cpu.h revision 1.11.2.2
1 1.11.2.2 bouyer /* $NetBSD: cpu.h,v 1.11.2.2 2001/01/05 17:34:53 bouyer Exp $ */ 2 1.1 dbj 3 1.1 dbj /* 4 1.1 dbj * Copyright (c) 1988 University of Utah. 5 1.1 dbj * Copyright (c) 1982, 1990, 1993 6 1.1 dbj * The Regents of the University of California. All rights reserved. 7 1.1 dbj * 8 1.1 dbj * This code is derived from software contributed to Berkeley by 9 1.1 dbj * the Systems Programming Group of the University of Utah Computer 10 1.1 dbj * Science Department. 11 1.1 dbj * 12 1.1 dbj * Redistribution and use in source and binary forms, with or without 13 1.1 dbj * modification, are permitted provided that the following conditions 14 1.1 dbj * are met: 15 1.1 dbj * 1. Redistributions of source code must retain the above copyright 16 1.1 dbj * notice, this list of conditions and the following disclaimer. 17 1.1 dbj * 2. Redistributions in binary form must reproduce the above copyright 18 1.1 dbj * notice, this list of conditions and the following disclaimer in the 19 1.1 dbj * documentation and/or other materials provided with the distribution. 20 1.1 dbj * 3. All advertising materials mentioning features or use of this software 21 1.1 dbj * must display the following acknowledgement: 22 1.1 dbj * This product includes software developed by the University of 23 1.1 dbj * California, Berkeley and its contributors. 24 1.1 dbj * 4. Neither the name of the University nor the names of its contributors 25 1.1 dbj * may be used to endorse or promote products derived from this software 26 1.1 dbj * without specific prior written permission. 27 1.1 dbj * 28 1.1 dbj * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 29 1.1 dbj * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 30 1.1 dbj * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 31 1.1 dbj * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 32 1.1 dbj * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 33 1.1 dbj * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 34 1.1 dbj * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 35 1.1 dbj * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 36 1.1 dbj * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 37 1.1 dbj * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 38 1.1 dbj * SUCH DAMAGE. 