1/*- 2 * Copyright (C) 2006-2009 Semihalf, Rafal Jaworowski <raj@semihalf.com> 3 * Copyright (C) 2006 Semihalf, Marian Balakowicz <m8@semihalf.com> 4 * Copyright (C) 2006 Juniper Networks, Inc. 5 * All rights reserved. 6 * 7 * Redistribution and use in source and binary forms, with or without 8 * modification, are permitted provided that the following conditions 9 * are met: 10 * 1. Redistributions of source code must retain the above copyright 11 * notice, this list of conditions and the following disclaimer. 12 * 2. Redistributions in binary form must reproduce the above copyright 13 * notice, this list of conditions and the following disclaimer in the 14 * documentation and/or other materials provided with the distribution. 15 * 3. The name of the author may not be used to endorse or promote products 16 * derived from this software without specific prior written permission. 17 * 18 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 19 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 20 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN 21 * NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 22 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED 23 * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 24 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF 25 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING 26 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 27 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 28 * 29 * $FreeBSD$ 30 */ 31/*- 32 * Copyright (C) 1995, 1996 Wolfgang Solfrank. 33 * Copyright (C) 1995, 1996 TooLs GmbH. 34 * All rights reserved. 35 * 36 * Redistribution and use in source and binary forms, with or without 37 * modification, are permitted provided that the following conditions 38 * are met: 39 * 1. Redistributions of source code must retain the above copyright 40 * notice, this list of conditions and the following disclaimer. 41 * 2. Redistributions in binary form must reproduce the above copyright 42 * notice, this list of conditions and the following disclaimer in the 43 * documentation and/or other materials provided with the distribution. 44 * 3. All advertising materials mentioning features or use of this software 45 * must display the following acknowledgement: 46 * This product includes software developed by TooLs GmbH. 47 * 4. The name of TooLs GmbH may not be used to endorse or promote products 48 * derived from this software without specific prior written permission. 49 * 50 * THIS SOFTWARE IS PROVIDED BY TOOLS GMBH ``AS IS'' AND ANY EXPRESS OR 51 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 52 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 53 * IN NO EVENT SHALL TOOLS GMBH BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 54 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, 55 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; 56 * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, 57 * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR 58 * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF 59 * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 60 * 61 * from: $NetBSD: trap_subr.S,v 1.20 2002/04/22 23:20:08 kleink Exp $ 62 */ 63 64/* 65 * NOTICE: This is not a standalone file. to use it, #include it in 66 * your port's locore.S, like so: 67 * 68 * #include <powerpc/booke/trap_subr.S> 69 */ 70 71/* 72 * SPRG usage notes 73 * 74 * SPRG0 - pcpu pointer 75 * SPRG1 - all interrupts except