1 /* 2 * ARM virtual CPU header 3 * 4 * Copyright (c) 2003 Fabrice Bellard 5 * 6 * This library is free software; you can redistribute it and/or 7 * modify it under the terms of the GNU Lesser General Public 8 * License as published by the Free Software Foundation; either 9 * version 2 of the License, or (at your option) any later version. 10 * 11 * This library is distributed in the hope that it will be useful, 12 * but WITHOUT ANY WARRANTY; without even the implied warranty of 13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 14 * Lesser General Public License for more details. 15 * 16 * You should have received a copy of the GNU Lesser General Public 17 * License along with this library; if not, see <http://www.gnu.org/licenses/>. 18 */ 19 20 #ifndef ARM_CPU_H 21 #define ARM_CPU_H 22 23 #include "kvm-consts.h" 24 #include "hw/registerfields.h" 25 26 #if defined(TARGET_AARCH64) 27 /* AArch64 definitions */ 28 # define TARGET_LONG_BITS 64 29 #else 30 # define TARGET_LONG_BITS 32 31 #endif 32 33 /* ARM processors have a weak memory model */ 34 #define TCG_GUEST_DEFAULT_MO (0) 35 36 #define CPUArchState struct CPUARMState 37 38 #include "qemu-common.h" 39 #include "cpu-qom.h" 40 #include "exec/cpu-defs.h" 41 42 #define EXCP_UDEF 1 /* undefined instruction */ 43 #define EXCP_SWI 2 /* software interrupt */ 44 #define EXCP_PREFETCH_ABORT 3 45 #define EXCP_DATA_ABORT 4 46 #define EXCP_IRQ 5 47 #define EXCP_FIQ 6 48 #define EXCP_BKPT 7 49 #define EXCP_EXCEPTION_EXIT 8 /* Return from v7M exception. */ 50 #define EXCP_KERNEL_TRAP 9 /* Jumped to kernel code page. */ 51 #define EXCP_HVC 11 /* HyperVisor Call */ 52 #define EXCP_HYP_TRAP 12 53 #define EXCP_SMC 13 /* Secure Monitor Call */ 54 #define EXCP_VIRQ 14 55 #define EXCP_VFIQ 15 56 #define EXCP_SEMIHOST 16 /* semihosting call */ 57 #define EXCP_NOCP 17 /* v7M NOCP UsageFault */ 58 #define EXCP_INVSTATE 18 /* v7M INVSTATE UsageFault */ 59 /* NB: add new EXCP_ defines to the array in arm_log_exception() too */ 60 61 #define ARMV7M_EXCP_RESET 1 62 #define ARMV7M_EXCP_NMI 2 63 #define ARMV7M_EXCP_HARD 3 64 #define ARMV7M_EXCP_MEM 4 65 #define ARMV7M_EXCP_BUS 5 66 #define ARMV7M_EXCP_USAGE 6 67 #define ARMV7M_EXCP_SECURE 7 68 #define ARMV7M_EXCP_SVC 11 69 #define ARMV7M_EXCP_DEBUG 12 70 #define ARMV7M_EXCP_PENDSV 14 71 #define ARMV7M_EXCP_SYSTICK 15 72 73 /* For M profile, some registers are banked secure vs non-secure; 74 * these are represented as a 2-element array where the first element 75 * is the non-secure copy and the second is the secure copy. 76 * When the CPU does not have implement the security extension then 77 * only the first element is used. 78 * This means that the copy for the current security state can be 79 * accessed via env->registerfield[env->v7m.secure] (whether the security 80 * extension is implemented or not). 81 */ 82 enum { 83 M_REG_NS = 0, 84 M_REG_S = 1, 85 M_REG_NUM_BANKS = 2, 86 }; 87 88 /* ARM-specific interrupt pending bits. */ 89 #define CPU_INTERRUPT_FIQ CPU_INTERRUPT_TGT_EXT_1 90 #define CPU_INTERRUPT_VIRQ CPU_INTERRUPT_TGT_EXT_2 91 #define CPU_INTERRUPT_VFIQ CPU_INTERRUPT_TGT_EXT_3 92 93 /* The usual mapping for an AArch64 system register to its AArch32 94 * counterpart is for the 32 bit world to have access to the lower 95 * half only (with writes leaving the upper half untouched). It's 96 * therefore useful to be able to pass TCG the offset of the least 97 * significant half of a uint64_t struct member. 98 */ 99 #ifdef HOST_WORDS_BIGENDIAN 100 #define offsetoflow32(S, M) (offsetof(S, M) + sizeof(uint32_t)) 101 #define offsetofhigh32(S, M) offsetof(S, M) 102 #else 103 #define offsetoflow32(S, M) offsetof(S, M) 104 #define offsetofhigh32(S, M) (offsetof(S, M) + sizeof(uint32_t)) 105 #endif 106 107 /* Meanings of the ARMCPU object's four inbound GPIO lines */ 108 #define ARM_CPU_IRQ 0 109 #define ARM_CPU_FIQ 1 110 #define ARM_CPU_VIRQ 2 111 #define ARM_CPU_VFIQ 3 112 113 #define NB_MMU_MODES 8 114 /* ARM-specific extra insn start words: 115 * 1: Conditional execution bits 116 * 2: Partial exception syndrome for data aborts 117 */ 118 #define TARGET_INSN_START_EXTRA_WORDS 2 119 120 /* The 2nd extra word holding syndrome info for data aborts does not use 121 * the upper 6 bits nor the lower 14 bits. We mask and shift it down to 122 * help the sleb128 encoder do a better job. 123 * When restoring the CPU state, we shift it back up. 124 */ 125 #define ARM_INSN_START_WORD2_MASK ((1 << 26) - 1) 126 #define ARM_INSN_START_WORD2_SHIFT 14 127 128 /* We currently assume float and double are IEEE single and double 129 precision respectively. 130 Doing runtime conversions is tricky because VFP registers may contain 131 integer values (eg. as the result of a FTOSI instruction). 132 s<2n> maps to the least significant half of d<n> 133 s<2n+1> maps to the most significant half of d<n> 134 */ 135 136 /** 137 * DynamicGDBXMLInfo: 138 * @desc: Contains the XML descriptions. 139 * @num_cpregs: Number of the Coprocessor registers seen by GDB. 140 * @cpregs_keys: Array that contains the corresponding Key of 141 * a given cpreg with the same order of the cpreg in the XML description. 142 */ 143 typedef struct DynamicGDBXMLInfo { 144 char *desc; 145 int num_cpregs; 146 uint32_t *cpregs_keys; 147 } DynamicGDBXMLInfo; 148 149 /* CPU state for each instance of a generic timer (in cp15 c14) */ 150 typedef struct ARMGenericTimer { 151 uint64_t cval; /* Timer CompareValue register */ 152 uint64_t ctl; /* Timer Control register */ 153 } ARMGenericTimer; 154 155 #define GTIMER_PHYS 0 156 #define GTIMER_VIRT 1 157 #define GTIMER_HYP 2 158 #define GTIMER_SEC 3 159 #define NUM_GTIMERS 4 160 161 typedef struct { 162 uint64_t raw_tcr; 163 uint32_t mask; 164 uint32_t base_mask; 165 } TCR; 166 167 /* Define a maximum sized vector register. 168 * For 32-bit, this is a 128-bit NEON/AdvSIMD register. 169 * For 64-bit, this is a 2048-bit SVE register. 170 * 171 * Note that the mapping between S, D, and Q views of the register bank 172 * differs between AArch64 and AArch32. 173 * In AArch32: 174 * Qn = regs[n].d[1]:regs[n].d[0] 175 * Dn = regs[n / 2].d[n & 1] 176 * Sn = regs[n / 4].d[n % 4 / 2], 177 * bits 31..0 for even n, and bits 63..32 for odd n 178 * (and regs[16] to regs[31] are inaccessible) 179 * In AArch64: 180 * Zn = regs[n].d[*] 181 * Qn = regs[n].d[1]:regs[n].d[0] 182 * Dn = regs[n].d[0] 183 * Sn = regs[n].d[0] bits 31..0 184 * Hn = regs[n].d[0] bits 15..0 185 * 186 * This corresponds to the architecturally defined mapping between 187 * the two execution states, and means we do not need to explicitly 188 * map these registers when changing states. 189 * 190 * Align the data for use with TCG host vector operations. 191 */ 192 193 #ifdef TARGET_AARCH64 194 # define ARM_MAX_VQ 16 195 #else 196 # define ARM_MAX_VQ 1 197 #endif 198 199 typedef struct ARMVectorReg { 200 uint64_t d[2 * ARM_MAX_VQ] QEMU_ALIGNED(16); 201 } ARMVectorReg; 202 203 /* In AArch32 mode, predicate registers do not exist at all. */ 204 #ifdef TARGET_AARCH64 205 typedef struct ARMPredicateReg { 206 uint64_t p[2 * ARM_MAX_VQ / 8] QEMU_ALIGNED(16); 207 } ARMPredicateReg; 208 #endif 209 210 211 typedef struct CPUARMState { 212 /* Regs for current mode. */ 213 uint32_t regs[16]; 214 215 /* 32/64 switch only happens when taking and returning from 216 * exceptions so the overlap semantics are taken care of then 217 * instead of having a complicated union. 218 */ 219 /* Regs for A64 mode. */ 220 uint64_t xregs[32]; 221 uint64_t pc; 222 /* PSTATE isn't an architectural register for ARMv8. However, it is 223 * convenient for us to assemble the underlying state into a 32 bit format 224 * identical to the architectural format used for the SPSR. (This is also 225 * what the Linux kernel's 'pstate' field in signal handlers and KVM's 226 * 'pstate' register are.) Of the PSTATE bits: 227 * NZCV are kept in the split out env->CF/VF/NF/ZF, (which have the same 228 * semantics as for AArch32, as described in the comments on each field) 229 * nRW (also known as M[4]) is kept, inverted, in env->aarch64 230 * DAIF (exception masks) are kept in env->daif 231 * all other bits are stored in their correct places in env->pstate 232 */ 233 uint32_t pstate; 234 uint32_t aarch64; /* 1 if CPU is in aarch64 state; inverse of PSTATE.nRW */ 235 236 /* Frequently accessed CPSR bits are stored separately for efficiency. 237 This contains all the other bits. Use cpsr_{read,write} to access 238 the whole CPSR. */ 239 uint32_t uncached_cpsr; 240 uint32_t spsr; 241 242 /* Banked registers. */ 243 uint64_t banked_spsr[8]; 244 uint32_t banked_r13[8]; 245 uint32_t banked_r14[8]; 246 247 /* These hold r8-r12. */ 248 uint32_t usr_regs[5]; 249 uint32_t fiq_regs[5]; 250 251 /* cpsr flag cache for faster execution */ 252 uint32_t CF; /* 0 or 1 */ 253 uint32_t VF; /* V is the bit 31. All other bits are undefined */ 254 uint32_t NF; /* N is bit 31. All other bits are undefined. */ 255 uint32_t ZF; /* Z set if zero. */ 256 uint32_t QF; /* 0 or 1 */ 257 uint32_t GE; /* cpsr[19:16] */ 258 uint32_t thumb; /* cpsr[5]. 0 = arm mode, 1 = thumb mode. */ 259 uint32_t condexec_bits; /* IT bits. cpsr[15:10,26:25]. */ 260 uint64_t daif; /* exception masks, in the bits they are in PSTATE */ 261 262 uint64_t elr_el[4]; /* AArch64 exception link regs */ 263 uint64_t sp_el[4]; /* AArch64 banked stack pointers */ 264 265 /* System control coprocessor (cp15) */ 266 struct { 267 uint32_t c0_cpuid; 268 union { /* Cache size selection */ 269 struct { 270 uint64_t _unused_csselr0; 271 uint64_t csselr_ns; 272 uint64_t _unused_csselr1; 273 uint64_t csselr_s; 274 }; 275 uint64_t csselr_el[4]; 276 }; 277 union { /* System control register. */ 278 struct { 279 uint64_t _unused_sctlr; 280 uint64_t sctlr_ns; 281 uint64_t hsctlr; 282 uint64_t sctlr_s; 283 }; 284 uint64_t sctlr_el[4]; 285 }; 286 uint64_t cpacr_el1; /* Architectural feature access control register */ 287 uint64_t cptr_el[4]; /* ARMv8 feature trap registers */ 288 uint32_t c1_xscaleauxcr; /* XScale auxiliary control register. */ 289 uint64_t sder; /* Secure debug enable register. */ 290 uint32_t nsacr; /* Non-secure access control register. */ 291 union { /* MMU translation table base 0. */ 292 struct { 293 uint64_t _unused_ttbr0_0; 294 uint64_t ttbr0_ns; 295 uint64_t _unused_ttbr0_1; 296 uint64_t ttbr0_s; 297 }; 298 uint64_t ttbr0_el[4]; 299 }; 300 union { /* MMU translation table base 1. */ 301 struct { 302 uint64_t _unused_ttbr1_0; 303 uint64_t ttbr1_ns; 304 uint64_t _unused_ttbr1_1; 305 uint64_t ttbr1_s; 306 }; 307 uint64_t ttbr1_el[4]; 308 }; 309 uint64_t vttbr_el2; /* Virtualization Translation Table Base. */ 310 /* MMU translation table base control. */ 311 TCR tcr_el[4]; 312 TCR vtcr_el2; /* Virtualization Translation Control. */ 313 uint32_t c2_data; /* MPU data cacheable bits. */ 314 uint32_t c2_insn; /* MPU instruction cacheable bits. */ 315 union { /* MMU domain access control register 316 * MPU write buffer control. 