39 1.1 dbj * 40 1.1 dbj * from: Utah $Hdr: cpu.h 1.16 91/03/25$ 41 1.1 dbj * 42 1.1 dbj * @(#)cpu.h 8.4 (Berkeley) 1/5/94 43 1.1 dbj */ 44 1.1 dbj 45 1.1 dbj 46 1.1 dbj #ifndef _CPU_MACHINE_ 47 1.1 dbj #define _CPU_MACHINE_ 48 1.1 dbj 49 1.11.2.1 bouyer #if defined(_KERNEL) && !defined(_LKM) 50 1.11.2.1 bouyer #include "opt_lockdebug.h" 51 1.11.2.1 bouyer #endif 52 1.11.2.1 bouyer 53 1.1 dbj /* 54 1.1 dbj * Exported definitions unique to next68k/68k cpu support. 55 1.1 dbj */ 56 1.1 dbj 57 1.1 dbj /* 58 1.1 dbj * Get common m68k definitions. 59 1.1 dbj */ 60 1.1 dbj #include <m68k/cpu.h> 61 1.1 dbj 62 1.1 dbj #define M68K_MMU_MOTOROLA 63 1.1 dbj 64 1.1 dbj /* 65 1.1 dbj * Get interrupt glue. 66 1.1 dbj */ 67 1.1 dbj #include <machine/intr.h> 68 1.1 dbj 69 1.11.2.1 bouyer #include <sys/sched.h> 70 1.11.2.1 bouyer struct cpu_info { 71 1.11.2.1 bouyer struct schedstate_percpu ci_schedstate; /* scheduler state */ 72 1.11.2.1 bouyer #if defined(DIAGNOSTIC) || defined(LOCKDEBUG) 73 1.11.2.1 bouyer u_long ci_spin_locks; /* # of spin locks held */ 74 1.11.2.1 bouyer u_long ci_simple_locks; /* # of simple locks held */ 75 1.11.2.1 bouyer #endif 76 1.11.2.1 bouyer }; 77 1.11.2.1 bouyer 78 1.11.2.1 bouyer #ifdef _KERNEL 79 1.11.2.1 bouyer extern struct cpu_info cpu_info_store; 80 1.11.2.1 bouyer 81 1.11.2.1 bouyer #define curcpu() (&cpu_info_store) 82 1.11.2.1 bouyer 83 1.1 dbj /* 84 1.1 dbj * definitions of cpu-dependent requirements 85 1.1 dbj * referenced in generic code 86 1.1 dbj */ 87 1.1 dbj #define cpu_swapin(p) /* nothing */ 88 1.1 dbj #define cpu_wait(p) /* nothing */ 89 1.1 dbj #define cpu_swapout(p) /* nothing */ 90 1.11 thorpej #define cpu_number() 0 91 1.1 dbj 92 1.1 dbj /* 93 1.1 dbj * Arguments to hardclock and gatherstats encapsulate the previous 94 1.1 dbj * machine state in an opaque clockframe. One the hp300, we use 95 1.1 dbj * what the hardware pushes on an interrupt (frame format 0). 96 1.1 dbj */ 97 1.1 dbj struct clockframe { 98 1.1 dbj u_short sr; /* sr at time of interrupt */ 99 1.1 dbj u_long pc; /* pc at time of interrupt */ 100 1.1 dbj u_short vo; /* vector offset (4-word frame) */ 101 1.1 dbj }; 102 1.1 dbj 103 1.1 dbj #define CLKF_USERMODE(framep) (((framep)->sr & PSL_S) == 0) 104 1.1 dbj #define CLKF_BASEPRI(framep) (((framep)->sr & PSL_IPL) == 0) 105 1.1 dbj #define CLKF_PC(framep) ((framep)->pc) 106 1.1 dbj #if 0 107 1.1 dbj /* We would like to do it this way... */ 108 1.1 dbj #define CLKF_INTR(framep) (((framep)->sr & PSL_M) == 0) 109 1.1 dbj #else 110 1.1 dbj /* but until we start using PSL_M, we have to do this instead */ 111 1.1 dbj #define CLKF_INTR(framep) (0) /* XXX */ 112 1.1 dbj #endif 113 1.1 dbj 114 1.1 dbj /* 115 1.1 dbj * Preempt the current