025