317 */ 318 struct { 319 uint64_t dacr_ns; 320 uint64_t dacr_s; 321 }; 322 struct { 323 uint64_t dacr32_el2; 324 }; 325 }; 326 uint32_t pmsav5_data_ap; /* PMSAv5 MPU data access permissions */ 327 uint32_t pmsav5_insn_ap; /* PMSAv5 MPU insn access permissions */ 328 uint64_t hcr_el2; /* Hypervisor configuration register */ 329 uint64_t scr_el3; /* Secure configuration register. */ 330 union { /* Fault status registers. */ 331 struct { 332 uint64_t ifsr_ns; 333 uint64_t ifsr_s; 334 }; 335 struct { 336 uint64_t ifsr32_el2; 337 }; 338 }; 339 union { 340 struct { 341 uint64_t _unused_dfsr; 342 uint64_t dfsr_ns; 343 uint64_t hsr; 344 uint64_t dfsr_s; 345 }; 346 uint64_t esr_el[4]; 347 }; 348 uint32_t c6_region[8]; /* MPU base/size registers. */ 349 union { /* Fault address registers. */ 350 struct { 351 uint64_t _unused_far0; 352 #ifdef HOST_WORDS_BIGENDIAN 353 uint32_t ifar_ns; 354 uint32_t dfar_ns; 355 uint32_t ifar_s; 356 uint32_t dfar_s; 357 #else 358 uint32_t dfar_ns; 359 uint32_t ifar_ns; 360 uint32_t dfar_s; 361 uint32_t ifar_s; 362 #endif 363 uint64_t _unused_far3; 364 }; 365 uint64_t far_el[4]; 366 }; 367 uint64_t hpfar_el2; 368 uint64_t hstr_el2; 369 union { /* Translation result. */ 370 struct { 371 uint64_t _unused_par_0; 372 uint64_t par_ns; 373 uint64_t _unused_par_1; 374 uint64_t par_s; 375 }; 376 uint64_t par_el[4]; 377 }; 378 379 uint32_t c9_insn; /* Cache lockdown registers. */ 380 uint32_t c9_data; 381 uint64_t c9_pmcr; /* performance monitor control register */ 382 uint64_t c9_pmcnten; /* perf monitor counter enables */ 383 uint64_t c9_pmovsr; /* perf monitor overflow status */ 384 uint64_t c9_pmuserenr; /* perf monitor user enable */ 385 uint64_t c9_pmselr; /* perf monitor counter selection register */ 386 uint64_t c9_pminten; /* perf monitor interrupt enables */ 387 union { /* Memory attribute redirection */ 388 struct { 389 #ifdef HOST_WORDS_BIGENDIAN 390 uint64_t _unused_mair_0; 391 uint32_t mair1_ns; 392 uint32_t mair0_ns; 393 uint64_t _unused_mair_1; 394 uint32_t mair1_s; 395 uint32_t mair0_s; 396 #else 397 uint64_t _unused_mair_0; 398 uint32_t mair0_ns; 399 uint32_t mair1_ns; 400 uint64_t _unused_mair_1; 401 uint32_t mair0_s; 402 uint32_t mair1_s; 403 #endif 404 }; 405 uint64_t mair_el[4]; 406 }; 407 union { /* vector base address register */ 408 struct { 409 uint64_t _unused_vbar; 410 uint64_t vbar_ns; 411 uint64_t hvbar; 412 uint64_t vbar_s; 413 }; 414 uint64_t vbar_el[4]; 415 }; 416 uint32_t mvbar; /* (monitor) vector base address register */ 417 struct { /* FCSE PID. */ 418 uint32_t fcseidr_ns; 419 uint32_t fcseidr_s; 420 }; 421 union { /* Context ID. */ 422 struct { 423 uint64_t _unused_contextidr_0; 424 uint64_t contextidr_ns; 425 uint64_t _unused_contextidr_1; 426 uint64_t contextidr_s; 427 }; 428 uint64_t contextidr_el[4]; 429 }; 430 union { /* User RW Thread register. */ 431 struct { 432 uint64_t tpidrurw_ns; 433 uint64_t tpidrprw_ns; 434 uint64_t htpidr; 435 uint64_t _tpidr_el3; 436 }; 437 uint64_t tpidr_el[4]; 438 }; 439 /* The secure banks of these registers don't map anywhere */ 440 uint64_t tpidrurw_s; 441 uint64_t tpidrprw_s; 442 uint64_t tpidruro_s; 443 444 union { /* User RO Thread register. */ 445 uint64_t tpidruro_ns; 446 uint64_t tpidrro_el[1]; 447 }; 448 uint64_t c14_cntfrq; /* Counter Frequency register */ 449 uint64_t c14_cntkctl; /* Timer Control register */ 450 uint32_t cnthctl_el2; /* Counter/Timer Hyp Control register */ 451 uint64_t cntvoff_el2; /* Counter Virtual Offset register */ 452 ARMGenericTimer c14_timer[NUM_GTIMERS]; 453 uint32_t c15_cpar; /* XScale Coprocessor Access Register */ 454 uint32_t c15_ticonfig; /* TI925T configuration byte. */ 455 uint32_t c15_i_max; /* Maximum D-cache dirty line index. */ 456 uint32_t c15_i_min; /* Minimum D-cache dirty line index. */ 457 uint32_t c15_threadid; /* TI debugger thread-ID. */ 458 uint32_t c15_config_base_address; /* SCU base address. */ 459 uint32_t c15_diagnostic; /* diagnostic register */ 460 uint32_t c15_power_diagnostic; 461 uint32_t c15_power_control; /* power control */ 462 uint64_t dbgbvr[16]; /* breakpoint value registers */ 463 uint64_t dbgbcr[16]; /* breakpoint control registers */ 464 uint64_t dbgwvr[16]; /* watchpoint value registers */ 465 uint64_t dbgwcr[16]; /* watchpoint control registers */ 466 uint64_t mdscr_el1; 467 uint64_t oslsr_el1; /* OS Lock Status */ 468 uint64_t mdcr_el2; 469 uint64_t mdcr_el3; 470 /* If the counter is enabled, this stores the last time the counter 471 * was reset. Otherwise it stores the counter value 472 */ 473 uint64_t c15_ccnt; 474 uint64_t pmccfiltr_el0; /* Performance Monitor Filter Register */ 475 uint64_t vpidr_el2; /* Virtualization Processor ID Register */ 476 uint64_t vmpidr_el2; /* Virtualization Multiprocessor ID Register */ 477 } cp15; 478 479 struct { 480 /* M profile has up to 4 stack pointers: 481 * a Main Stack Pointer and a Process Stack Pointer for each 482 * of the Secure and Non-Secure states. (If the CPU doesn't support 483 * the security extension then it has only two SPs.) 484 * In QEMU we always store the currently active SP in regs[13], 485 * and the non-active SP for the current security state in 486 * v7m.other_sp. The stack pointers for the inactive security state 487 * are stored in other_ss_msp and other_ss_psp. 488 * switch_v7m_security_state() is responsible for rearranging them 489 * when we change security state. 490 */ 491 uint32_t other_sp; 492 uint32_t other_ss_msp; 493 uint32_t other_ss_psp; 494 uint32_t vecbase[M_REG_NUM_BANKS]; 495 uint32_t basepri[M_REG_NUM_BANKS]; 496 uint32_t control[M_REG_NUM_BANKS]; 497 uint32_t ccr[M_REG_NUM_BANKS]; /* Configuration and Control */ 498 uint32_t cfsr[M_REG_NUM_BANKS]; /* Configurable Fault Status */ 499 uint32_t hfsr; /* HardFault Status */ 500 uint32_t dfsr; /* Debug Fault Status Register */ 501 uint32_t sfsr; /* Secure Fault Status Register */ 502 uint32_t mmfar[M_REG_NUM_BANKS]; /* MemManage Fault Address */ 503 uint32_t bfar; /* BusFault Address */ 504 uint32_t sfar; /* Secure Fault Address Register */ 505 unsigned mpu_ctrl[M_REG_NUM_BANKS]; /* MPU_CTRL */ 506 int exception; 507 uint32_t primask[M_REG_NUM_BANKS]; 508 uint32_t faultmask[M_REG_NUM_BANKS]; 509 uint32_t aircr; /* only holds r/w state if security extn implemented */ 510 uint32_t secure; /* Is CPU in Secure state? (not guest visible) */ 511 uint32_t csselr[M_REG_NUM_BANKS]; 512 uint32_t scr[M_REG_NUM_BANKS]; 513 uint32_t msplim[M_REG_NUM_BANKS]; 514 uint32_t psplim[M_REG_NUM_BANKS]; 515 } v7m; 516 517 /* Information associated with an exception about to be taken: 518 * code which raises an exception must set cs->exception_index and 519 * the relevant parts of this structure; the cpu_do_interrupt function 520 * will then set the guest-visible registers as part of the exception 521 * entry process. 522 */ 523 struct { 524 uint32_t syndrome; /* AArch64 format syndrome register */ 525 uint32_t fsr; /* AArch32 format fault status register info */ 526 uint64_t vaddress; /* virtual addr associated with exception, if any */ 527 uint32_t target_el; /* EL the exception should be targeted for */ 528 /* If we implement EL2 we will also need to store information 529 * about the intermediate physical address for stage 2 faults. 530 */ 531 } exception; 532 533 /* Thumb-2 EE state. */ 534 uint32_t teecr; 535 uint32_t teehbr; 536 537 /* VFP coprocessor state. */ 538 struct { 539 ARMVectorReg zregs[32]; 540 541 #ifdef TARGET_AARCH64 542 /* Store FFR as pregs[16] to make it easier to treat as any other. */ 543 #define FFR_PRED_NUM 16 544 ARMPredicateReg pregs[17]; 545 /* Scratch space for aa64 sve predicate temporary. */ 546 ARMPredicateReg preg_tmp; 547 #endif 548 549 uint32_t xregs[16]; 550 /* We store these fpcsr fields separately for convenience. */ 551 int vec_len; 552 int vec_stride; 553 554 /* Scratch space for aa32 neon expansion. */ 555 uint32_t scratch[8]; 556 557 /* There are a number of distinct float control structures: 558 * 559 * fp_status: is the "normal" fp status. 560 * fp_status_fp16: used for half-precision calculations 561 * standard_fp_status : the ARM "Standard FPSCR Value" 562 * 563 * Half-precision operations are governed by a separate 564 * flush-to-zero control bit in FPSCR:FZ16. We pass a separate 565 * status structure to control this. 566 * 567 * The "Standard FPSCR", ie default-NaN, flush-to-zero, 568 * round-to-nearest and is used by any operations (generally 569 * Neon) which the architecture defines as controlled by the 570 * standard FPSCR value rather than the FPSCR. 571 * 572 * To avoid having to transfer exception bits around, we simply 573 * say that the FPSCR cumulative exception flags are the logical 574 * OR of the flags in the three fp statuses. This relies on the 575 * only thing which needs to read the exception flags being 576 * an explicit FPSCR read. 577 */ 578 float_status fp_status; 579 float_status fp_status_f16; 580 float_status standard_fp_status; 581 582 /* ZCR_EL[1-3] */ 583 uint64_t zcr_el[4]; 584 } vfp; 585 uint64_t exclusive_addr; 586 uint64_t exclusive_val; 587 uint64_t exclusive_high; 588 589 /* iwMMXt coprocessor state. */ 590 struct { 591 uint64_t regs[16]; 592 uint64_t val; 593 594 uint32_t cregs[16]; 595 } iwmmxt; 596 597 #if defined(CONFIG_USER_ONLY) 598 /* For usermode syscall translation. */ 599 int eabi; 600 #endif 601 602 struct CPUBreakpoint *cpu_breakpoint[16]; 603 struct CPUWatchpoint *cpu_watchpoint[16]; 604 605 /* Fields up to this point are cleared by a CPU reset */ 606 struct {} end_reset_fields; 607 608 CPU_COMMON 609 610 /* Fields after CPU_COMMON are preserved across CPU reset. */ 611 612 /* Internal CPU feature flags. */ 613 uint64_t features; 614 615 /* PMSAv7 MPU */ 616 struct { 617 uint32_t *drbar; 618 uint32_t *drsr; 619 uint32_t *dracr; 620 uint32_t rnr[M_REG_NUM_BANKS]; 621 } pmsav7; 622 623 /* PMSAv8 MPU */ 624 struct { 625 /* The PMSAv8 implementation also shares some PMSAv7 config 626 * and state: 627 * pmsav7.rnr (region number register) 628 * pmsav7_dregion (number of configured regions) 629 */ 630 uint32_t *rbar[M_REG_NUM_BANKS]; 631 uint32_t *rlar[M_REG_NUM_BANKS]; 632 uint32_t mair0[M_REG_NUM_BANKS]; 633 uint32_t mair1[M_REG_NUM_BANKS]; 634 } pmsav8; 635 636 /* v8M SAU */ 637 struct { 638 uint32_t *rbar; 639 uint32_t *rlar; 640 uint32_t rnr; 641 uint32_t ctrl; 642 } sau; 643 644 void *nvic; 645 const struct arm_boot_info *boot_info; 646 /* Store GICv3CPUState to access from this struct */ 647 void *gicv3state; 648 } CPUARMState; 649 650 /** 651 * ARMELChangeHookFn: 652 * type of a function which can be registered via arm_register_el_change_hook() 653 * to get callbacks when the CPU changes its exception level or mode. 654 */ 655 typedef void ARMELChangeHookFn(ARMCPU *cpu, void *opaque); 656 typedef struct ARMELChangeHook ARMELChangeHook; 657 struct ARMELChangeHook { 658 ARMELChangeHookFn *hook; 659 void *opaque; 660 QLIST_ENTRY(ARMELChangeHook) node; 661 }; 662 663 /* These values map onto the return values for 664 * QEMU_PSCI_0_2_FN_AFFINITY_INFO */ 665 typedef enum ARMPSCIState { 666 PSCI_ON = 0, 667 PSCI_OFF = 1, 668 PSCI_ON_PENDING = 2 669 } ARMPSCIState; 670 671 /** 672 * ARMCPU: 673 * @env: #CPUARMState 674 * 675 * An ARM CPU core. 676 */ 677 struct ARMCPU { 678 /*< private >*/ 679 CPUState parent_obj; 680 /*< public >*/ 681 682 CPUARMState env; 683 684 /* Coprocessor information */ 685 GHashTable *cp_regs; 686 /* For marshalling (mostly coprocessor) register state between the 687 * kernel and QEMU (for KVM) and between two QEMUs (for migration), 688 * we use these arrays. 