process if in interrupt from user mode, 116 1.1 dbj * or after the current trap/syscall if in system mode. 117 1.1 dbj */ 118 1.11.2.1 bouyer extern int want_resched; /* resched() was called */ 119 1.11.2.1 bouyer #define need_resched(ci) { want_resched = 1; aston(); } 120 1.1 dbj 121 1.1 dbj /* 122 1.1 dbj * Give a profiling tick to the current process when the user profiling 123 1.1 dbj * buffer pages are invalid. On the sun3, request an ast to send us 124 1.1 dbj * through trap, marking the proc as needing a profiling tick. 125 1.1 dbj */ 126 1.1 dbj #define need_proftick(p) ((p)->p_flag |= P_OWEUPC, aston()) 127 1.1 dbj 128 1.1 dbj /* 129 1.1 dbj * Notify the current process (p) that it has a signal pending, 130 1.1 dbj * process as soon as possible. 131 1.1 dbj */ 132 1.1 dbj #define signotify(p) aston() 133 1.1 dbj 134 1.1 dbj #define aston() (astpending++) 135 1.1 dbj 136 1.1 dbj int astpending; /* need to trap before returning to user mode */ 137 1.1 dbj int want_resched; /* resched() was called */ 138 1.1 dbj 139 1.1 dbj extern volatile char *intiobase; 140 1.1 dbj extern volatile char *intiolimit; 141 1.10 dbj extern volatile char *monobase; 142 1.10 dbj extern volatile char *monolimit; 143 1.10 dbj extern volatile char *colorbase; 144 1.10 dbj extern volatile char *colorlimit; 145 1.1 dbj extern void (*vectab[]) __P((void)); 146 1.1 dbj 147 1.1 dbj struct frame; 148 1.1 dbj struct fpframe; 149 1.1 dbj struct pcb; 150 1.1 dbj 151 1.1 dbj /* locore.s functions */ 152 1.1 dbj void m68881_save __P((struct fpframe *)); 153 1.1 dbj void m68881_restore __P((struct fpframe *)); 154 1.1 dbj #if 0 /* it's already in m68k/m68k.h */ 155 1.1 dbj u_long getdfc __P((void)); 156 1.1 dbj u_long getsfc __P((void)); 157 1.1 dbj #endif 158 1.5 dbj 159 1.5 dbj #if 0 /* {@@@ Use cacheops.h? */ 160 1.5 dbj 161 1.1 dbj void DCIA __P((void)); 162 1.1 dbj void DCIS __P((void)); 163 1.1 dbj void DCIU __P((void)); 164 1.1 dbj void ICIA __P((void)); 165 1.1 dbj void ICPA __P((void)); 166 1.1 dbj void PCIA __P((void)); 167 1.1 dbj void TBIA __P((void)); 168 1.1 dbj void TBIS __P((vm_offset_t)); 169 1.1 dbj void TBIAS __P((void)); 170 1.1 dbj void TBIAU __P((void)); 171 1.1 dbj #if defined(M68040) 172 1.1 dbj void DCFA __P((void)); 173 1.1 dbj void DCFP __P((vm_offset_t)); 174 1.1 dbj void DCFL __P((vm_offset_t)); 175 1.1 dbj void DCPL __P((vm_offset_t)); 176 1.1 dbj void DCPP __P((vm_offset_t)); 177 1.1 dbj void ICPL __P((vm_offset_t)); 178 1.1 dbj void ICPP __P((vm_offset_t)); 179 