TLB miss, critical, machine check 76 * SPRG2 - critical 77 * SPRG3 - machine check 78 * SPRG4-6 - scratch 79 * 80 */ 81 82/* Get the per-CPU data structure */ 83#define GET_CPUINFO(r) mfsprg0 r 84 85#define RES_GRANULE 32 86#define RES_LOCK 0 /* offset to the 'lock' word */ 87#define RES_RECURSE 4 /* offset to the 'recurse' word */ 88 89/* 90 * Standard interrupt prolog 91 * 92 * sprg_sp - SPRG{1-3} reg used to temporarily store the SP 93 * savearea - temp save area (pc_{tempsave, disisave, critsave, mchksave}) 94 * isrr0-1 - save restore registers with CPU state at interrupt time (may be 95 * SRR0-1, CSRR0-1, MCSRR0-1 96 * 97 * 1. saves in the given savearea: 98 * - R30-31 99 * - DEAR, ESR 100 * - xSRR0-1 101 * 102 * 2. saves CR -> R30 103 * 104 * 3. switches to kstack if needed 105 * 106 * 4. notes: 107 * - R31 can be used as scratch register until a new frame is layed on 108 * the stack with FRAME_SETUP 109 * 110 * - potential TLB miss: NO. Saveareas are always acessible via TLB1 111 * permanent entries, and within this prolog we do not dereference any 112 * locations potentially not in the TLB 113 */ 114#define STANDARD_PROLOG(sprg_sp, savearea, isrr0, isrr1) \ 115 mtspr sprg_sp, %r1; /* Save SP */ \ 116 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 117 stw %r30, (savearea+CPUSAVE_R30)(%r1); \ 118 stw %r31, (savearea+CPUSAVE_R31)(%r1); \ 119 mfdear %r30; \ 120 mfesr %r31; \ 121 stw %r30, (savearea+CPUSAVE_BOOKE_DEAR)(%r1); \ 122 stw %r31, (savearea+CPUSAVE_BOOKE_ESR)(%r1); \ 123 mfspr %r30, isrr0; \ 124 mfspr %r31, isrr1; /* MSR at interrupt time */ \ 125 stw %r30, (savearea+CPUSAVE_SRR0)(%r1); \ 126 stw %r31, (savearea+CPUSAVE_SRR1)(%r1); \ 127 isync; \ 128 mfspr %r1, sprg_sp; /* Restore SP */ \ 129 mfcr %r30; /* Save CR */ \ 130 /* switch to per-thread kstack if intr taken in user mode */ \ 131 mtcr %r31; /* MSR at interrupt time */ \ 132 bf 17, 1f; \ 133 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 134 lwz %r1, PC_CURPCB(%r1); /* Per-thread kernel stack */ \ 1351: 136 137#define STANDARD_CRIT_PROLOG(sprg_sp, savearea, isrr0, isrr1) \ 138 mtspr sprg_sp, %r1; /* Save SP */ \ 139 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 140 stw %r30, (savearea+CPUSAVE_R30)(%r1); \ 141 stw %r31, (savearea+CPUSAVE_R31)(%r1); \ 142 mfdear %r30; \ 143 mfesr %r31; \ 144 stw %r30, (savearea+CPUSAVE_BOOKE_DEAR)(%r1); \ 145 stw %r31, (savearea+CPUSAVE_BOOKE_ESR)(%r1); \ 146 mfspr %r30, isrr0; \ 147 mfspr %r31, isrr1; /* MSR at interrupt time */ \ 148 stw %r30, (savearea+CPUSAVE_SRR0)(%r1); \ 149 stw %r31, (savearea+CPUSAVE_SRR1)(%r1); \ 150 mfspr %r30, SPR_SRR0; \ 151 mfspr %r31, SPR_SRR1; /* MSR at interrupt time */ \ 152 stw %r30, (savearea+CPUSAVE_SRR0+8)(%r1); \ 153 stw %r31, (savearea+CPUSAVE_SRR1+8)(%r1); \ 154 isync; \ 155 mfspr %r1, sprg_sp; /* Restore SP */ \ 156 mfcr %r30; /* Save CR */ \ 157 /* switch to per-thread kstack if intr taken in user mode */ \ 158 mtcr %r31; /* MSR at interrupt time */ \ 159 bf 17, 1f; \ 160 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 161 lwz %r1, PC_CURPCB(%r1); /* Per-thread kernel stack */ \ 1621: 163 164/* 165 * FRAME_SETUP assumes: 166 * SPRG{1-3} SP at the time interrupt occured 167 * savearea r30-r31, DEAR, ESR, xSRR0-1 168 * r30 CR 169 * r31 scratch 170 * r1 kernel stack 171 * 172 * sprg_sp - SPRG reg containing SP at the time interrupt occured 173 * savearea - temp save 174 * exc - exception number (EXC_xxx) 175 * 176 * 1. sets a new