689 */ 690 /* List of register indexes managed via these arrays; (full KVM style 691 * 64 bit indexes, not CPRegInfo 32 bit indexes) 692 */ 693 uint64_t *cpreg_indexes; 694 /* Values of the registers (cpreg_indexes[i]'s value is cpreg_values[i]) */ 695 uint64_t *cpreg_values; 696 /* Length of the indexes, values, reset_values arrays */ 697 int32_t cpreg_array_len; 698 /* These are used only for migration: incoming data arrives in 699 * these fields and is sanity checked in post_load before copying 700 * to the working data structures above. 701 */ 702 uint64_t *cpreg_vmstate_indexes; 703 uint64_t *cpreg_vmstate_values; 704 int32_t cpreg_vmstate_array_len; 705 706 DynamicGDBXMLInfo dyn_xml; 707 708 /* Timers used by the generic (architected) timer */ 709 QEMUTimer *gt_timer[NUM_GTIMERS]; 710 /* GPIO outputs for generic timer */ 711 qemu_irq gt_timer_outputs[NUM_GTIMERS]; 712 /* GPIO output for GICv3 maintenance interrupt signal */ 713 qemu_irq gicv3_maintenance_interrupt; 714 /* GPIO output for the PMU interrupt */ 715 qemu_irq pmu_interrupt; 716 717 /* MemoryRegion to use for secure physical accesses */ 718 MemoryRegion *secure_memory; 719 720 /* For v8M, pointer to the IDAU interface provided by board/SoC */ 721 Object *idau; 722 723 /* 'compatible' string for this CPU for Linux device trees */ 724 const char *dtb_compatible; 725 726 /* PSCI version for this CPU 727 * Bits[31:16] = Major Version 728 * Bits[15:0] = Minor Version 729 */ 730 uint32_t psci_version; 731 732 /* Should CPU start in PSCI powered-off state? */ 733 bool start_powered_off; 734 735 /* Current power state, access guarded by BQL */ 736 ARMPSCIState power_state; 737 738 /* CPU has virtualization extension */ 739 bool has_el2; 740 /* CPU has security extension */ 741 bool has_el3; 742 /* CPU has PMU (Performance Monitor Unit) */ 743 bool has_pmu; 744 745 /* CPU has memory protection unit */ 746 bool has_mpu; 747 /* PMSAv7 MPU number of supported regions */ 748 uint32_t pmsav7_dregion; 749 /* v8M SAU number of supported regions */ 750 uint32_t sau_sregion; 751 752 /* PSCI conduit used to invoke PSCI methods 753 * 0 - disabled, 1 - smc, 2 - hvc 754 */ 755 uint32_t psci_conduit; 756 757 /* For v8M, initial value of the Secure VTOR */ 758 uint32_t init_svtor; 759 760 /* [QEMU_]KVM_ARM_TARGET_* constant for this CPU, or 761 * QEMU_KVM_ARM_TARGET_NONE if the kernel doesn't support this CPU type. 762 */ 763 uint32_t kvm_target; 764 765 /* KVM init features for this CPU */ 766 uint32_t kvm_init_features[7]; 767 768 /* Uniprocessor system with MP extensions */ 769 bool mp_is_up; 770 771 /* True if we tried kvm_arm_host_cpu_features() during CPU instance_init 772 * and the probe failed (so we need to report the error in realize) 773 */ 774 bool host_cpu_probe_failed; 775 776 /* Specify the number of cores in this CPU cluster. Used for the L2CTLR 777 * register. 778 */ 779 int32_t core_count; 780 781 /* The instance init functions for implementation-specific subclasses 782 * set these fields to specify the implementation-dependent values of 783 * various constant registers and reset values of non-constant 784 * registers. 785 * Some of these might become QOM properties eventually. 786 * Field names match the official register names as defined in the 787 * ARMv7AR ARM Architecture Reference Manual. A reset_ prefix 788 * is used for reset values of non-constant registers; no reset_ 789 * prefix means a constant register. 790 */ 791 uint32_t midr; 792 uint32_t revidr; 793 uint32_t reset_fpsid; 794 uint32_t mvfr0; 795 uint32_t mvfr1; 796 uint32_t mvfr2; 797 uint32_t ctr; 798 uint32_t reset_sctlr; 799 uint32_t id_pfr0; 800 uint32_t id_pfr1; 801 uint32_t id_dfr0; 802 uint32_t pmceid0; 803 uint32_t pmceid1; 804 uint32_t id_afr0; 805 uint32_t id_mmfr0; 806 uint32_t id_mmfr1; 807 uint32_t id_mmfr2; 808 uint32_t id_mmfr3; 809 uint32_t id_mmfr4; 810 uint32_t id_isar0; 811 uint32_t id_isar1; 812 uint32_t id_isar2; 813 uint32_t id_isar3; 814 uint32_t id_isar4; 815 uint32_t id_isar5; 816 uint32_t id_isar6; 817 uint64_t id_aa64pfr0; 818 uint64_t id_aa64pfr1; 819 uint64_t id_aa64dfr0; 820 uint64_t id_aa64dfr1; 821 uint64_t id_aa64afr0; 822 uint64_t id_aa64afr1; 823 uint64_t id_aa64isar0; 824 uint64_t id_aa64isar1; 825 uint64_t id_aa64mmfr0; 826 uint64_t id_aa64mmfr1; 827 uint32_t dbgdidr; 828 uint32_t clidr; 829 uint64_t mp_affinity; /* MP ID without feature bits */ 830 /* The elements of this array are the CCSIDR values for each cache, 831 * in the order L1DCache, L1ICache, L2DCache, L2ICache, etc. 832 */ 833 uint32_t ccsidr[16]; 834 uint64_t reset_cbar; 835 uint32_t reset_auxcr; 836 bool reset_hivecs; 837 /* DCZ blocksize, in log_2(words), ie low 4 bits of DCZID_EL0 */ 838 uint32_t dcz_blocksize; 839 uint64_t rvbar; 840 841 /* Configurable aspects of GIC cpu interface (which is part of the CPU) */ 842 int gic_num_lrs; /* number of list registers */ 843 int gic_vpribits; /* number of virtual priority bits */ 844 int gic_vprebits; /* number of virtual preemption bits */ 845 846 /* Whether the cfgend input is high (i.e. this CPU should reset into 847 * big-endian mode). This setting isn't used directly: instead it modifies 848 * the reset_sctlr value to have SCTLR_B or SCTLR_EE set, depending on the 849 * architecture version. 850 */ 851 bool cfgend; 852 853 QLIST_HEAD(, ARMELChangeHook) pre_el_change_hooks; 854 QLIST_HEAD(, ARMELChangeHook) el_change_hooks; 855 856 int32_t node_id; /* NUMA node this CPU belongs to */ 857 858 /* Used to synchronize KVM and QEMU in-kernel device levels */ 859 uint8_t device_irq_level; 860 861 /* Used to set the maximum vector length the cpu will support. */ 862 uint32_t sve_max_vq; 863 }; 864 865 static inline ARMCPU *arm_env_get_cpu(CPUARMState *env) 866 { 867 return container_of(env, ARMCPU, env); 868 } 869 870 uint64_t arm_cpu_mp_affinity(int idx, uint8_t clustersz); 871 872 #define ENV_GET_CPU(e) CPU(arm_env_get_cpu(e)) 873 874 #define ENV_OFFSET offsetof(ARMCPU, env) 875 876 #ifndef CONFIG_USER_ONLY 877 extern const struct VMStateDescription vmstate_arm_cpu; 878 #endif 879 880 void arm_cpu_do_interrupt(CPUState *cpu); 881 void arm_v7m_cpu_do_interrupt(CPUState *cpu); 882 bool arm_cpu_exec_interrupt(CPUState *cpu, int int_req); 883 884 void arm_cpu_dump_state(CPUState *cs, FILE *f, fprintf_function cpu_fprintf, 885 int flags); 886 887 hwaddr arm_cpu_get_phys_page_attrs_debug(CPUState *cpu, vaddr addr, 888 MemTxAttrs *attrs); 889 890 int arm_cpu_gdb_read_register(CPUState *cpu, uint8_t *buf, int reg); 891 int arm_cpu_gdb_write_register(CPUState *cpu, uint8_t *buf, int reg); 892 893 /* Dynamically generates for gdb stub an XML description of the sysregs from 894 * the cp_regs hashtable. Returns the registered sysregs number. 895 */ 896 int arm_gen_dynamic_xml(CPUState *cpu); 897 898 /* Returns the dynamically generated XML for the gdb stub. 899 * Returns a pointer to the XML contents for the specified XML file or NULL 900 * if the XML name doesn't match the predefined one. 901 */ 902 const char *arm_gdb_get_dynamic_xml(CPUState *cpu, const char *xmlname); 903 904 int arm_cpu_write_elf64_note(WriteCoreDumpFunction f, CPUState *cs, 905 int cpuid, void *opaque); 906 int arm_cpu_write_elf32_note(WriteCoreDumpFunction f, CPUState *cs, 907 int cpuid, void *opaque); 908 909 #ifdef TARGET_AARCH64 910 int aarch64_cpu_gdb_read_register(CPUState *cpu, uint8_t *buf, int reg); 911 int aarch64_cpu_gdb_write_register(CPUState *cpu, uint8_t *buf, int reg); 912 void aarch64_sve_narrow_vq(CPUARMState *env, unsigned vq); 913 #endif 914 915 target_ulong do_arm_semihosting(CPUARMState *env); 916 void aarch64_sync_32_to_64(CPUARMState *env); 917 void aarch64_sync_64_to_32(CPUARMState *env); 918 919 static inline bool is_a64(CPUARMState *env) 920 { 921 return env->aarch64; 922 } 923 924 /* you can call this signal handler from your SIGBUS and SIGSEGV 925 signal handlers to inform the virtual CPU of exceptions. non zero 926 is returned if the signal was handled by the virtual CPU. */ 927 int cpu_arm_signal_handler(int host_signum, void *pinfo, 928 void *puc); 929 930 /** 931 * pmccntr_sync 932 * @env: CPUARMState 933 * 934 * Synchronises the counter in the PMCCNTR. This must always be called twice, 935 * once before any action that might affect the timer and again afterwards. 936 * The function is used to swap the state of the register if required. 937 * This only happens when not in user mode (!CONFIG_USER_ONLY) 938 */ 939 void pmccntr_sync(CPUARMState *env); 940 941 /* SCTLR bit meanings. Several bits have been reused in newer 942 * versions of the architecture; in that case we define constants 943 * for both old and new bit meanings. Code which tests against those 944 * bits should probably check or otherwise arrange that the CPU 945 * is the architectural version it expects. 