1.1 dbj #endif 180 1.5 dbj #endif /* }@@@ use m68k/cacheops.c */ 181 1.5 dbj 182 1.1 dbj int suline __P((caddr_t, caddr_t)); 183 1.1 dbj void savectx __P((struct pcb *)); 184 1.1 dbj void switch_exit __P((struct proc *)); 185 1.1 dbj void proc_trampoline __P((void)); 186 1.1 dbj void loadustp __P((int)); 187 1.1 dbj 188 1.1 dbj void doboot __P((void)) __attribute__((__noreturn__)); 189 1.8 is 190 1.8 is /* sys_machdep.c functions */ 191 1.9 is int cachectl1 __P((unsigned long, vaddr_t, size_t, struct proc *)); 192 1.1 dbj 193 1.1 dbj /* vm_machdep.c functions */ 194 1.1 dbj void physaccess __P((caddr_t, caddr_t, int, int)); 195 1.1 dbj void physunaccess __P((caddr_t, int)); 196 1.1 dbj int kvtop __P((caddr_t)); 197 1.1 dbj 198 1.1 dbj /* clock.c functions */ 199 1.1 dbj void next68k_calibrate_delay __P((void)); 200 1.1 dbj 201 1.1 dbj #endif /* _KERNEL */ 202 1.1 dbj 203 1.1 dbj #define NEXT_RAMBASE (0x4000000) /* really depends on slot, but... */ 204 1.1 dbj #define NEXT_BANKSIZE (0x1000000) /* Size of a memory bank in physical address */ 205 1.1 dbj 206 1.1 dbj #if 0 207 1.1 dbj /* @@@ this needs to be fixed to work on 030's */ 208 1.1 dbj #define NEXT_SLOT_ID 0x0 209 1.1 dbj #ifdef M68030 210 1.1 dbj #define NEXT_SLOT_ID_BMAP 0x0 211 1.1 dbj #endif M68030 212 1.1 dbj #endif 213 1.1 dbj #ifdef M68040 214 1.3 dbj #ifdef DISABLE_NEXT_BMAP_CHIP /* @@@ For turbo testing */ 215 1.3 dbj #define NEXT_SLOT_ID_BMAP 0x0 216 1.3 dbj #else 217 1.1 dbj #define NEXT_SLOT_ID_BMAP 0x00100000 218 1.3 dbj #endif 219 1.1 dbj #define NEXT_SLOT_ID 0x0 220 1.1 dbj #endif M68040 221 1.1 dbj 222 1.1 dbj /****************************************************************/ 223 1.1 dbj 224 1.1 dbj /* Eventually, I'd like to move these defines off into 225 1.1 dbj * configure somewhere 226 1.1 dbj * Darrin B Jewell <jewell (at) mit.edu> Thu Feb 5 03:50:58 1998 227 1.1 dbj */ 228 1.1 dbj /* ROM */ 229 1.1 dbj #define NEXT_P_EPROM (NEXT_SLOT_ID+0x00000000) 230 1.1 dbj #define NEXT_P_EPROM_BMAP (NEXT_SLOT_ID+0x01000000) 231 1.1 dbj #define NEXT_P_EPROM_SIZE (128 * 1024) 232 1.1 dbj 233 1.1 dbj /* device space */ 234 1.1 dbj #define NEXT_P_DEV_SPACE (NEXT_SLOT_ID+0x02000000) 235 1.1 dbj #define NEXT_P_DEV_BMAP (NEXT_SLOT_ID+0x02100000) 236 1.1 dbj #define NEXT_DEV_SPACE_SIZE 0x0001c000 237 1.1 dbj 238 1.1 dbj /* DMA control/status (writes MUST be 32-bit) */ 239 1.1 dbj #define NEXT_P_SCSI_CSR (NEXT_SLOT_ID+0x02000010) 240 1.1 dbj #define NEXT_P_SOUNDOUT_CSR (NEXT_SLOT_ID+0x02000040) 241 1.1 dbj #define NEXT_P_DISK_CSR (NEXT_SLOT_ID+0x02000050) 242 1.1 dbj #define NEXT_P_SOUNDIN_CSR (NEXT_SLOT_ID+0x02000080) 243 1.1 dbj #define NEXT_P_PRINTER_CSR (NEXT_SLOT_ID+0x02000090) 244 1.1 dbj #define NEXT_P_SCC_CSR (NEXT_SLOT_ID+0x020000c0) 245 1.1 dbj #define NEXT_P_DSP_CSR (NEXT_SLOT_ID+0x020000d0) 246 1.1 dbj #define NEXT_P_ENETX_CSR (NEXT_SLOT_ID+0x02000110) 247 1.1 dbj #define NEXT_P_ENETR_CSR (NEXT_SLOT_ID+0x02000150) 248 1.1 dbj #define NEXT_P_VIDEO_CSR (NEXT_SLOT_ID+0x02000180) 249 1.1 dbj #define NEXT_P_M2R_CSR (NEXT_SLOT_ID+0x020001d0) 250 1.1 dbj #define NEXT_P_R2M_CSR (NEXT_SLOT_ID+0x020001c0) 251 1.1 dbj 252 1.1 dbj /* DMA scratch pad (writes MUST be 32-bit) */ 253 1.1 dbj #define NEXT_P_VIDEO_SPAD (NEXT_SLOT_ID+0x02004180) 254 1.1 dbj #define NEXT_P_EVENT_SPAD (NEXT_SLOT_ID+0x0200418c) 255 1.1 dbj #define NEXT_P_M2M_SPAD (NEXT_SLOT_ID+0x020041e0) 256 1.1 dbj 257 1.1 dbj /* device registers */ 258 1.1 dbj #define NEXT_P_ENET (NEXT_SLOT_ID_BMAP+0x02006000) 259 1.1 dbj #define NEXT_P_DSP (NEXT_SLOT_ID_BMAP+0x02008000) 260 1.1 dbj #define NEXT_P_MON (NEXT_SLOT_ID+0x0200e000) 261 1.1 dbj #define NEXT_P_PRINTER (NEXT_SLOT_ID+0x0200f000) 262 1.1 dbj #define NEXT_P_DISK (NEXT_SLOT_ID_BMAP+0x02012000) 263 1.1 dbj #define NEXT_P_SCSI (NEXT_SLOT_ID_BMAP+0x02014000) 264 1.1 dbj #define NEXT_P_FLOPPY (NEXT_SLOT_ID_BMAP+0x02014100) 265 1.1 dbj #define NEXT_P_TIMER (NEXT_SLOT_ID_BMAP+0x02016000) 266 1.1 dbj #define NEXT_P_TIMER_CSR (NEXT_SLOT_ID_BMAP+0x02016004) 267 1.1 dbj #define NEXT_P_SCC (NEXT_SLOT_ID_BMAP+0x02018000) 268 1.1 dbj #define NEXT_P_SCC_CLK (NEXT_SLOT_ID_BMAP+0x02018004) 269 1.1 dbj #define NEXT_P_EVENTC (NEXT_SLOT_ID_BMAP+0x0201a000) 270 1.1 dbj #define NEXT_P_BMAP (NEXT_SLOT_ID+0x020c0000) 271 1.1 dbj /* All COLOR_FB registers are 1 byte wide */ 272 1.1 dbj #define NEXT_P_C16_DAC_0 (NEXT_SLOT_ID_BMAP+0x02018100) /* COLOR_FB - RAMDAC */ 273 1.1 dbj #define NEXT_P_C16_DAC_1 (NEXT_SLOT_ID_BMAP+0x02018101) 274 1.1 dbj #define NEXT_P_C16_DAC_2 (NEXT_SLOT_ID_BMAP+0x02018102) 275 1.1 dbj #define NEXT_P_C16_DAC_3 (NEXT_SLOT_ID_BMAP+0x02018103) 276 1.1 dbj #define NEXT_P_C16_CMD_REG (NEXT_SLOT_ID_BMAP+0x02018180) /* COLOR_FB - CSR */ 277 1.1 dbj 278 1.1 dbj /* system control registers */ 279 1.1 dbj #define NEXT_P_MEMTIMING (NEXT_SLOT_ID_BMAP+0x02006010) 280 1.1 dbj #define NEXT_P_INTRSTAT (NEXT_SLOT_ID+0x02007000) 281 1.1 dbj #define NEXT_P_INTRSTAT_CON 0x02007000 282 1.1 dbj #define NEXT_P_INTRMASK (NEXT_SLOT_ID+0x02007800) 283 1.1 dbj #define