frame 177 * 2. saves in the frame: 178 * - R0, R1 (SP at the time of interrupt), R2, LR, CR 179 * - R3-31 (R30-31 first restored from savearea) 180 * - XER, CTR, DEAR, ESR (from savearea), xSRR0-1 181 * 182 * Notes: 183 * - potential TLB miss: YES, since we make dereferences to kstack, which 184 * can happen not covered (we can have up to two DTLB misses if fortunate 185 * enough i.e. when kstack crosses page boundary and both pages are 186 * untranslated) 187 */ 188#define FRAME_SETUP(sprg_sp, savearea, exc) \ 189 mfspr %r31, sprg_sp; /* get saved SP */ \ 190 /* establish a new stack frame and put everything on it */ \ 191 stwu %r31, -FRAMELEN(%r1); \ 192 stw %r0, FRAME_0+8(%r1); /* save r0 in the trapframe */ \ 193 stw %r31, FRAME_1+8(%r1); /* save SP " " */ \ 194 stw %r2, FRAME_2+8(%r1); /* save r2 " " */ \ 195 mflr %r31; \ 196 stw %r31, FRAME_LR+8(%r1); /* save LR " " */ \ 197 stw %r30, FRAME_CR+8(%r1); /* save CR " " */ \ 198 GET_CPUINFO(%r2); \ 199 lwz %r30, (savearea+CPUSAVE_R30)(%r2); /* get saved r30 */ \ 200 lwz %r31, (savearea+CPUSAVE_R31)(%r2); /* get saved r31 */ \ 201 /* save R3-31 */ \ 202 stmw %r3, FRAME_3+8(%r1) ; \ 203 /* save DEAR, ESR */ \ 204 lwz %r28, (savearea+CPUSAVE_BOOKE_DEAR)(%r2); \ 205 lwz %r29, (savearea+CPUSAVE_BOOKE_ESR)(%r2); \ 206 stw %r28, FRAME_BOOKE_DEAR+8(%r1); \ 207 stw %r29, FRAME_BOOKE_ESR+8(%r1); \ 208 /* save XER, CTR, exc number */ \ 209 mfxer %r3; \ 210 mfctr %r4; \ 211 stw %r3, FRAME_XER+8(%r1); \ 212 stw %r4, FRAME_CTR+8(%r1); \ 213 li %r5, exc; \ 214 stw %r5, FRAME_EXC+8(%r1); \ 215 /* save DBCR0 */ \ 216 mfspr %r3, SPR_DBCR0; \ 217 stw %r3, FRAME_BOOKE_DBCR0+8(%r1); \ 218 /* save xSSR0-1 */ \ 219 lwz %r30, (savearea+CPUSAVE_SRR0)(%r2); \ 220 lwz %r31, (savearea+CPUSAVE_SRR1)(%r2); \ 221 stw %r30, FRAME_SRR0+8(%r1); \ 222 stw %r31, FRAME_SRR1+8(%r1) 223 224/* 225 * 226 * isrr0-1 - save restore registers to restore CPU state to (may be 227 * SRR0-1, CSRR0-1, MCSRR0-1 228 * 229 * Notes: 230 * - potential TLB miss: YES. The deref'd kstack may be not covered 231 */ 232#define FRAME_LEAVE(isrr0, isrr1) \ 233 /* restore CTR, XER, LR, CR */ \ 234 lwz %r4, FRAME_CTR+8(%r1); \ 235 lwz %r5, FRAME_XER+8(%r1); \ 236 lwz %r6, FRAME_LR+8(%r1); \ 237 lwz %r7, FRAME_CR+8(%r1); \ 238 mtctr %r4; \ 239 mtxer %r5; \ 240 mtlr %r6; \ 241 mtcr %r7; \ 242 /* restore DBCR0 */ \ 243 lwz %r4, FRAME_BOOKE_DBCR0+8(%r1); \ 244 mtspr SPR_DBCR0, %r4; \ 245 /* restore xSRR0-1 */ \ 246 lwz %r30, FRAME_SRR0+8(%r1); \ 247 lwz %r31, FRAME_SRR1+8(%r1); \ 248 mtspr isrr0, %r30; \ 249 mtspr isrr1, %r31; \ 250 /* restore R2-31, SP */ \ 251 lmw %r2, FRAME_2+8(%r1) ; \ 252 lwz %r0, FRAME_0+8(%r1); \ 253 lwz %r1, FRAME_1+8(%r1); \ 254 isync 255 256/* 257 * TLB miss prolog 258 * 259 * saves LR, CR, SRR0-1, R20-31 in the TLBSAVE area 260 * 261 * Notes: 262 * - potential TLB miss: NO. It is crucial that we do not generate a TLB 263 * miss within the TLB prolog itself! 264 * - TLBSAVE is always translated 265 */ 266#define TLB_PROLOG \ 267 mtsprg4 %r1; /* Save SP */ \ 268 mtsprg5 %r28; \ 269 mtsprg6 %r29; \ 270 /* calculate TLB nesting level and TLBSAVE instance address */ \ 271 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 272 lwz %r28, PC_BOOKE_TLB_LEVEL(%r1); \ 273 rlwinm %r29, %r28, 6, 23, 25; /* 4 x TLBSAVE_LEN */ \ 274 addi %r28, %r28, 1; \ 275 stw %r28, PC_BOOKE_TLB_LEVEL(%r1); \ 276 addi %r29, %r29, PC_BOOKE_TLBSAVE@l; \ 277 add %r1, %r1, %r29; /* current TLBSAVE ptr */ \ 278 \ 279 /* save R20-31 */ \ 280 mfsprg5 %r28; \ 281 mfsprg6 %r29; \ 282 stmw %r20, (TLBSAVE_BOOKE_R20)(%r1); \ 283 /* save LR, CR */ \ 284 mflr %r30; \ 285 mfcr %r31; \ 286 stw %r30, (TLBSAVE_BOOKE_LR)(%r1); \ 287 stw %r31, (TLBSAVE_BOOKE_CR)(%r1); \ 288 /* save SRR0-1 */ \ 289 mfsrr0 %r30; /* execution addr at interrupt time */ \ 290 mfsrr1 %r31; /* MSR at interrupt time*/ \ 291 stw %r30, (TLBSAVE_BOOKE_SRR0)(%r1); /* save SRR0 */ \ 292 stw %r31, (TLBSAVE_BOOKE_SRR1)(%r1); /* save SRR1 */ \ 293 isync; \ 294 mfsprg4 %r1 295 296/* 297 * restores LR, CR, SRR0-1, R20-31 from the TLBSAVE area 298 * 299 * same notes as for the TLB_PROLOG 300 */ 301#define TLB_RESTORE \ 302 mtsprg4 %r1; /* Save SP */ \ 303 GET_CPUINFO(%r1); /* Per-cpu structure */ \ 304 /* calculate TLB nesting level and TLBSAVE instance addr */ \ 305 lwz %r28, PC_BOOKE_TLB_LEVEL(%r1); \ 306 subi %r28, %r28, 1; \ 307 stw %r28, PC_BOOKE_TLB_LEVEL(%r1); \ 308 rlwinm %r29, %r28, 6, 23, 25; /* 4 x TLBSAVE_LEN */ \ 309 addi %r29, %r29, PC_BOOKE_TLBSAVE@l; \ 310 add %r1, %r1, %r29; \ 311 \ 312 /* restore LR, CR */ \ 313 lwz %r30, (TLBSAVE_BOOKE_LR)(%r1); \ 314 lwz %r31, (TLBSAVE_BOOKE_CR)(%r1); \ 315 mtlr %r30; \ 316 mtcr %r31; \ 317 /* restore SRR0-1 */ \ 318 lwz %r30, (TLBSAVE_BOOKE_SRR0)(%r1); \ 319 lwz %r31, (TLBSAVE_BOOKE_SRR1)(%r1); \ 320 mtsrr0 %r30; \ 321 mtsrr1 %r31; \ 322 /* restore R20-31 */ \ 323 lmw %r20, (TLBSAVE_BOOKE_R20)(%r1); \ 324 mfsprg4 %r1 325 326#ifdef SMP 327#define TLB_LOCK \ 328 GET_CPUINFO(%r20); \ 329 lwz %r21, PC_CURTHREAD(%r20); \ 330 lwz %r22, PC_BOOKE_TLB_LOCK(%r20); \ 331 \ 3321: lwarx %r23, 0, %r22; \ 333 cmpwi %r23, TLB_UNLOCKED; \ 334 beq 2f; \ 335 \ 336 /* check if this is recursion */ \ 337 cmplw cr0, %r21, %r23; \ 338 bne- 1b; \ 339 \ 3402: /* try to acquire lock */ \ 341 stwcx. %r21, 0, %r22; \ 342 bne- 1b; \ 343 \ 344 /* got it, update recursion counter */ \ 345 lwz %r21, RES_RECURSE(%r22); \ 346 addi %r21, %r21, 1; \ 347 stw %r21, RES_RECURSE(%r22); \ 348 isync; \ 349 msync 350 351#define TLB_UNLOCK \ 352 GET_CPUINFO(%r20); \ 353 lwz %r21, PC_CURTHREAD(%r20); \ 354 lwz %r22, PC_BOOKE_TLB_LOCK(%r20); \ 355 \ 356 /* update recursion counter */ \ 357 lwz %r23, RES_RECURSE(%r22); \ 358 subi %r23, %r23, 1; \ 359 stw %r23, RES_RECURSE(%r22); \ 360 \ 361 cmpwi %r23, 0; \ 362 bne 1f; \ 363 isync; \ 364 msync; \ 365 \ 366 /* release the lock */ \ 367 li %r23, TLB_UNLOCKED; \ 368 stw %r23, 0(%r22); \ 3691: isync; \ 370 msync 371#else 372#define TLB_LOCK 373#define TLB_UNLOCK 374#endif /* SMP */ 375 376#define INTERRUPT(label) \ 377 .globl label; \ 378 .align 5; \ 379 CNAME(label): 380 381/* 382 * Interrupt handling routines in BookE can be flexibly placed and do not have 383 * to live in pre-defined vectors location. Note they need to be TLB-mapped at 384 * all times in order to be able to handle exceptions. We thus arrange for 385 * them to be part of kernel text which is always TLB-accessible. 386 * 387 * The interrupt handling routines have to be 16 bytes aligned: we align them 388 * to 32 bytes (cache line length) which supposedly performs better. 