946 */ 947 #define SCTLR_M (1U << 0) 948 #define SCTLR_A (1U << 1) 949 #define SCTLR_C (1U << 2) 950 #define SCTLR_W (1U << 3) /* up to v6; RAO in v7 */ 951 #define SCTLR_SA (1U << 3) 952 #define SCTLR_P (1U << 4) /* up to v5; RAO in v6 and v7 */ 953 #define SCTLR_SA0 (1U << 4) /* v8 onward, AArch64 only */ 954 #define SCTLR_D (1U << 5) /* up to v5; RAO in v6 */ 955 #define SCTLR_CP15BEN (1U << 5) /* v7 onward */ 956 #define SCTLR_L (1U << 6) /* up to v5; RAO in v6 and v7; RAZ in v8 */ 957 #define SCTLR_B (1U << 7) /* up to v6; RAZ in v7 */ 958 #define SCTLR_ITD (1U << 7) /* v8 onward */ 959 #define SCTLR_S (1U << 8) /* up to v6; RAZ in v7 */ 960 #define SCTLR_SED (1U << 8) /* v8 onward */ 961 #define SCTLR_R (1U << 9) /* up to v6; RAZ in v7 */ 962 #define SCTLR_UMA (1U << 9) /* v8 onward, AArch64 only */ 963 #define SCTLR_F (1U << 10) /* up to v6 */ 964 #define SCTLR_SW (1U << 10) /* v7 onward */ 965 #define SCTLR_Z (1U << 11) 966 #define SCTLR_I (1U << 12) 967 #define SCTLR_V (1U << 13) 968 #define SCTLR_RR (1U << 14) /* up to v7 */ 969 #define SCTLR_DZE (1U << 14) /* v8 onward, AArch64 only */ 970 #define SCTLR_L4 (1U << 15) /* up to v6; RAZ in v7 */ 971 #define SCTLR_UCT (1U << 15) /* v8 onward, AArch64 only */ 972 #define SCTLR_DT (1U << 16) /* up to ??, RAO in v6 and v7 */ 973 #define SCTLR_nTWI (1U << 16) /* v8 onward */ 974 #define SCTLR_HA (1U << 17) 975 #define SCTLR_BR (1U << 17) /* PMSA only */ 976 #define SCTLR_IT (1U << 18) /* up to ??, RAO in v6 and v7 */ 977 #define SCTLR_nTWE (1U << 18) /* v8 onward */ 978 #define SCTLR_WXN (1U << 19) 979 #define SCTLR_ST (1U << 20) /* up to ??, RAZ in v6 */ 980 #define SCTLR_UWXN (1U << 20) /* v7 onward */ 981 #define SCTLR_FI (1U << 21) 982 #define SCTLR_U (1U << 22) 983 #define SCTLR_XP (1U << 23) /* up to v6; v7 onward RAO */ 984 #define SCTLR_VE (1U << 24) /* up to v7 */ 985 #define SCTLR_E0E (1U << 24) /* v8 onward, AArch64 only */ 986 #define SCTLR_EE (1U << 25) 987 #define SCTLR_L2 (1U << 26) /* up to v6, RAZ in v7 */ 988 #define SCTLR_UCI (1U << 26) /* v8 onward, AArch64 only */ 989 #define SCTLR_NMFI (1U << 27) 990 #define SCTLR_TRE (1U << 28) 991 #define SCTLR_AFE (1U << 29) 992 #define SCTLR_TE (1U << 30) 993 994 #define CPTR_TCPAC (1U << 31) 995 #define CPTR_TTA (1U << 20) 996 #define CPTR_TFP (1U << 10) 997 #define CPTR_TZ (1U << 8) /* CPTR_EL2 */ 998 #define CPTR_EZ (1U << 8) /* CPTR_EL3 */ 999 1000 #define MDCR_EPMAD (1U << 21) 1001 #define MDCR_EDAD (1U << 20) 1002 #define MDCR_SPME (1U << 17) 1003 #define MDCR_SDD (1U << 16) 1004 #define MDCR_SPD (3U << 14) 1005 #define MDCR_TDRA (1U << 11) 1006 #define MDCR_TDOSA (1U << 10) 1007 #define MDCR_TDA (1U << 9) 1008 #define MDCR_TDE (1U << 8) 1009 #define MDCR_HPME (1U << 7) 1010 #define MDCR_TPM (1U << 6) 1011 #define MDCR_TPMCR (1U << 5) 1012 1013 /* Not all of the MDCR_EL3 bits are present in the 32-bit SDCR */ 1014 #define SDCR_VALID_MASK (MDCR_EPMAD | MDCR_EDAD | MDCR_SPME | MDCR_SPD) 1015 1016 #define CPSR_M (0x1fU) 1017 #define CPSR_T (1U << 5) 1018 #define CPSR_F (1U << 6) 1019 #define CPSR_I (1U << 7) 1020 #define CPSR_A (1U << 8) 1021 #define CPSR_E (1U << 9) 1022 #define CPSR_IT_2_7 (0xfc00U) 1023 #define CPSR_GE (0xfU << 16) 1024 #define CPSR_IL (1U << 20) 1025 /* Note that the RESERVED bits include bit 21, which is PSTATE_SS in 1026 * an AArch64 SPSR but RES0 in AArch32 SPSR and CPSR. In QEMU we use 1027 * env->uncached_cpsr bit 21 to store PSTATE.SS when executing in AArch32, 1028 * where it is live state but not accessible to the AArch32 code. 1029 */ 1030 #define CPSR_RESERVED (0x7U << 21) 1031 #define CPSR_J (1U << 24) 1032 #define CPSR_IT_0_1 (3U << 25) 1033 #define CPSR_Q (1U << 27) 1034 #define CPSR_V (1U << 28) 1035 #define CPSR_C (1U << 29) 1036 #define CPSR_Z (1U << 30) 1037 #define CPSR_N (1U << 31) 1038 #define CPSR_NZCV (CPSR_N | CPSR_Z | CPSR_C | CPSR_V) 1039 #define CPSR_AIF (CPSR_A | CPSR_I | CPSR_F) 1040 1041 #define CPSR_IT (CPSR_IT_0_1 | CPSR_IT_2_7) 1042 #define CACHED_CPSR_BITS (CPSR_T | CPSR_AIF | CPSR_GE | CPSR_IT | CPSR_Q \ 1043 | CPSR_NZCV) 1044 /* Bits writable in user mode. */ 1045 #define CPSR_USER (CPSR_NZCV | CPSR_Q | CPSR_GE) 1046 /* Execution state bits. MRS read as zero, MSR writes ignored. */ 1047 #define CPSR_EXEC (CPSR_T | CPSR_IT | CPSR_J | CPSR_IL) 1048 /* Mask of bits which may be set by exception return copying them from SPSR */ 1049 #define CPSR_ERET_MASK (~CPSR_RESERVED) 1050 1051 /* Bit definitions for M profile XPSR. Most are the same as CPSR. */ 1052 #define XPSR_EXCP 0x1ffU 1053 #define XPSR_SPREALIGN (1U << 9) /* Only set in exception stack frames */ 1054 #define XPSR_IT_2_7 CPSR_IT_2_7 1055 #define XPSR_GE CPSR_GE 1056 #define XPSR_SFPA (1U << 20) /* Only set in exception stack frames */ 1057 #define XPSR_T (1U << 24) /* Not the same as CPSR_T ! */ 1058 #define XPSR_IT_0_1 CPSR_IT_0_1 1059 #define XPSR_Q CPSR_Q 1060 #define XPSR_V CPSR_V 1061 #define XPSR_C CPSR_C 1062 #define XPSR_Z CPSR_Z 1063 #define XPSR_N CPSR_N 1064 #define XPSR_NZCV CPSR_NZCV 1065 #define XPSR_IT CPSR_IT 1066 1067 #define TTBCR_N (7U << 0) /* TTBCR.EAE==0 */ 1068 #define TTBCR_T0SZ (7U << 0) /* TTBCR.EAE==1 */ 1069 #define TTBCR_PD0 (1U << 4) 1070 #define TTBCR_PD1 (1U << 5) 1071 #define TTBCR_EPD0 (1U << 7) 1072 #define TTBCR_IRGN0 (3U << 8) 1073 #define TTBCR_ORGN0 (3U << 10) 1074 #define TTBCR_SH0 (3U << 12) 1075 #define TTBCR_T1SZ (3U << 16) 1076 #define TTBCR_A1 (1U << 22) 1077 #define TTBCR_EPD1 (1U << 23) 1078 #define TTBCR_IRGN1 (3U << 24) 1079 #define TTBCR_ORGN1 (3U << 26) 1080 #define TTBCR_SH1 (1U << 28) 1081 #define TTBCR_EAE (1U << 31) 1082 1083 /* Bit definitions for ARMv8 SPSR (PSTATE) format. 1084 * Only these are valid when in AArch64 mode; in 1085 * AArch32 mode SPSRs are basically CPSR-format. 1086 */ 1087 #define PSTATE_SP (1U) 1088 #define PSTATE_M (0xFU) 1089 #define PSTATE_nRW (1U << 4) 1090 #define PSTATE_F (1U << 6) 1091 #define PSTATE_I (1U << 7) 1092 #define PSTATE_A (1U << 8) 1093 #define PSTATE_D (1U << 9) 1094 #define PSTATE_IL (1U << 20) 1095 #define PSTATE_SS (1U << 21) 1096 #define PSTATE_V (1U << 28) 1097 #define PSTATE_C (1U << 29) 1098 #define PSTATE_Z (1U << 30) 1099 #define PSTATE_N (1U << 31) 1100 #define PSTATE_NZCV (PSTATE_N | PSTATE_Z | PSTATE_C | PSTATE_V) 1101 #define PSTATE_DAIF (PSTATE_D | PSTATE_A | PSTATE_I | PSTATE_F) 1102 #define CACHED_PSTATE_BITS (PSTATE_NZCV | PSTATE_DAIF) 1103 /* Mode values for AArch64 */ 1104 #define PSTATE_MODE_EL3h 13 1105 #define PSTATE_MODE_EL3t 12 1106 #define PSTATE_MODE_EL2h 9 1107 #define PSTATE_MODE_EL2t 8 1108 #define PSTATE_MODE_EL1h 5 1109 #define PSTATE_MODE_EL1t 4 1110 #define PSTATE_MODE_EL0t 0 1111 1112 /* Write a new value to v7m.exception, thus transitioning into or out 1113 * of Handler mode; this may result in a change of active stack pointer. 1114 */ 1115 void write_v7m_exception(CPUARMState *env, uint32_t new_exc); 1116 1117 /* Map EL and handler into a PSTATE_MODE. */ 1118 static inline unsigned int aarch64_pstate_mode(unsigned int el, bool handler) 1119 { 1120 return (el << 2) | handler; 1121 } 1122 1123 /* Return the current PSTATE value. For the moment we don't support 32<->64 bit 1124 * interprocessing, so we don't attempt to sync with the cpsr state used by 1125 * the 32 bit decoder. 1126 */ 1127 static inline uint32_t pstate_read(CPUARMState *env) 1128 { 1129 int ZF; 1130 1131 ZF = (env->ZF == 0); 1132 return (env->NF & 0x80000000) | (ZF << 30) 1133 | (env->CF << 29) | ((env->VF & 0x80000000) >> 3) 1134 | env->pstate | env->daif; 1135 } 1136 1137 static inline void pstate_write(CPUARMState *env, uint32_t val) 1138 { 1139 env->ZF = (~val) & PSTATE_Z; 1140 env->NF = val; 1141 env->CF = (val >> 29) & 1; 1142 env->VF = (val << 3) & 0x80000000; 1143 env->daif = val & PSTATE_DAIF; 1144 env->pstate = val & ~CACHED_PSTATE_BITS; 1145 } 1146 1147 /* Return the current CPSR value. */ 1148 uint32_t cpsr_read(CPUARMState *env); 1149 1150 typedef enum CPSRWriteType { 1151 CPSRWriteByInstr = 0, /* from guest MSR or CPS */ 1152 CPSRWriteExceptionReturn = 1, /* from guest exception return insn */ 1153 CPSRWriteRaw = 2, /* trust values, do not switch reg banks */ 1154 CPSRWriteByGDBStub = 3, /* from the GDB stub */ 1155 } CPSRWriteType; 1156 1157 /* Set the CPSR. Note that some bits of mask must be all-set or all-clear.*/ 1158 void cpsr_write(CPUARMState *env, uint32_t val, uint32_t mask, 1159 CPSRWriteType write_type); 1160 1161 /* Return the current xPSR value. */ 1162 static inline uint32_t xpsr_read(CPUARMState *env) 1163 { 1164 int ZF; 1165 ZF = (env->ZF == 0); 1166 return (env->NF & 0x80000000) | (ZF << 30) 1167 | (env->CF << 29) | ((env->VF & 0x80000000) >> 3) | (env->QF << 27) 1168 | (env->thumb << 24) | ((env->condexec_bits & 3) << 25) 1169 | ((env->condexec_bits & 0xfc) << 8) 1170 | env->v7m.exception; 1171 } 1172 1173 /* Set the xPSR. Note that some bits of mask must be all-set or all-clear. */ 1174 static inline void xpsr_write(CPUARMState *env, uint32_t val, uint32_t mask) 1175 { 1176 if (mask & XPSR_NZCV) { 1177 env->ZF = (~val) & XPSR_Z; 1178 env->NF = val; 1179 env->CF = (val >> 29) & 1; 1180 env->VF = (val << 3) & 0x80000000; 1181 } 1182 if (mask & XPSR_Q) { 1183 env->QF = ((val & XPSR_Q) != 0); 1184 } 1185 if (mask & XPSR_T) { 1186 env->thumb = ((val & XPSR_T) != 0); 1187 } 1188 if (mask & XPSR_IT_0_1) { 1189 env->condexec_bits &= ~3; 1190 env->condexec_bits |= (val >> 25) & 3; 1191 } 1192 if (mask & XPSR_IT_2_7) { 1193 env->condexec_bits &= 3; 1194 env->condexec_bits |= (val >> 8) & 0xfc; 1195 } 1196 if (mask & XPSR_EXCP) { 1197 /* Note that this only happens on exception exit */ 1198 write_v7m_exception(env, val & XPSR_EXCP); 1199 } 1200 } 1201 1202 #define HCR_VM (1ULL << 0) 1203 #define HCR_SWIO (1ULL << 1) 1204 #define HCR_PTW (1ULL << 2) 1205 #define HCR_FMO (1ULL << 3) 1206 #define HCR_IMO (1ULL << 4) 1207 #define HCR_AMO (1ULL << 5) 1208 #define HCR_VF (1ULL << 6) 1209 #define HCR_VI (1ULL << 7) 1210 #define HCR_VSE (1ULL << 8) 1211 #define HCR_FB (1ULL << 9) 1212 #define HCR_BSU_MASK (3ULL << 10) 1213 #define HCR_DC (1ULL << 12) 1214 #define HCR_TWI (1ULL << 13) 1215 #define HCR_TWE (1ULL << 14) 1216 #define HCR_TID0 (1ULL << 15) 1217 #define HCR_TID1 (1ULL << 16) 1218 #define HCR_TID2 (1ULL << 17) 1219 #define HCR_TID3 (1ULL << 18) 1220 #define HCR_TSC (1ULL << 19) 1221 #define HCR_TIDCP (1ULL << 20) 1222 #define HCR_TACR (1ULL << 21) 1223 #define HCR_TSW (1ULL << 22) 1224 #define HCR_TPC (1ULL << 23) 1225 #define HCR_TPU (1ULL << 24) 1226 #define HCR_TTLB (1ULL << 25) 1227 #define HCR_TVM (1ULL << 26) 1228 #define HCR_TGE (1ULL << 27) 1229 #define HCR_TDZ (1ULL << 28) 1230 #define HCR_HCD (1ULL << 29) 1231 #define HCR_TRVM (1ULL << 30) 1232 #define HCR_RW (1ULL << 31) 1233 #define HCR_CD (1ULL << 32) 1234 #define HCR_ID (1ULL << 33) 1235 #define HCR_E2H (1ULL << 34) 1236 /* 1237 * When we actually implement ARMv8.1-VHE we should add HCR_E2H to 1238 * HCR_MASK and then clear it again if the feature bit is not set in 1239 * hcr_write(). 