NEXT_P_INTRMASK_CON 0x02007800 284 1.1 dbj #define NEXT_P_SCR1 (NEXT_SLOT_ID+0x0200c000) 285 1.1 dbj #define NEXT_P_SCR1_CON 0x0200c000 286 1.1 dbj #define NEXT_P_SID 0x0200c800 /* NOT slot-relative */ 287 1.1 dbj #define NEXT_P_SCR2 (NEXT_SLOT_ID+0x0200d000) 288 1.1 dbj #define NEXT_P_SCR2_CON 0x0200d000 289 1.1 dbj #define NEXT_P_RMTINT (NEXT_SLOT_ID+0x0200d800) 290 1.1 dbj #define NEXT_P_BRIGHTNESS (NEXT_SLOT_ID_BMAP+0x02010000) 291 1.1 dbj #define NEXT_P_DRAM_TIMING (NEXT_SLOT_ID_BMAP+0x02018190) /* Warp 9C memory ctlr */ 292 1.1 dbj #define NEXT_P_VRAM_TIMING (NEXT_SLOT_ID_BMAP+0x02018198) /* Warp 9C memory ctlr */ 293 1.1 dbj 294 1.1 dbj /* memory */ 295 1.1 dbj #define NEXT_P_MAINMEM (NEXT_SLOT_ID+0x04000000) 296 1.1 dbj #define NEXT_P_MEMSIZE 0x04000000 297 1.1 dbj #define NEXT_P_VIDEOMEM (NEXT_SLOT_ID+0x0b000000) 298 1.1 dbj #define NEXT_P_VIDEOSIZE 0x0003a800 299 1.11.2.1 bouyer #if 0 300 1.1 dbj #define NEXT_P_C16_VIDEOMEM (NEXT_SLOT_ID+0x06000000) /* COLOR_FB */ 301 1.11.2.1 bouyer #endif 302 1.11.2.1 bouyer #define NEXT_P_C16_VIDEOMEM (0x2c000000) 303 1.1 dbj #define NEXT_P_C16_VIDEOSIZE 0x001D4000 /* COLOR_FB */ 304 1.1 dbj #define NEXT_P_WF4VIDEO (NEXT_SLOT_ID+0x0c000000) /* w A+B-AB function */ 305 1.1 dbj #define NEXT_P_WF3VIDEO (NEXT_SLOT_ID+0x0d000000) /* w (1-A)B function */ 306 1.1 dbj #define NEXT_P_WF2VIDEO (NEXT_SLOT_ID+0x0e000000) /* w ceil(A+B) function */ 307 1.1 dbj #define NEXT_P_WF1VIDEO (NEXT_SLOT_ID+0x0f000000) /* w AB function */ 308 1.1 dbj #define NEXT_P_WF4MEM (NEXT_SLOT_ID+0x10000000) /* w A+B-AB function */ 309 1.1 dbj #define NEXT_P_WF3MEM (NEXT_SLOT_ID+0x14000000) /* w (1-A)B function */ 310 1.1 dbj #define NEXT_P_WF2MEM (NEXT_SLOT_ID+0x18000000) /* w ceil(A+B) function */ 311 1.1 dbj #define NEXT_P_WF1MEM (NEXT_SLOT_ID+0x1c000000) /* w AB function */ 312 1.1 dbj #define NEXT_NMWF 4 /* # of memory write funcs */ 313 1.1 dbj 314 1.1 dbj /* 315 1.1 dbj * Interrupt structure. 316 1.1 dbj * BASE and BITS define the origin and length of the bit field in the 317 1.1 dbj * interrupt status/mask register for the particular interrupt level. 318 1.1 dbj * The first component of the interrupt device name indicates the bit 319 1.1 dbj * position in the interrupt status and mask registers; the second is the 320 1.1 dbj * interrupt level; the third is the bit index relative to the start of the 321 1.1 dbj * bit field. 