389 * 390 */ 391 .text 392 .globl CNAME(interrupt_vector_base) 393 .align 5 394interrupt_vector_base: 395 396/***************************************************************************** 397 * Critical input interrupt 398 ****************************************************************************/ 399INTERRUPT(int_critical_input) 400 STANDARD_PROLOG(SPR_SPRG2, PC_BOOKE_CRITSAVE, SPR_CSRR0, SPR_CSRR1) 401 FRAME_SETUP(SPR_SPRG2, PC_BOOKE_CRITSAVE, EXC_CRIT) 402 addi %r3, %r1, 8 403 bl CNAME(powerpc_crit_interrupt) 404 FRAME_LEAVE(SPR_CSRR0, SPR_CSRR1) 405 rfci 406 407 408/***************************************************************************** 409 * Machine check interrupt 410 ****************************************************************************/ 411INTERRUPT(int_machine_check) 412 STANDARD_PROLOG(SPR_SPRG3, PC_BOOKE_MCHKSAVE, SPR_MCSRR0, SPR_MCSRR1) 413 FRAME_SETUP(SPR_SPRG3, PC_BOOKE_MCHKSAVE, EXC_MCHK) 414 addi %r3, %r1, 8 415 bl CNAME(powerpc_mchk_interrupt) 416 FRAME_LEAVE(SPR_MCSRR0, SPR_MCSRR1) 417 rfmci 418 419 420/***************************************************************************** 421 * Data storage interrupt 422 ****************************************************************************/ 423INTERRUPT(int_data_storage) 424 STANDARD_PROLOG(SPR_SPRG1, PC_DISISAVE, SPR_SRR0, SPR_SRR1) 425 FRAME_SETUP(SPR_SPRG1, PC_DISISAVE, EXC_DSI) 426 b trap_common 427 428 429/***************************************************************************** 430 * Instruction storage interrupt 431 ****************************************************************************/ 432INTERRUPT(int_instr_storage) 433 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 434 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_ISI) 435 b trap_common 436 437 438/***************************************************************************** 439 * External input interrupt 440 ****************************************************************************/ 441INTERRUPT(int_external_input) 442 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 443 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_EXI) 444 addi %r3, %r1, 8 445 bl CNAME(powerpc_extr_interrupt) 446 b trapexit 447 448 449INTERRUPT(int_alignment) 450 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 451 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_ALI) 452 b trap_common 453 454 455INTERRUPT(int_program) 456 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 457 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_PGM) 458 b trap_common 459 460 461/***************************************************************************** 462 * System call 463 ****************************************************************************/ 464INTERRUPT(int_syscall) 465 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 466 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_SC) 467 b trap_common 468 469 470/***************************************************************************** 471 * Decrementer interrupt 472 ****************************************************************************/ 473INTERRUPT(int_decrementer) 474 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 475 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_DECR) 476 addi %r3, %r1, 8 477 bl CNAME(powerpc_decr_interrupt) 478 b trapexit 479 480 481/***************************************************************************** 482 * Fixed interval timer 483 ****************************************************************************/ 484INTERRUPT(int_fixed_interval_timer) 485 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 486 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_FIT) 487 b trap_common 488 489 490/***************************************************************************** 491 * Watchdog interrupt 492 ****************************************************************************/ 493INTERRUPT(int_watchdog) 494 STANDARD_PROLOG(SPR_SPRG1, PC_TEMPSAVE, SPR_SRR0, SPR_SRR1) 495 FRAME_SETUP(SPR_SPRG1, PC_TEMPSAVE, EXC_WDOG) 496 b trap_common 497 498 499/***************************************************************************** 500 * Data TLB miss interrupt 501 * 502 * There can be nested TLB misses - while handling a TLB miss we reference 503 * data structures that may be not covered by translations. We support up to 504 * TLB_NESTED_MAX-1 nested misses. 505 * 506 * Registers use: 507 * r31 - dear 508 * r30 - unused 509 * r29 - saved mas0 510 * r28 - saved mas1 511 * r27 - saved mas2 512 * r26 - pmap address 513 * r25 - pte address 514 * 515 * r20:r23 - scratch registers 516 ****************************************************************************/ 517INTERRUPT(int_data_tlb_error) 518 TLB_PROLOG 519 TLB_LOCK 520 521 mfdear %r31 522 523 /* 524 * Save MAS0-MAS2 registers. There might be another tlb miss during 525 * pte lookup overwriting current contents (which was hw filled). 526 */ 527 mfspr %r29, SPR_MAS0 528 mfspr %r28, SPR_MAS1 529 mfspr %r27, SPR_MAS2 530 531 /* Check faulting address. */ 532 lis %r21, VM_MAXUSER_ADDRESS@h 533 ori %r21, %r21, VM_MAXUSER_ADDRESS@l 534 cmplw cr0, %r31, %r21 535 blt search_user_pmap 536 537 /* If it's kernel address, allow only supervisor mode misses. */ 538 mfsrr1 %r21 539 mtcr %r21 540 bt 17, search_failed /* check MSR[PR] */ 541 542search_kernel_pmap: 543 /* Load r26 with kernel_pmap address */ 544 lis %r26, kernel_pmap_store@h 545 ori %r26, %r26, kernel_pmap_store@l 546 547 /* Force kernel tid, set TID to 0 in MAS1. */ 548 li %r21, 0 549 rlwimi %r28, %r21, 0, 8, 15 /* clear TID bits */ 550 551tlb_miss_handle: 552 /* This may result in nested tlb miss. */ 553 bl pte_lookup /* returns PTE address in R25 */ 554 555 cmpwi %r25, 0 /* pte found? */ 556 beq search_failed 557 558 /* Finish up, write TLB entry. */ 559 bl tlb_fill_entry 560 561tlb_miss_return: 562 TLB_UNLOCK 563 TLB_RESTORE 564 rfi 565 566search_user_pmap: 567 /* Load r26 with current user space process pmap */ 568 GET_CPUINFO(%r26) 569 lwz %r26, PC_CURPMAP(%r26) 570 571 b tlb_miss_handle 572 573search_failed: 574 /* 575 * Whenever we don't find a TLB mapping in PT, set a TLB0 entry with 576 * the faulting virtual address anyway, but put a fake RPN and no 577 * access rights. This should cause a following {D,I}SI exception. 578 */ 579 lis %r23, 0xffff0000@h /* revoke all permissions */ 580 581 /* Load MAS registers. */ 582 mtspr SPR_MAS0, %r29 583 isync 584 mtspr SPR_MAS1, %r28 585 isync 586 mtspr SPR_MAS2, %r27 587 isync 588 mtspr SPR_MAS3, %r23 589 isync 590 591 tlbwe 592 msync 593 isync 594 b tlb_miss_return 595 596/***************************************************************************** 597 * 598 * Return pte address that corresponds to given pmap/va. If there is no valid 599 * entry return 0. 600 * 601 * input: r26 - pmap 602 * input: r31 - dear 603 * output: r25 - pte address 604 * 605 * scratch regs used: r21 606 * 607 ****************************************************************************/ 608pte_lookup: 609 cmpwi %r26, 0 610 beq 1f /* fail quickly if pmap is invalid */ 611 612 srwi %r21, %r31, PDIR_SHIFT /* pdir offset */ 613 slwi %r21, %r21, PDIR_ENTRY_SHIFT /* multiply by pdir entry size */ 614 615 addi %r25, %r26, PM_PDIR /* pmap pm_dir[] address */ 616 add %r25, %r25, %r21 /* offset within