1240 */ 1241 #define HCR_MASK ((1ULL << 34) - 1) 1242 1243 #define SCR_NS (1U << 0) 1244 #define SCR_IRQ (1U << 1) 1245 #define SCR_FIQ (1U << 2) 1246 #define SCR_EA (1U << 3) 1247 #define SCR_FW (1U << 4) 1248 #define SCR_AW (1U << 5) 1249 #define SCR_NET (1U << 6) 1250 #define SCR_SMD (1U << 7) 1251 #define SCR_HCE (1U << 8) 1252 #define SCR_SIF (1U << 9) 1253 #define SCR_RW (1U << 10) 1254 #define SCR_ST (1U << 11) 1255 #define SCR_TWI (1U << 12) 1256 #define SCR_TWE (1U << 13) 1257 #define SCR_AARCH32_MASK (0x3fff & ~(SCR_RW | SCR_ST)) 1258 #define SCR_AARCH64_MASK (0x3fff & ~SCR_NET) 1259 1260 /* Return the current FPSCR value. */ 1261 uint32_t vfp_get_fpscr(CPUARMState *env); 1262 void vfp_set_fpscr(CPUARMState *env, uint32_t val); 1263 1264 /* FPCR, Floating Point Control Register 1265 * FPSR, Floating Poiht Status Register 1266 * 1267 * For A64 the FPSCR is split into two logically distinct registers, 1268 * FPCR and FPSR. However since they still use non-overlapping bits 1269 * we store the underlying state in fpscr and just mask on read/write. 1270 */ 1271 #define FPSR_MASK 0xf800009f 1272 #define FPCR_MASK 0x07ff9f00 1273 1274 #define FPCR_FZ16 (1 << 19) /* ARMv8.2+, FP16 flush-to-zero */ 1275 #define FPCR_FZ (1 << 24) /* Flush-to-zero enable bit */ 1276 #define FPCR_DN (1 << 25) /* Default NaN enable bit */ 1277 1278 static inline uint32_t vfp_get_fpsr(CPUARMState *env) 1279 { 1280 return vfp_get_fpscr(env) & FPSR_MASK; 1281 } 1282 1283 static inline void vfp_set_fpsr(CPUARMState *env, uint32_t val) 1284 { 1285 uint32_t new_fpscr = (vfp_get_fpscr(env) & ~FPSR_MASK) | (val & FPSR_MASK); 1286 vfp_set_fpscr(env, new_fpscr); 1287 } 1288 1289 static inline uint32_t vfp_get_fpcr(CPUARMState *env) 1290 { 1291 return vfp_get_fpscr(env) & FPCR_MASK; 1292 } 1293 1294 static inline void vfp_set_fpcr(CPUARMState *env, uint32_t val) 1295 { 1296 uint32_t new_fpscr = (vfp_get_fpscr(env) & ~FPCR_MASK) | (val & FPCR_MASK); 1297 vfp_set_fpscr(env, new_fpscr); 1298 } 1299 1300 enum arm_cpu_mode { 1301 ARM_CPU_MODE_USR = 0x10, 1302 ARM_CPU_MODE_FIQ = 0x11, 1303 ARM_CPU_MODE_IRQ = 0x12, 1304 ARM_CPU_MODE_SVC = 0x13, 1305 ARM_CPU_MODE_MON = 0x16, 1306 ARM_CPU_MODE_ABT = 0x17, 1307 ARM_CPU_MODE_HYP = 0x1a, 1308 ARM_CPU_MODE_UND = 0x1b, 1309 ARM_CPU_MODE_SYS = 0x1f 1310 }; 1311 1312 /* VFP system registers. */ 1313 #define ARM_VFP_FPSID 0 1314 #define ARM_VFP_FPSCR 1 1315 #define ARM_VFP_MVFR2 5 1316 #define ARM_VFP_MVFR1 6 1317 #define ARM_VFP_MVFR0 7 1318 #define ARM_VFP_FPEXC 8 1319 #define ARM_VFP_FPINST 9 1320 #define ARM_VFP_FPINST2 10 1321 1322 /* iwMMXt coprocessor control registers. */ 1323 #define ARM_IWMMXT_wCID 0 1324 #define ARM_IWMMXT_wCon 1 1325 #define ARM_IWMMXT_wCSSF 2 1326 #define ARM_IWMMXT_wCASF 3 1327 #define ARM_IWMMXT_wCGR0 8 1328 #define ARM_IWMMXT_wCGR1 9 1329 #define ARM_IWMMXT_wCGR2 10 1330 #define ARM_IWMMXT_wCGR3 11 1331 1332 /* V7M CCR bits */ 1333 FIELD(V7M_CCR, NONBASETHRDENA, 0, 1) 1334 FIELD(V7M_CCR, USERSETMPEND, 1, 1) 1335 FIELD(V7M_CCR, UNALIGN_TRP, 3, 1) 1336 FIELD(V7M_CCR, DIV_0_TRP, 4, 1) 1337 FIELD(V7M_CCR, BFHFNMIGN, 8, 1) 1338 FIELD(V7M_CCR, STKALIGN, 9, 1) 1339 FIELD(V7M_CCR, DC, 16, 1) 1340 FIELD(V7M_CCR, IC, 17, 1) 1341 1342 /* V7M SCR bits */ 1343 FIELD(V7M_SCR, SLEEPONEXIT, 1, 1) 1344 FIELD(V7M_SCR, SLEEPDEEP, 2, 1) 1345 FIELD(V7M_SCR, SLEEPDEEPS, 3, 1) 1346 FIELD(V7M_SCR, SEVONPEND, 4, 1) 1347 1348 /* V7M AIRCR bits */ 1349 FIELD(V7M_AIRCR, VECTRESET, 0, 1) 1350 FIELD(V7M_AIRCR, VECTCLRACTIVE, 1, 1) 1351 FIELD(V7M_AIRCR, SYSRESETREQ, 2, 1) 1352 FIELD(V7M_AIRCR, SYSRESETREQS, 3, 1) 1353 FIELD(V7M_AIRCR, PRIGROUP, 8, 3) 1354 FIELD(V7M_AIRCR, BFHFNMINS, 13, 1) 1355 FIELD(V7M_AIRCR, PRIS, 14, 1) 1356 FIELD(V7M_AIRCR, ENDIANNESS, 15, 1) 1357 FIELD(V7M_AIRCR, VECTKEY, 16, 16) 1358 1359 /* V7M CFSR bits for MMFSR */ 1360 FIELD(V7M_CFSR, IACCVIOL, 0, 1) 1361 FIELD(V7M_CFSR, DACCVIOL, 1, 1) 1362 FIELD(V7M_CFSR, MUNSTKERR, 3, 1) 1363 FIELD(V7M_CFSR, MSTKERR, 4, 1) 1364 FIELD(V7M_CFSR, MLSPERR, 5, 1) 1365 FIELD(V7M_CFSR, MMARVALID, 7, 1) 1366 1367 /* V7M CFSR bits for BFSR */ 1368 FIELD(V7M_CFSR, IBUSERR, 8 + 0, 1) 1369 FIELD(V7M_CFSR, PRECISERR, 8 + 1, 1) 1370 FIELD(V7M_CFSR, IMPRECISERR, 8 + 2, 1) 1371 FIELD(V7M_CFSR, UNSTKERR, 8 + 3, 1) 1372 FIELD(V7M_CFSR, STKERR, 8 + 4, 1) 1373 FIELD(V7M_CFSR, LSPERR, 8 + 5, 1) 1374 FIELD(V7M_CFSR, BFARVALID, 8 + 7, 1) 1375 1376 /* V7M CFSR bits for UFSR */ 1377 FIELD(V7M_CFSR, UNDEFINSTR, 16 + 0, 1) 1378 FIELD(V7M_CFSR, INVSTATE, 16 + 1, 1) 1379 FIELD(V7M_CFSR, INVPC, 16 + 2, 1) 1380 FIELD(V7M_CFSR, NOCP, 16 + 3, 1) 1381 FIELD(V7M_CFSR, UNALIGNED, 16 + 8, 1) 1382 FIELD(V7M_CFSR, DIVBYZERO, 16 + 9, 1) 1383 1384 /* V7M CFSR bit masks covering all of the subregister bits */ 1385 FIELD(V7M_CFSR, MMFSR, 0, 8) 1386 FIELD(V7M_CFSR, BFSR, 8, 8) 1387 FIELD(V7M_CFSR, UFSR, 16, 16) 1388 1389 /* V7M HFSR bits */ 1390 FIELD(V7M_HFSR, VECTTBL, 1, 1) 1391 FIELD(V7M_HFSR, FORCED, 30, 1) 1392 FIELD(V7M_HFSR, DEBUGEVT, 31, 1) 1393 1394 /* V7M DFSR bits */ 1395 FIELD(V7M_DFSR, HALTED, 0, 1) 1396 FIELD(V7M_DFSR, BKPT, 1, 1) 1397 FIELD(V7M_DFSR, DWTTRAP, 2, 1) 1398 FIELD(V7M_DFSR, VCATCH, 3, 1) 1399 FIELD(V7M_DFSR, EXTERNAL, 4, 1) 1400 1401 /* V7M SFSR bits */ 1402 FIELD(V7M_SFSR, INVEP, 0, 1) 1403 FIELD(V7M_SFSR, INVIS, 1, 1) 1404 FIELD(V7M_SFSR, INVER, 2, 1) 1405 FIELD(V7M_SFSR, AUVIOL, 3, 1) 1406 FIELD(V7M_SFSR, INVTRAN, 4, 1) 1407 FIELD(V7M_SFSR, LSPERR, 5, 1) 1408 FIELD(V7M_SFSR, SFARVALID, 6, 1) 1409 FIELD(V7M_SFSR, LSERR, 7, 1) 1410 1411 /* v7M MPU_CTRL bits */ 1412 FIELD(V7M_MPU_CTRL, ENABLE, 0, 1) 1413 FIELD(V7M_MPU_CTRL, HFNMIENA, 1, 1) 1414 FIELD(V7M_MPU_CTRL, PRIVDEFENA, 2, 1) 1415 1416 /* v7M CLIDR bits */ 1417 FIELD(V7M_CLIDR, CTYPE_ALL, 0, 21) 1418 FIELD(V7M_CLIDR, LOUIS, 21, 3) 1419 FIELD(V7M_CLIDR, LOC, 24, 3) 1420 FIELD(V7M_CLIDR, LOUU, 27, 3) 1421 FIELD(V7M_CLIDR, ICB, 30, 2) 1422 1423 FIELD(V7M_CSSELR, IND, 0, 1) 1424 FIELD(V7M_CSSELR, LEVEL, 1, 3) 1425 /* We use the combination of InD and Level to index into cpu->ccsidr[]; 1426 * define a mask for this and check that it doesn't permit running off 1427 * the end of the array. 1428 */ 1429 FIELD(V7M_CSSELR, INDEX, 0, 4) 1430 1431 QEMU_BUILD_BUG_ON(ARRAY_SIZE(((ARMCPU *)0)->ccsidr) <= R_V7M_CSSELR_INDEX_MASK); 1432 1433 /* If adding a feature bit which corresponds to a Linux ELF 1434 * HWCAP bit, remember to update the feature-bit-to-hwcap 1435 * mapping in linux-user/elfload.c:get_elf_hwcap(). 1436 */ 1437 enum arm_features { 1438 ARM_FEATURE_VFP, 1439 ARM_FEATURE_AUXCR, /* ARM1026 Auxiliary control register. */ 1440 ARM_FEATURE_XSCALE, /* Intel XScale extensions. */ 1441 ARM_FEATURE_IWMMXT, /* Intel iwMMXt extension. */ 1442 ARM_FEATURE_V6, 1443 ARM_FEATURE_V6K, 1444 ARM_FEATURE_V7, 1445 ARM_FEATURE_THUMB2, 1446 ARM_FEATURE_PMSA, /* no MMU; may have Memory Protection Unit */ 1447 ARM_FEATURE_VFP3, 1448 ARM_FEATURE_VFP_FP16, 1449 ARM_FEATURE_NEON, 1450 ARM_FEATURE_THUMB_DIV, /* divide supported in Thumb encoding */ 1451 ARM_FEATURE_M, /* Microcontroller profile. */ 1452 ARM_FEATURE_OMAPCP, /* OMAP specific CP15 ops handling. */ 1453 ARM_FEATURE_THUMB2EE, 1454 ARM_FEATURE_V7MP, /* v7 Multiprocessing Extensions */ 1455 ARM_FEATURE_V7VE, /* v7 Virtualization Extensions (non-EL2 parts) */ 1456 ARM_FEATURE_V4T, 1457 ARM_FEATURE_V5, 1458 ARM_FEATURE_STRONGARM, 1459 ARM_FEATURE_VAPA, /* cp15 VA to PA lookups */ 1460 ARM_FEATURE_ARM_DIV, /* divide supported in ARM encoding */ 1461 ARM_FEATURE_VFP4, /* VFPv4 (implies that NEON is v2) */ 1462 ARM_FEATURE_GENERIC_TIMER, 1463 ARM_FEATURE_MVFR, /* Media and VFP Feature Registers 0 and 1 */ 1464 ARM_FEATURE_DUMMY_C15_REGS, /* RAZ/WI all of cp15 crn=15 */ 1465 ARM_FEATURE_CACHE_TEST_CLEAN, /* 926/1026 style test-and-clean ops */ 1466 ARM_FEATURE_CACHE_DIRTY_REG, /* 1136/1176 cache dirty status register */ 1467 ARM_FEATURE_CACHE_BLOCK_OPS, /* v6 optional cache block operations */ 1468 ARM_FEATURE_MPIDR, /* has cp15 MPIDR */ 1469 ARM_FEATURE_PXN, /* has Privileged Execute Never bit */ 1470 ARM_FEATURE_LPAE, /* has Large Physical Address Extension */ 1471 ARM_FEATURE_V8, 1472 ARM_FEATURE_AARCH64, /* supports 64 bit mode */ 1473 ARM_FEATURE_V8_AES, /* implements AES part of v8 Crypto Extensions */ 1474 ARM_FEATURE_CBAR, /* has cp15 CBAR */ 1475 ARM_FEATURE_CRC, /* ARMv8 CRC instructions */ 1476 ARM_FEATURE_CBAR_RO, /* has cp15 CBAR and it is read-only */ 1477 ARM_FEATURE_EL2, /* has EL2 Virtualization support */ 1478 ARM_FEATURE_EL3, /* has EL3 Secure monitor support */ 1479 ARM_FEATURE_V8_SHA1, /* implements SHA1 part of v8 Crypto Extensions */ 1480 ARM_FEATURE_V8_SHA256, /* implements SHA256 part of v8 Crypto Extensions */ 1481 ARM_FEATURE_V8_PMULL, /* implements PMULL part of v8 Crypto Extensions */ 1482 ARM_FEATURE_THUMB_DSP, /* DSP insns supported in the Thumb encodings */ 1483 ARM_FEATURE_PMU, /* has PMU support */ 1484 ARM_FEATURE_VBAR, /* has cp15 VBAR */ 1485 ARM_FEATURE_M_SECURITY, /* M profile Security Extension */ 1486 ARM_FEATURE_JAZELLE, /* has (trivial) Jazelle implementation */ 1487 ARM_FEATURE_SVE, /* has Scalable Vector Extension */ 1488 ARM_FEATURE_V8_SHA512, /* implements SHA512 part of v8 Crypto Extensions */ 1489 ARM_FEATURE_V8_SHA3, /* implements SHA3 part of v8 Crypto Extensions */ 1490 ARM_FEATURE_V8_SM3, /* implements SM3 part of v8 Crypto Extensions */ 1491 ARM_FEATURE_V8_SM4, /* implements SM4 part of v8 Crypto Extensions */ 1492 ARM_FEATURE_V8_ATOMICS, /* ARMv8.1-Atomics feature */ 1493 ARM_FEATURE_V8_RDM, /* implements v8.1 simd round multiply */ 1494 ARM_FEATURE_V8_DOTPROD, /* implements v8.2 simd dot product */ 1495 ARM_FEATURE_V8_FP16, /* implements v8.2 half-precision float */ 1496 ARM_FEATURE_V8_FCMA, /* has complex number part of v8.3 extensions. */ 1497 ARM_FEATURE_M_MAIN, /* M profile Main Extension */ 1498 }; 1499 1500 static inline int arm_feature(CPUARMState *env, int feature) 1501 { 1502 return (env->features & (1ULL << feature)) != 0; 1503 } 1504 1505 #if !defined(CONFIG_USER_ONLY) 1506 /* Return true if exception levels below EL3 are in secure state, 1507 * or would be following an exception return to that level. 1508 * Unlike arm_is_secure() (which is always a question about the 1509 * _current_ state of the CPU) this doesn't care about the current 1510 * EL or mode. 1511 */ 1512 static inline bool arm_is_secure_below_el3(CPUARMState *env) 1513 { 1514 if (arm_feature(env, ARM_FEATURE_EL3)) { 1515 return !