322 1.1 dbj */ 323 1.1 dbj #define NEXT_I(l,i,b) (((b) << 8) | ((l) << 4) | (i)) 324 1.1 dbj #define NEXT_I_INDEX(i) ((i) & 0xf) 325 1.1 dbj #define NEXT_I_IPL(i) (((i) >> 4) & 7) 326 1.1 dbj #define NEXT_I_BIT(i) ( 1 << (((i) >> 8) & 0x1f)) 327 1.1 dbj 328 1.1 dbj #define NEXT_I_IPL7_BASE 0 329 1.1 dbj #define NEXT_I_IPL7_BITS 2 330 1.1 dbj #define NEXT_I_NMI NEXT_I(7,0,31) 331 1.1 dbj #define NEXT_I_PFAIL NEXT_I(7,1,30) 332 1.1 dbj 333 1.1 dbj #define NEXT_I_IPL6_BASE 2 334 1.1 dbj #define NEXT_I_IPL6_BITS 12 335 1.1 dbj #define NEXT_I_TIMER NEXT_I(6,0,29) 336 1.1 dbj #define NEXT_I_ENETX_DMA NEXT_I(6,1,28) 337 1.1 dbj #define NEXT_I_ENETR_DMA NEXT_I(6,2,27) 338 1.2 dbj #define NEXT_I_SCSI_DMA NEXT_I(6,3,26) 339 1.1 dbj #define NEXT_I_DISK_DMA NEXT_I(6,4,25) 340 1.1 dbj #define NEXT_I_PRINTER_DMA NEXT_I(6,5,24) 341 1.1 dbj #define NEXT_I_SOUND_OUT_DMA NEXT_I(6,6,23) 342 1.1 dbj #define NEXT_I_SOUND_IN_DMA NEXT_I(6,7,22) 343 1.1 dbj #define NEXT_I_SCC_DMA NEXT_I(6,8,21) 344 1.1 dbj #define NEXT_I_DSP_DMA NEXT_I(6,9,20) 345 1.1 dbj #define NEXT_I_M2R_DMA NEXT_I(6,10,19) 346 1.1 dbj #define NEXT_I_R2M_DMA NEXT_I(6,11,18) 347 1.1 dbj 348 1.1 dbj #define NEXT_I_IPL5_BASE 14 349 1.1 dbj #define NEXT_I_IPL5_BITS 3 350 1.1 dbj #define NEXT_I_SCC NEXT_I(5,0,17) 351 1.1 dbj #define NEXT_I_REMOTE NEXT_I(5,1,16) 352 1.1 dbj #define NEXT_I_BUS NEXT_I(5,2,15) 353 1.1 dbj 354 1.1 dbj #define NEXT_I_IPL4_BASE 17 355 1.1 dbj #define NEXT_I_IPL4_BITS 1 356 1.1 dbj #define NEXT_I_DSP_4 NEXT_I(4,0,14) 357 1.1 dbj 358 1.1 dbj #define NEXT_I_IPL3_BASE 18 359 1.1 dbj #define NEXT_I_IPL3_BITS 12 360 1.1 dbj #define NEXT_I_DISK NEXT_I(3,0,13) 361 1.1 dbj #define NEXT_I_C16_VIDEO NEXT_I(3,0,13) /* COLOR_FB - Steals old ESDI interrupt */ 362 1.1 dbj #define NEXT_I_SCSI NEXT_I(3,1,12) 363 1.1 dbj #define NEXT_I_PRINTER NEXT_I(3,2,11) 364 1.1 dbj #define NEXT_I_ENETX NEXT_I(3,3,10) 365 1.1 dbj #define NEXT_I_ENETR NEXT_I(3,4,9) 366 1.1 dbj #define NEXT_I_SOUND_OVRUN NEXT_I(3,5,8) 367 1.1 dbj #define NEXT_I_PHONE NEXT_I(3,6,7) 368 1.1 dbj #define NEXT_I_DSP_3 NEXT_I(3,7,6) 369 1.1 dbj #define NEXT_I_VIDEO NEXT_I(3,8,5) 370 1.1 dbj #define NEXT_I_MONITOR NEXT_I(3,9,4) 371 1.1 dbj #define NEXT_I_KYBD_MOUSE NEXT_I(3,10,3) 372 1.1 dbj #define NEXT_I_POWER NEXT_I(3,11,2) 373 1.1 dbj 374 1.1 dbj #define NEXT_I_IPL2_BASE 30 375 1.1 dbj #define NEXT_I_IPL2_BITS 1 376 1.1 dbj #define NEXT_I_SOFTINT1 NEXT_I(2,0,1) 377 1.1 dbj 378 1.1 dbj #define NEXT_I_IPL1_BASE 31 379 1.1 dbj #define NEXT_I_IPL1_BITS 1 380 1.1 dbj #define NEXT_I_SOFTINT0 NEXT_I(1,0,0) 381 1.1 dbj 382 1.1 dbj /****************************************************************/ 