pm_pdir[] table */ 617 /* 618 * Get ptbl address, i.e. pmap->pm_pdir[pdir_idx] 619 * This load may cause a Data TLB miss for non-kernel pmap! 620 */ 621 lwz %r25, 0(%r25) 622 cmpwi %r25, 0 623 beq 2f 624 625 lis %r21, PTBL_MASK@h 626 ori %r21, %r21, PTBL_MASK@l 627 and %r21, %r21, %r31 628 629 /* ptbl offset, multiply by ptbl entry size */ 630 srwi %r21, %r21, (PTBL_SHIFT - PTBL_ENTRY_SHIFT) 631 632 add %r25, %r25, %r21 /* address of pte entry */ 633 /* 634 * Get pte->flags 635 * This load may cause a Data TLB miss for non-kernel pmap! 636 */ 637 lwz %r21, PTE_FLAGS(%r25) 638 andis. %r21, %r21, PTE_VALID@h 639 bne 2f 6401: 641 li %r25, 0 6422: 643 blr 644 645/***************************************************************************** 646 * 647 * Load MAS1-MAS3 registers with data, write TLB entry 648 * 649 * input: 650 * r29 - mas0 651 * r28 - mas1 652 * r27 - mas2 653 * r25 - pte 654 * 655 * output: none 656 * 657 * scratch regs: r21-r23 658 * 659 ****************************************************************************/ 660tlb_fill_entry: 661 /* 662 * Update PTE flags: we have to do it atomically, as pmap_protect() 663 * running on other CPUs could attempt to update the flags at the same 664 * time. 665 */ 666 li %r23, PTE_FLAGS 6671: 668 lwarx %r21, %r23, %r25 /* get pte->flags */ 669 oris %r21, %r21, PTE_REFERENCED@h /* set referenced bit */ 670 671 andi. %r22, %r21, (PTE_UW | PTE_UW)@l /* check if writable */ 672 beq 2f 673 oris %r21, %r21, PTE_MODIFIED@h /* set modified bit */ 6742: 675 stwcx. %r21, %r23, %r25 /* write it back */ 676 bne- 1b 677 678 /* Update MAS2. */ 679 rlwimi %r27, %r21, 0, 27, 30 /* insert WIMG bits from pte */ 680 681 /* Setup MAS3 value in r23. */ 682 lwz %r23, PTE_RPN(%r25) /* get pte->rpn */ 683 684 rlwimi %r23, %r21, 24, 26, 31 /* insert protection bits from pte */ 685 686 /* Load MAS registers. */ 687 mtspr SPR_MAS0, %r29 688 isync 689 mtspr SPR_MAS1, %r28 690 isync 691 mtspr SPR_MAS2, %r27 692 isync 693 mtspr SPR_MAS3, %r23 694 isync 695 696 tlbwe 697 isync 698 msync 699 blr 700 701/***************************************************************************** 702 * Instruction TLB miss interrupt 703 * 704 * Same notes as for the Data TLB miss 705 ****************************************************************************/ 706INTERRUPT(int_inst_tlb_error) 707 TLB_PROLOG 708 TLB_LOCK 709 710 mfsrr0 %r31 /* faulting address */ 711 712 /* 713 * Save MAS0-MAS2 registers. There might be another tlb miss during pte 714 * lookup overwriting current contents (which was hw filled). 715 */ 716 mfspr %r29, SPR_MAS0 717 mfspr %r28, SPR_MAS1 718 mfspr %r27, SPR_MAS2 719 720 mfsrr1 %r21 721 mtcr %r21 722 723 /* check MSR[PR] */ 724 bt 17, search_user_pmap 725 b search_kernel_pmap 726 727 728 .globl interrupt_vector_top 729interrupt_vector_top: 730 731/***************************************************************************** 732 * Debug interrupt 733 ****************************************************************************/ 734INTERRUPT(int_debug) 735 STANDARD_CRIT_PROLOG(SPR_SPRG2, PC_BOOKE_CRITSAVE, SPR_CSRR0, SPR_CSRR1) 736 FRAME_SETUP(SPR_SPRG2, PC_BOOKE_CRITSAVE, EXC_DEBUG) 737 lwz %r3, (PC_BOOKE_CRITSAVE+CPUSAVE_SRR0)(%r2); 738 lis %r4, interrupt_vector_base@ha 739 addi %r4, %r4, interrupt_vector_base@l 740 cmplw cr0, %r3, %r4 741 blt 1f 742 lis %r4, interrupt_vector_top@ha 743 addi %r4, %r4, interrupt_vector_top@l 744 cmplw cr0, %r3, %r4 745 bge 1f 746 /* Disable single-stepping for the interrupt handlers. */ 747 lwz %r3, FRAME_SRR1+8(%r1); 748 rlwinm %r3, %r3, 0, 23, 21 749 stw %r3, FRAME_SRR1+8(%r1); 750 /* Restore srr0 and srr1 as they could have been clobbered. */ 751 lwz %r3, (PC_BOOKE_CRITSAVE+CPUSAVE_SRR0+8)(%r2); 752 mtspr SPR_SRR0, %r3 753 lwz %r4, (PC_BOOKE_CRITSAVE+CPUSAVE_SRR1+8)(%r2); 754 mtspr SPR_SRR1, %r4 755 b 9f 7561: 757 addi %r3, %r1, 8 758 bl CNAME(trap) 759 /* 760 * Handle ASTs, needed for proper support of single-stepping. 