(env->cp15.scr_el3 & SCR_NS); 1516 } else { 1517 /* If EL3 is not supported then the secure state is implementation 1518 * defined, in which case QEMU defaults to non-secure. 1519 */ 1520 return false; 1521 } 1522 } 1523 1524 /* Return true if the CPU is AArch64 EL3 or AArch32 Mon */ 1525 static inline bool arm_is_el3_or_mon(CPUARMState *env) 1526 { 1527 if (arm_feature(env, ARM_FEATURE_EL3)) { 1528 if (is_a64(env) && extract32(env->pstate, 2, 2) == 3) { 1529 /* CPU currently in AArch64 state and EL3 */ 1530 return true; 1531 } else if (!is_a64(env) && 1532 (env->uncached_cpsr & CPSR_M) == ARM_CPU_MODE_MON) { 1533 /* CPU currently in AArch32 state and monitor mode */ 1534 return true; 1535 } 1536 } 1537 return false; 1538 } 1539 1540 /* Return true if the processor is in secure state */ 1541 static inline bool arm_is_secure(CPUARMState *env) 1542 { 1543 if (arm_is_el3_or_mon(env)) { 1544 return true; 1545 } 1546 return arm_is_secure_below_el3(env); 1547 } 1548 1549 #else 1550 static inline bool arm_is_secure_below_el3(CPUARMState *env) 1551 { 1552 return false; 1553 } 1554 1555 static inline bool arm_is_secure(CPUARMState *env) 1556 { 1557 return false; 1558 } 1559 #endif 1560 1561 /* Return true if the specified exception level is running in AArch64 state. */ 1562 static inline bool arm_el_is_aa64(CPUARMState *env, int el) 1563 { 1564 /* This isn't valid for EL0 (if we're in EL0, is_a64() is what you want, 1565 * and if we're not in EL0 then the state of EL0 isn't well defined.) 1566 */ 1567 assert(el >= 1 && el <= 3); 1568 bool aa64 = arm_feature(env, ARM_FEATURE_AARCH64); 1569 1570 /* The highest exception level is always at the maximum supported 1571 * register width, and then lower levels have a register width controlled 1572 * by bits in the SCR or HCR registers. 1573 */ 1574 if (el == 3) { 1575 return aa64; 1576 } 1577 1578 if (arm_feature(env, ARM_FEATURE_EL3)) { 1579 aa64 = aa64 && (env->cp15.scr_el3 & SCR_RW); 1580 } 1581 1582 if (el == 2) { 1583 return aa64; 1584 } 1585 1586 if (arm_feature(env, ARM_FEATURE_EL2) && !arm_is_secure_below_el3(env)) { 1587 aa64 = aa64 && (env->cp15.hcr_el2 & HCR_RW); 1588 } 1589 1590 return aa64; 1591 } 1592 1593 /* Function for determing whether guest cp register reads and writes should 1594 * access the secure or non-secure bank of a cp register. When EL3 is 1595 * operating in AArch32 state, the NS-bit determines whether the secure 1596 * instance of a cp register should be used. When EL3 is AArch64 (or if 1597 * it doesn't exist at all) then there is no register banking, and all 1598 * accesses are to the non-secure version. 1599 */ 1600 static inline bool access_secure_reg(CPUARMState *env) 1601 { 1602 bool ret = (arm_feature(env, ARM_FEATURE_EL3) && 1603 !arm_el_is_aa64(env, 3) && 1604 !(env->cp15.scr_el3 & SCR_NS)); 1605 1606 return ret; 1607 } 1608 1609 /* Macros for accessing a specified CP register bank */ 1610 #define A32_BANKED_REG_GET(_env, _regname, _secure) \ 1611 ((_secure) ? (_env)->cp15._regname##_s : (_env)->cp15._regname##_ns) 1612 1613 #define A32_BANKED_REG_SET(_env, _regname, _secure, _val) \ 1614 do { \ 1615 if (_secure) { \ 1616 (_env)->cp15._regname##_s = (_val); \ 1617 } else { \ 1618 (_env)->cp15._regname##_ns = (_val); \ 1619 } \ 1620 } while (0) 1621 1622 /* Macros for automatically accessing a specific CP register bank depending on 1623 * the current secure state of the system. These macros are not intended for 1624 * supporting instruction translation reads/writes as these are dependent 1625 * solely on the SCR.NS bit and not the mode. 1626 */ 1627 #define A32_BANKED_CURRENT_REG_GET(_env, _regname) \ 1628 A32_BANKED_REG_GET((_env), _regname, \ 1629 (arm_is_secure(_env) && !arm_el_is_aa64((_env), 3))) 1630 1631 #define A32_BANKED_CURRENT_REG_SET(_env, _regname, _val) \ 1632 A32_BANKED_REG_SET((_env), _regname, \ 1633 (arm_is_secure(_env) && !arm_el_is_aa64((_env), 3)), \ 1634 (_val)) 1635 1636 void arm_cpu_list(FILE *f, fprintf_function cpu_fprintf); 1637 uint32_t arm_phys_excp_target_el(CPUState *cs, uint32_t excp_idx, 1638 uint32_t cur_el, bool secure); 1639 1640 /* Interface between CPU and Interrupt controller. */ 1641 #ifndef CONFIG_USER_ONLY 1642 bool armv7m_nvic_can_take_pending_exception(void *opaque); 1643 #else 1644 static inline bool armv7m_nvic_can_take_pending_exception(void *opaque) 1645 { 1646 return true; 1647 } 1648 #endif 1649 /** 1650 * armv7m_nvic_set_pending: mark the specified exception as pending 1651 * @opaque: the NVIC 1652 * @irq: the exception number to mark pending 1653 * @secure: false for non-banked exceptions or for the nonsecure 1654 * version of a banked exception, true for the secure version of a banked 1655 * exception. 1656 * 1657 * Marks the specified exception as pending. Note that we will assert() 1658 * if @secure is true and @irq does not specify one of the fixed set 1659 * of architecturally banked exceptions. 1660 */ 1661 void armv7m_nvic_set_pending(void *opaque, int irq, bool secure); 1662 /** 1663 * armv7m_nvic_set_pending_derived: mark this derived exception as pending 1664 * @opaque: the NVIC 1665 * @irq: the exception number to mark pending 1666 * @secure: false for non-banked exceptions or for the nonsecure 1667 * version of a banked exception, true for the secure version of a banked 1668 * exception. 1669 * 1670 * Similar to armv7m_nvic_set_pending(), but specifically for derived 1671 * exceptions (exceptions generated in the course of trying to take 1672 * a different exception). 1673 */ 1674 void armv7m_nvic_set_pending_derived(void *opaque, int irq, bool secure); 1675 /** 1676 * armv7m_nvic_get_pending_irq_info: return highest priority pending 1677 * exception, and whether it targets Secure state 1678 * @opaque: the NVIC 1679 * @pirq: set to pending exception number 1680 * @ptargets_secure: set to whether pending exception targets Secure 1681 * 1682 * This function writes the number of the highest priority pending 1683 * exception (the one which would be made active by 1684 * armv7m_nvic_acknowledge_irq()) to @pirq, and sets @ptargets_secure 1685 * to true if the current highest priority pending exception should 1686 * be taken to Secure state, false for NS. 1687 */ 1688 void armv7m_nvic_get_pending_irq_info(void *opaque, int *pirq, 1689 bool *ptargets_secure); 1690 /** 1691 * armv7m_nvic_acknowledge_irq: make highest priority pending exception active 1692 * @opaque: the NVIC 1693 * 1694 * Move the current highest priority pending exception from the pending 1695 * state to the active state, and update v7m.exception to indicate that 1696 * it is the exception currently being handled. 1697 */ 1698 void armv7m_nvic_acknowledge_irq(void *opaque); 1699 /** 1700 * armv7m_nvic_complete_irq: complete specified interrupt or exception 1701 * @opaque: the NVIC 1702 * @irq: the exception number to complete 1703 * @secure: true if this exception was secure 1704 * 1705 * Returns: -1 if the irq was not active 1706 * 1 if completing this irq brought us back to base (no active irqs) 1707 * 0 if there is still an irq active after this one was completed 1708 * (Ignoring -1, this is the same as the RETTOBASE value before completion.) 1709 */ 1710 int armv7m_nvic_complete_irq(void *opaque, int irq, bool secure); 1711 /** 1712 * armv7m_nvic_raw_execution_priority: return the raw execution priority 1713 * @opaque: the NVIC 1714 * 1715 * Returns: the raw execution priority as defined by the v8M architecture. 1716 * This is the execution priority minus the effects of AIRCR.PRIS, 1717 * and minus any PRIMASK/FAULTMASK/BASEPRI priority boosting. 1718 * (v8M ARM ARM I_PKLD.) 1719 */ 1720 int armv7m_nvic_raw_execution_priority(void *opaque); 1721 /** 1722 * armv7m_nvic_neg_prio_requested: return true if the requested execution 1723 * priority is negative for the specified security state. 1724 * @opaque: the NVIC 1725 * @secure: the security state to test 1726 * This corresponds to the pseudocode IsReqExecPriNeg(). 1727 */ 1728 #ifndef CONFIG_USER_ONLY 1729 bool armv7m_nvic_neg_prio_requested(void *opaque, bool secure); 1730 #else 1731 static inline bool armv7m_nvic_neg_prio_requested(void *opaque, bool secure) 1732 { 1733 return false; 1734 } 1735 #endif 1736 1737 /* Interface for defining coprocessor registers. 1738 * Registers are defined in tables of arm_cp_reginfo structs 1739 * which are passed to define_arm_cp_regs(). 1740 */ 1741 1742 /* When looking up a coprocessor register we look for it 1743 * via an integer which encodes all of: 1744 * coprocessor number 1745 * Crn, Crm, opc1, opc2 fields 1746 * 32 or 64 bit register (ie is it accessed via MRC/MCR 1747 * or via MRRC/MCRR?) 1748 * non-secure/secure bank (AArch32 only) 1749 * We allow 4 bits for opc1 because MRRC/MCRR have a 4 bit field. 1750 * (In this case crn and opc2 should be zero.) 1751 * For AArch64, there is no 32/64 bit size distinction; 1752 * instead all registers have a 2 bit op0, 3 bit op1 and op2, 1753 * and 4 bit CRn and CRm. The encoding patterns are chosen 1754 * to be easy to convert to and from the KVM encodings, and also 1755 * so that the hashtable can contain both AArch32 and AArch64 1756 * registers (to allow for interprocessing where we might run 1757 * 32 bit code on a 64 bit core). 1758 */ 1759 /* This bit is private to our hashtable cpreg; in KVM register 1760 * IDs the AArch64/32 distinction is the KVM_REG_ARM/ARM64 1761 * in the upper bits of the 64 bit ID. 1762 */ 1763 #define CP_REG_AA64_SHIFT 28 1764 #define CP_REG_AA64_MASK (1 << CP_REG_AA64_SHIFT) 1765 1766 /* To enable banking of coprocessor registers depending on ns-bit we 1767 * add a bit to distinguish between secure and non-secure cpregs in the 1768 * hashtable. 1769 */ 1770 #define CP_REG_NS_SHIFT 29 1771 #define CP_REG_NS_MASK (1 << CP_REG_NS_SHIFT) 1772 1773 #define ENCODE_CP_REG(cp, is64, ns, crn, crm, opc1, opc2) \ 1774 ((ns) << CP_REG_NS_SHIFT | ((cp) << 16) | ((is64) << 15) | \ 1775 ((crn) << 11) | ((crm) << 7) | ((opc1) << 3) | (opc2)) 1776 1777 #define ENCODE_AA64_CP_REG(cp, crn, crm, op0, op1, op2) \ 1778 (CP_REG_AA64_MASK | \ 1779 ((cp) << CP_REG_ARM_COPROC_SHIFT) | \ 1780 ((op0) << CP_REG_ARM64_SYSREG_OP0_SHIFT) | \ 1781 ((op1) << CP_REG_ARM64_SYSREG_OP1_SHIFT) | \ 1782 ((crn) << CP_REG_ARM64_SYSREG_CRN_SHIFT) | \ 1783 ((crm) << CP_REG_ARM64_SYSREG_CRM_SHIFT) | \ 1784 ((op2) << CP_REG_ARM64_SYSREG_OP2_SHIFT)) 1785 1786 /* Convert a full 64 bit KVM register ID to the truncated 32 bit 1787 * version used as a key for the coprocessor register hashtable 1788 */ 1789 static inline uint32_t kvm_to_cpreg_id(uint64_t kvmid) 1790 { 1791 uint32_t cpregid = kvmid; 1792 if ((kvmid & CP_REG_ARCH_MASK) == CP_REG_ARM64) { 1793 cpregid |= CP_REG_AA64_MASK; 1794 } else { 1795 if ((kvmid & CP_REG_SIZE_MASK) == CP_REG_SIZE_U64) { 1796 cpregid |= (1 << 15); 1797 } 1798 1799 /* KVM is always non-secure so add the NS flag on AArch32 register 1800 * entries. 