383 1.1 dbj 384 1.1 dbj /* physical memory sections */ 385 1.1 dbj #if 0 386 1.1 dbj #define ROMBASE (0x00000000) 387 1.1 dbj #endif 388 1.1 dbj 389 1.1 dbj #define INTIOBASE (0x02000000) 390 1.1 dbj #define INTIOTOP (0x02120000) 391 1.10 dbj #define MONOBASE (0x0b000000) 392 1.10 dbj #define MONOTOP (0x0b03a800) 393 1.11.2.1 bouyer #define COLORBASE (0x2c000000) 394 1.11.2.1 bouyer #define COLORTOP (0x2c1D4000) 395 1.7 dbj 396 1.1 dbj #define NEXT_INTR_BITS \ 397 1.4 dbj "\20\40NMI\37PFAIL\36TIMER\35ENETX_DMA\34ENETR_DMA\33SCSI_DMA\32DISK_DMA\31PRINTER_DMA\30SOUND_OUT_DMA\27SOUND_IN_DMA\26SCC_DMA\25DSP_DMA\24M2R_DMA\23R2M_DMA\22SCC\21REMOTE\20BUS\17DSP_4\16DISK|C16_VIDEO\15SCSI\14PRINTER\13ENETX\12ENETR\11SOUND_OVRUN\10PHONE\07DSP_3\06VIDEO\05MONITOR\04KYBD_MOUSE\03POWER\02SOFTINT1\01SOFTINT0" 398 1.1 dbj 399 1.1 dbj /* 400 1.1 dbj * Internal IO space: 401 1.1 dbj * 402 1.1 dbj * Ranges from 0x400000 to 0x600000 (IIOMAPSIZE). 403 1.1 dbj * 404 1.1 dbj * Internal IO space is mapped in the kernel from ``intiobase'' to 405 1.1 dbj * ``intiolimit'' (defined in locore.s). Since it is always mapped, 406 1.1 dbj * conversion between physical and kernel virtual addresses is easy. 407 1.1 dbj */ 408 1.1 dbj #define ISIIOVA(va) \ 409 1.1 dbj ((char *)(va) >= intiobase && (char *)(va) < intiolimit) 410 1.1 dbj #define IIOV(pa) ((int)(pa)-INTIOBASE+(int)intiobase) 411 1.1 dbj #define IIOP(va) ((int)(va)-(int)intiobase+INTIOBASE) 412 1.1 dbj #define IIOPOFF(pa) ((int)(pa)-INTIOBASE) 413 1.1 dbj #define IIOMAPSIZE btoc(INTIOTOP-INTIOBASE) /* 2mb */ 414 1.7 dbj 415 1.10 dbj /* mono fb space */ 416 1.10 dbj #define ISMONOVA(va) \ 417 1.10 dbj ((char *)(va) >= monobase && (char *)(va) < monolimit) 418 1.10 dbj #define MONOV(pa) ((int)(pa)-MONOBASE+(int)monobase) 419 1.10 dbj #define MONOP(va) ((int)(va)-(int)monobase+MONOBASE) 420 1.10 dbj #define MONOPOFF(pa) ((int)(pa)-MONOBASE) 421 1.10 dbj #define MONOMAPSIZE btoc(MONOTOP-MONOBASE) /* who cares */ 422 1.10 dbj 423 1.10 dbj /* color fb space */ 424 1.10 dbj #define ISCOLORVA(va) \ 425 1.10 dbj ((char *)(va) >= colorbase && (char *)(va) < colorlimit) 426 1.10 dbj #define COLORV(pa) ((int)(pa)-COLORBASE+(int)colorbase) 427 1.10 dbj #define COLORP(va) ((int)(va)-(int)colorbase+COLORBASE) 428 1.10 dbj #define COLORPOFF(pa) ((int)(pa)-COLORBASE) 429 1.10 dbj #define COLORMAPSIZE btoc(COLORTOP-COLORBASE) /* who cares */ 430 1.1 dbj 431 1.1 dbj #endif /* _CPU_MACHINE_ */ 432
Indexes created Mon Oct 13 08:09:50 GMT 2025