761 * We actually need to return to the process with an rfi. 762 */ 763 b trapexit 7649: 765 FRAME_LEAVE(SPR_CSRR0, SPR_CSRR1) 766 rfci 767 768 769/***************************************************************************** 770 * Common trap code 771 ****************************************************************************/ 772trap_common: 773 /* Call C trap dispatcher */ 774 addi %r3, %r1, 8 775 bl CNAME(trap) 776 777 .globl CNAME(trapexit) /* exported for db_backtrace use */ 778CNAME(trapexit): 779 /* disable interrupts */ 780 wrteei 0 781 782 /* Test AST pending - makes sense for user process only */ 783 lwz %r5, FRAME_SRR1+8(%r1) 784 mtcr %r5 785 bf 17, 1f 786 787 GET_CPUINFO(%r3) 788 lwz %r4, PC_CURTHREAD(%r3) 789 lwz %r4, TD_FLAGS(%r4) 790 lis %r5, (TDF_ASTPENDING | TDF_NEEDRESCHED)@h 791 ori %r5, %r5, (TDF_ASTPENDING | TDF_NEEDRESCHED)@l 792 and. %r4, %r4, %r5 793 beq 1f 794 795 /* re-enable interrupts before calling ast() */ 796 wrteei 1 797 798 addi %r3, %r1, 8 799 bl CNAME(ast) 800 .globl CNAME(asttrapexit) /* db_backtrace code sentinel #2 */ 801CNAME(asttrapexit): 802 b trapexit /* test ast ret value ? */ 8031: 804 FRAME_LEAVE(SPR_SRR0, SPR_SRR1) 805 rfi 806 807 808#if defined(KDB) 809/* 810 * Deliberate entry to dbtrap 811 */ 812 .globl CNAME(breakpoint) 813CNAME(breakpoint): 814 mtsprg1 %r1 815 mfmsr %r3 816 mtsrr1 %r3 817 andi. %r3, %r3, ~(PSL_EE | PSL_ME)@l 818 mtmsr %r3 /* disable interrupts */ 819 isync 820 GET_CPUINFO(%r3) 821 stw %r30, (PC_DBSAVE+CPUSAVE_R30)(%r3) 822 stw %r31, (PC_DBSAVE+CPUSAVE_R31)(%r3) 823 824 mflr %r31 825 mtsrr0 %r31 826 827 mfdear %r30 828 mfesr %r31 829 stw %r30, (PC_DBSAVE+CPUSAVE_BOOKE_DEAR)(%r3) 830 stw %r31, (PC_DBSAVE+CPUSAVE_BOOKE_ESR)(%r3) 831 832 mfsrr0 %r30 833 mfsrr1 %r31 834 stw %r30, (PC_DBSAVE+CPUSAVE_SRR0)(%r3) 835 stw %r31, (PC_DBSAVE+CPUSAVE_SRR1)(%r3) 836 isync 837 838 mfcr %r30 839 840/* 841 * Now the kdb trap catching code. 842 */ 843dbtrap: 844 FRAME_SETUP(SPR_SPRG1, PC_DBSAVE, EXC_DEBUG) 845/* Call C trap code: */ 846 addi %r3, %r1, 8 847 bl CNAME(db_trap_glue) 848 or. %r3, %r3, %r3 849 bne dbleave 850/* This wasn't for KDB, so switch to real trap: */ 851 b trap_common 852 853dbleave: 854 FRAME_LEAVE(SPR_SRR0, SPR_SRR1) 855 rfi 856#endif /* KDB */ 857 858#ifdef SMP 859ENTRY(tlb_lock) 860 GET_CPUINFO(%r5) 861 lwz %r5, PC_CURTHREAD(%r5) 8621: lwarx %r4, 0, %r3 863 cmpwi %r4, TLB_UNLOCKED 864 bne 1b 865 stwcx. %r5, 0, %r3 866 bne- 1b 867 isync 868 msync 869 blr 870 871ENTRY(tlb_unlock) 872 isync 873 msync 874 li %r4, TLB_UNLOCKED 875 stw %r4, 0(%r3) 876 isync 877 msync 878 blr 879 880/* 881 * TLB miss spin locks. For each CPU we have a reservation granule (32 bytes); 882 * only a single word from this granule will actually be used as a spin lock 883 * for mutual exclusion between TLB miss handler and pmap layer that 884 * manipulates page table contents. 885 */ 886 .data 887 .align 5 888GLOBAL(tlb0_miss_locks) 889 .space RES_GRANULE * MAXCPU 890#endif 891