1801 */ 1802 cpregid |= 1 << CP_REG_NS_SHIFT; 1803 } 1804 return cpregid; 1805 } 1806 1807 /* Convert a truncated 32 bit hashtable key into the full 1808 * 64 bit KVM register ID. 1809 */ 1810 static inline uint64_t cpreg_to_kvm_id(uint32_t cpregid) 1811 { 1812 uint64_t kvmid; 1813 1814 if (cpregid & CP_REG_AA64_MASK) { 1815 kvmid = cpregid & ~CP_REG_AA64_MASK; 1816 kvmid |= CP_REG_SIZE_U64 | CP_REG_ARM64; 1817 } else { 1818 kvmid = cpregid & ~(1 << 15); 1819 if (cpregid & (1 << 15)) { 1820 kvmid |= CP_REG_SIZE_U64 | CP_REG_ARM; 1821 } else { 1822 kvmid |= CP_REG_SIZE_U32 | CP_REG_ARM; 1823 } 1824 } 1825 return kvmid; 1826 } 1827 1828 /* ARMCPRegInfo type field bits. If the SPECIAL bit is set this is a 1829 * special-behaviour cp reg and bits [11..8] indicate what behaviour 1830 * it has. Otherwise it is a simple cp reg, where CONST indicates that 1831 * TCG can assume the value to be constant (ie load at translate time) 1832 * and 64BIT indicates a 64 bit wide coprocessor register. SUPPRESS_TB_END 1833 * indicates that the TB should not be ended after a write to this register 1834 * (the default is that the TB ends after cp writes). OVERRIDE permits 1835 * a register definition to override a previous definition for the 1836 * same (cp, is64, crn, crm, opc1, opc2) tuple: either the new or the 1837 * old must have the OVERRIDE bit set. 1838 * ALIAS indicates that this register is an alias view of some underlying 1839 * state which is also visible via another register, and that the other 1840 * register is handling migration and reset; registers marked ALIAS will not be 1841 * migrated but may have their state set by syncing of register state from KVM. 1842 * NO_RAW indicates that this register has no underlying state and does not 1843 * support raw access for state saving/loading; it will not be used for either 1844 * migration or KVM state synchronization. (Typically this is for "registers" 1845 * which are actually used as instructions for cache maintenance and so on.) 1846 * IO indicates that this register does I/O and therefore its accesses 1847 * need to be surrounded by gen_io_start()/gen_io_end(). In particular, 1848 * registers which implement clocks or timers require this. 1849 */ 1850 #define ARM_CP_SPECIAL 0x0001 1851 #define ARM_CP_CONST 0x0002 1852 #define ARM_CP_64BIT 0x0004 1853 #define ARM_CP_SUPPRESS_TB_END 0x0008 1854 #define ARM_CP_OVERRIDE 0x0010 1855 #define ARM_CP_ALIAS 0x0020 1856 #define ARM_CP_IO 0x0040 1857 #define ARM_CP_NO_RAW 0x0080 1858 #define ARM_CP_NOP (ARM_CP_SPECIAL | 0x0100) 1859 #define ARM_CP_WFI (ARM_CP_SPECIAL | 0x0200) 1860 #define ARM_CP_NZCV (ARM_CP_SPECIAL | 0x0300) 1861 #define ARM_CP_CURRENTEL (ARM_CP_SPECIAL | 0x0400) 1862 #define ARM_CP_DC_ZVA (ARM_CP_SPECIAL | 0x0500) 1863 #define ARM_LAST_SPECIAL ARM_CP_DC_ZVA 1864 #define ARM_CP_FPU 0x1000 1865 #define ARM_CP_SVE 0x2000 1866 #define ARM_CP_NO_GDB 0x4000 1867 /* Used only as a terminator for ARMCPRegInfo lists */ 1868 #define ARM_CP_SENTINEL 0xffff 1869 /* Mask of only the flag bits in a type field */ 1870 #define ARM_CP_FLAG_MASK 0x70ff 1871 1872 /* Valid values for ARMCPRegInfo state field, indicating which of 1873 * the AArch32 and AArch64 execution states this register is visible in. 1874 * If the reginfo doesn't explicitly specify then it is AArch32 only. 1875 * If the reginfo is declared to be visible in both states then a second 1876 * reginfo is synthesised for the AArch32 view of the AArch64 register, 1877 * such that the AArch32 view is the lower 32 bits of the AArch64 one. 1878 * Note that we rely on the values of these enums as we iterate through 1879 * the various states in some places. 1880 */ 1881 enum { 1882 ARM_CP_STATE_AA32 = 0, 1883 ARM_CP_STATE_AA64 = 1, 1884 ARM_CP_STATE_BOTH = 2, 1885 }; 1886 1887 /* ARM CP register secure state flags. These flags identify security state 1888 * attributes for a given CP register entry. 1889 * The existence of both or neither secure and non-secure flags indicates that 1890 * the register has both a secure and non-secure hash entry. A single one of 1891 * these flags causes the register to only be hashed for the specified 1892 * security state. 1893 * Although definitions may have any combination of the S/NS bits, each 1894 * registered entry will only have one to identify whether the entry is secure 1895 * or non-secure. 1896 */ 1897 enum { 1898 ARM_CP_SECSTATE_S = (1 << 0), /* bit[0]: Secure state register */ 1899 ARM_CP_SECSTATE_NS = (1 << 1), /* bit[1]: Non-secure state register */ 1900 }; 1901 1902 /* Return true if cptype is a valid type field. This is used to try to 1903 * catch errors where the sentinel has been accidentally left off the end 1904 * of a list of registers. 1905 */ 1906 static inline bool cptype_valid(int cptype) 1907 { 1908 return ((cptype & ~ARM_CP_FLAG_MASK) == 0) 1909 || ((cptype & ARM_CP_SPECIAL) && 1910 ((cptype & ~ARM_CP_FLAG_MASK) <= ARM_LAST_SPECIAL)); 1911 } 1912 1913 /* Access rights: 1914 * We define bits for Read and Write access for what rev C of the v7-AR ARM ARM 1915 * defines as PL0 (user), PL1 (fiq/irq/svc/abt/und/sys, ie privileged), and 1916 * PL2 (hyp). The other level which has Read and Write bits is Secure PL1 1917 * (ie any of the privileged modes in Secure state, or Monitor mode). 1918 * If a register is accessible in one privilege level it's always accessible 1919 * in higher privilege levels too. Since "Secure PL1" also follows this rule 1920 * (ie anything visible in PL2 is visible in S-PL1, some things are only 1921 * visible in S-PL1) but "Secure PL1" is a bit of a mouthful, we bend the 1922 * terminology a little and call this PL3. 1923 * In AArch64 things are somewhat simpler as the PLx bits line up exactly 1924 * with the ELx exception levels. 1925 * 1926 * If access permissions for a register are more complex than can be 1927 * described with these bits, then use a laxer set of restrictions, and 1928 * do the more restrictive/complex check inside a helper function. 1929 */ 1930 #define PL3_R 0x80 1931 #define PL3_W 0x40 1932 #define PL2_R (0x20 | PL3_R) 1933 #define PL2_W (0x10 | PL3_W) 1934 #define PL1_R (0x08 | PL2_R) 1935 #define PL1_W (0x04 | PL2_W) 1936 #define PL0_R (0x02 | PL1_R) 1937 #define PL0_W (0x01 | PL1_W) 1938 1939 #define PL3_RW (PL3_R | PL3_W) 1940 #define PL2_RW (PL2_R | PL2_W) 1941 #define PL1_RW (PL1_R | PL1_W) 1942 #define PL0_RW (PL0_R | PL0_W) 1943 1944 /* Return the highest implemented Exception Level */ 1945 static inline int arm_highest_el(CPUARMState *env) 1946 { 1947 if (arm_feature(env, ARM_FEATURE_EL3)) { 1948 return 3; 1949 } 1950 if (arm_feature(env, ARM_FEATURE_EL2)) { 1951 return 2; 1952 } 1953 return 1; 1954 } 1955 1956 /* Return true if a v7M CPU is in Handler mode */ 1957 static inline bool arm_v7m_is_handler_mode(CPUARMState *env) 1958 { 1959 return env->v7m.exception != 0; 1960 } 1961 1962 /* Return the current Exception Level (as per ARMv8; note that this differs 1963 * from the ARMv7 Privilege Level). 1964 */ 1965 static inline int arm_current_el(CPUARMState *env) 1966 { 1967 if (arm_feature(env, ARM_FEATURE_M)) { 1968 return arm_v7m_is_handler_mode(env) || 1969 !(env->v7m.control[env->v7m.secure] & 1); 1970 } 1971 1972 if (is_a64(env)) { 1973 return extract32(env->pstate, 2, 2); 1974 } 1975 1976 switch (env->uncached_cpsr & 0x1f) { 1977 case ARM_CPU_MODE_USR: 1978 return 0; 1979 case ARM_CPU_MODE_HYP: 1980 return 2; 1981 case ARM_CPU_MODE_MON: 1982 return 3; 1983 default: 1984 if (arm_is_secure(env) && !arm_el_is_aa64(env, 3)) { 1985 /* If EL3 is 32-bit then all secure privileged modes run in 1986 * EL3 1987 */ 1988 return 3; 1989 } 1990 1991 return 1; 1992 } 1993 } 1994 1995 typedef struct ARMCPRegInfo ARMCPRegInfo; 1996 1997 typedef enum CPAccessResult { 1998 /* Access is permitted */ 1999 CP_ACCESS_OK = 0, 2000 /* Access fails due to a configurable trap or enable which would 2001 * result in a categorized exception syndrome giving information about 2002 * the failing instruction (ie syndrome category 0x3, 0x4, 0x5, 0x6, 2003 * 0xc or 0x18). The exception is taken to the usual target EL (EL1 or 2004 * PL1 if in EL0, otherwise to the current EL). 2005 */ 2006 CP_ACCESS_TRAP = 1, 2007 /* Access fails and results in an exception syndrome 0x0 ("uncategorized"). 2008 * Note that this is not a catch-all case -- the set of cases which may 2009 * result in this failure is specifically defined by the architecture. 2010 */ 2011 CP_ACCESS_TRAP_UNCATEGORIZED = 2, 2012 /* As CP_ACCESS_TRAP, but for traps directly to EL2 or EL3 */ 2013 CP_ACCESS_TRAP_EL2 = 3, 2014 CP_ACCESS_TRAP_EL3 = 4, 2015 /* As CP_ACCESS_UNCATEGORIZED, but for traps directly to EL2 or EL3 */ 2016 CP_ACCESS_TRAP_UNCATEGORIZED_EL2 = 5, 2017 CP_ACCESS_TRAP_UNCATEGORIZED_EL3 = 6, 2018 /* Access fails and results in an exception syndrome for an FP access, 2019 * trapped directly to EL2 or EL3 2020 */ 2021 CP_ACCESS_TRAP_FP_EL2 = 7, 2022 CP_ACCESS_TRAP_FP_EL3 = 8, 2023 } CPAccessResult; 2024 2025 /* Access functions for coprocessor registers. These cannot fail and 2026 * may not raise exceptions. 2027 */ 2028 typedef uint64_t CPReadFn(CPUARMState *env, const ARMCPRegInfo *opaque); 2029 typedef void CPWriteFn(CPUARMState *env, const ARMCPRegInfo *opaque, 2030 uint64_t value); 2031 /* Access permission check functions for coprocessor registers. */ 2032 typedef CPAccessResult CPAccessFn(CPUARMState *env, 2033 const ARMCPRegInfo *opaque, 2034 bool isread); 2035 /* Hook function for register reset */ 2036 typedef void CPResetFn(CPUARMState *env, const ARMCPRegInfo *opaque); 2037 2038 #define CP_ANY 0xff 2039 2040 /* Definition of an ARM coprocessor register */ 2041 struct ARMCPRegInfo { 2042 /* Name of register (useful mainly for debugging, need not be unique) */ 2043 const char *name; 2044 /* Location of register: coprocessor number and (crn,crm,opc1,opc2) 2045 * tuple. Any of crm, opc1 and opc2 may be CP_ANY to indicate a 2046 * 'wildcard' field -- any value of that field in the MRC/MCR insn 2047 * will be decoded to this register. The register read and write 2048 * callbacks will be passed an ARMCPRegInfo with the crn/crm/opc1/opc2 2049 * used by the program, so it is possible to register a wildcard and 2050 * then behave differently on read/write if necessary. 2051 * For 64 bit registers, only crm and opc1 are relevant; crn and opc2 2052 * must both be zero. 2053 * For AArch64-visible registers, opc0 is also used. 2054 * Since there are no "coprocessors" in AArch64, cp is purely used as a 2055 * way to distinguish (for KVM's benefit) guest-visible system registers 2056 * from demuxed ones provided to preserve the "no side effects on 2057 * KVM register read/write from QEMU" semantics. cp==0x13 is guest 2058 * visible (to match KVM's encoding); cp==0 will be converted to 2059 * cp==0x13 when the ARMCPRegInfo is registered, for convenience. 2060 */ 2061 uint8_t cp; 2062 uint8_t crn; 2063 uint8_t crm; 2064 uint8_t opc0; 2065 uint8_t opc1; 2066 uint8_t opc2; 2067 /* Execution state in which this register is visible: ARM_CP_STATE_* */ 2068 int state; 2069 /* Register type: ARM_CP_* bits/values */ 2070 int type; 2071 /* Access rights: PL*_[RW] */ 2072 int access; 2073 /* Security state: ARM_CP_SECSTATE_* bits/values */ 2074 int secure; 2075 /* The opaque pointer passed to define_arm_cp_regs_with_opaque() when 2076 * this register was defined: can be used to hand data through to the 2077 * register read/write functions, since they are passed the ARMCPRegInfo*. 2078 */ 2079 void *opaque; 2080 /* Value of this register, if it is ARM_CP_CONST. Otherwise, if 2081 * fieldoffset is non-zero, the reset value of the register. 2082 */ 2083 uint64_t resetvalue; 2084 /* Offset of the field in CPUARMState for this register. 2085 * 2086 * This is not needed if either: 2087 * 1. type is ARM_CP_CONST or one of the ARM_CP_SPECIALs 2088 * 2. both readfn and writefn are specified 2089 */ 2090 ptrdiff_t fieldoffset; /* offsetof(CPUARMState, field) */ 2091 2092 /* Offsets of the secure and non-secure fields in CPUARMState for the 2093 * register if it is banked. These fields are only used during the static 2094 * registration of a register. During hashing the bank associated 2095 * with a given security state is copied to fieldoffset which is used from 2096 * there on out. 2097 * 2098 * It is expected that register definitions use either fieldoffset or 2099 * bank_fieldoffsets in the definition but not both. It is also expected 2100 * that both bank offsets are set when defining a banked register. This 2101 * use indicates that a register is banked. 2102 */ 2103 ptrdiff_t bank_fieldoffsets[2]; 2104 2105 /* Function for making any access checks for this register in addition to 2106 * those specified by the 'access' permissions bits. If NULL, no extra 2107 * checks required. The access check is performed at runtime, not at 2108 * translate time. 2109 */ 2110 CPAccessFn *accessfn; 2111 /* Function for handling reads of this register. If NULL, then reads 2112 * will be done by loading from the offset into CPUARMState specified 2113 * by fieldoffset. 2114 */ 2115 CPReadFn *readfn; 2116 /* Function for handling writes of this register. If NULL, then writes 2117 * will be done by writing to the offset into CPUARMState specified 2118 * by fieldoffset. 2119 */ 2120 CPWriteFn *writefn; 2121 /* Function for doing a "raw" read; used when we need to copy 2122 * coprocessor state to the kernel for KVM or out for 2123 * migration. This only needs to be provided if there is also a 2124 * readfn and it has side effects (for instance clear-on-read bits). 2125 */ 2126 CPReadFn *raw_readfn; 2127 /* Function for doing a "raw" write; used when we need to copy KVM 2128 * kernel coprocessor state into userspace, or for inbound 2129 * migration. This only needs to be provided if there is also a 2130 * writefn and it masks out "unwritable" bits or has write-one-to-clear 2131 * or similar behaviour. 2132 */ 2133 CPWriteFn *raw_writefn; 2134 /* Function for resetting the register. If NULL, then reset will be done 2135 * by writing resetvalue to the field specified in fieldoffset. If 2136 * fieldoffset is 0 then no reset will be done. 2137 */ 2138 CPResetFn *resetfn; 2139 }; 2140 2141 /* Macros which are lvalues for the field in CPUARMState for the 2142 * ARMCPRegInfo *ri. 2143 */ 2144 #define CPREG_FIELD32(env, ri) \ 2145 (*(uint32_t *)((char *)(env) + (ri)->fieldoffset)) 2146 #define CPREG_FIELD64(env, ri) \ 2147 (*(uint64_t *)((char *)(env) + (ri)->fieldoffset)) 2148 2149 #define REGINFO_SENTINEL { .type = ARM_CP_SENTINEL } 2150 2151 void define_arm_cp_regs_with_opaque(ARMCPU *cpu, 2152 const ARMCPRegInfo *regs, void *opaque); 2153 void define_one_arm_cp_reg_with_opaque(ARMCPU *cpu, 2154 const ARMCPRegInfo *regs, void *opaque); 2155 static inline void define_arm_cp_regs(ARMCPU *cpu, const ARMCPRegInfo *regs) 2156 { 2157 define_arm_cp_regs_with_opaque(cpu, regs, 0); 2158 } 2159 static inline void define_one_arm_cp_reg(ARMCPU *cpu, const ARMCPRegInfo *regs) 2160 { 2161 define_one_arm_cp_reg_with_opaque(cpu, regs, 0); 2162 } 2163 const ARMCPRegInfo *get_arm_cp_reginfo(GHashTable *cpregs, uint32_t encoded_cp); 2164 2165 /* CPWriteFn that can be used to implement writes-ignored behaviour */ 2166 void arm_cp_write_ignore(CPUARMState *env, const ARMCPRegInfo *ri, 2167 uint64_t value); 2168 /* CPReadFn that can be used for read-as-zero behaviour */ 2169 uint64_t arm_cp_read_zero(CPUARMState *env, const ARMCPRegInfo *ri); 2170 2171 /* CPResetFn that does nothing, for use if no reset is required even 2172 * if fieldoffset is non zero. 2173 */ 2174 void arm_cp_reset_ignore(CPUARMState *env, const ARMCPRegInfo *opaque); 2175 2176 /* Return true if this reginfo struct's field in the cpu state struct 2177 * is 64 bits wide. 2178 */ 2179 static inline bool cpreg_field_is_64bit(const ARMCPRegInfo *ri) 2180 { 2181 return (ri->state == ARM_CP_STATE_AA64) || (ri->type & ARM_CP_64BIT); 2182 } 2183 2184 static inline bool cp_access_ok(int current_el, 2185 const ARMCPRegInfo *ri, int isread) 2186 { 2187 return (ri->access >> ((current_el * 2) + isread)) & 1; 2188 } 2189 2190 /* Raw read of a coprocessor register (as needed for migration, etc) */ 2191 uint64_t read_raw_cp_reg(CPUARMState *env, const ARMCPRegInfo *ri); 2192 2193 /** 2194 * write_list_to_cpustate 2195 * @cpu: ARMCPU 2196 * 2197 * For each register listed in the ARMCPU cpreg_indexes list, write 2198 * its value from the cpreg_values list into the ARMCPUState structure. 2199 * This updates TCG's working data structures from KVM data or 2200 * from incoming migration state. 2201 * 2202 * Returns: true if all register values were updated correctly, 2203 * false if some register was unknown or could not be written. 2204 * Note that we do not stop early on failure -- we will attempt 2205 * writing all registers in the list. 2206 */ 2207 bool write_list_to_cpustate(ARMCPU *cpu); 2208 2209 /** 2210 * write_cpustate_to_list: 2211 * @cpu: ARMCPU 2212 * 2213 * For each register listed in the ARMCPU cpreg_indexes list, write 2214 * its value from the ARMCPUState structure into the cpreg_values list. 2215 * This is used to copy info from TCG's working data structures into 2216 * KVM or for outbound migration. 2217 * 2218 * Returns: true if all register values were read correctly, 2219 * false if some register was unknown or could not be read. 2220 * Note that we do not stop early on failure -- we will attempt 2221 * reading all registers in the list. 2222 */ 2223 bool write_cpustate_to_list(ARMCPU *cpu); 2224 2225 #define ARM_CPUID_TI915T 0x54029152 2226 #define ARM_CPUID_TI925T 0x54029252 2227 2228 #if defined(CONFIG_USER_ONLY) 2229 #define TARGET_PAGE_BITS 12 2230 #else 2231 /* ARMv7 and later CPUs have 4K pages minimum, but ARMv5 and v6 2232 * have to support 1K tiny pages. 2233 */ 2234 #define TARGET_PAGE_BITS_VARY 2235 #define TARGET_PAGE_BITS_MIN 10 2236 #endif 2237 2238 #if defined(TARGET_AARCH64) 2239 # define TARGET_PHYS_ADDR_SPACE_BITS 48 2240 # define TARGET_VIRT_ADDR_SPACE_BITS 64 2241 #else 2242 # define TARGET_PHYS_ADDR_SPACE_BITS 40 2243 # define TARGET_VIRT_ADDR_SPACE_BITS 32 2244 #endif 2245 2246 /** 2247 * arm_hcr_el2_imo(): Return the effective value of HCR_EL2.IMO. 2248 * Depending on the values of HCR_EL2.E2H and TGE, this may be 2249 * "behaves as 1 for all purposes other than direct read/write" or 2250 * "behaves as 0 for all purposes other than direct read/write" 2251 */ 2252 static inline bool arm_hcr_el2_imo(CPUARMState *env) 2253 { 2254 switch (env->cp15.hcr_el2 & (HCR_TGE | HCR_E2H)) { 2255 case HCR_TGE: 2256 return true; 2257 case HCR_TGE | HCR_E2H: 2258 return false; 2259 default: 2260 return env->cp15.hcr_el2 & HCR_IMO; 2261 } 2262 } 2263 2264 /** 2265 * arm_hcr_el2_fmo(): Return the effective value of HCR_EL2.FMO. 2266 */ 2267 static inline bool arm_hcr_el2_fmo(CPUARMState *env) 2268 { 2269 switch (env->cp15.hcr_el2 & (HCR_TGE | HCR_E2H)) { 2270 case HCR_TGE: 2271 return true; 2272 case HCR_TGE | HCR_E2H: 2273 return false; 2274 default: 2275 return env->cp15.hcr_el2 & HCR_FMO; 2276 } 2277 } 2278 2279 /** 2280 * arm_hcr_el2_amo(): Return the effective value of HCR_EL2.AMO. 2281 */ 2282 static inline bool arm_hcr_el2_amo(CPUARMState *env) 2283 { 2284 switch (env->cp15.hcr_el2 & (HCR_TGE | HCR_E2H)) { 2285 case HCR_TGE: 2286 return true; 2287 case HCR_TGE | HCR_E2H: 2288 return false; 2289 default: 2290 return env->cp15.hcr_el2 & HCR_AMO; 2291 } 2292 } 2293 2294 static inline bool arm_excp_unmasked(CPUState *cs, unsigned int excp_idx, 2295 unsigned int target_el) 2296 { 2297 CPUARMState *env = cs->env_ptr; 2298 unsigned int cur_el = arm_current_el(env); 2299 bool secure = arm_is_secure(env); 2300 bool pstate_unmasked; 2301 int8_t unmasked = 0; 2302 2303 /* Don't take exceptions if they target a lower EL. 2304 * This check should catch any exceptions that would not be taken but left 2305 * pending. 2306 */ 2307 if (cur_el > target_el) { 2308 return false; 2309 } 2310 2311 switch (excp_idx) { 2312 case EXCP_FIQ: 2313 pstate_unmasked = !(env->daif & PSTATE_F); 2314 break; 2315 2316 case EXCP_IRQ: 2317 pstate_unmasked = !(env->daif & PSTATE_I); 2318 break; 2319 2320 case EXCP_VFIQ: 2321 if (secure || !arm_hcr_el2_fmo(env) || (env->cp15.hcr_el2 & HCR_TGE)) { 2322 /* VFIQs are only taken when hypervized and non-secure. */ 2323 return false; 2324 } 2325 return !(env->daif & PSTATE_F); 2326 case EXCP_VIRQ: 2327 if (secure || !arm_hcr_el2_imo(env) || (env->cp15.hcr_el2 & HCR_TGE)) { 2328 /* VIRQs are only taken when hypervized and non-secure. */ 2329 return false; 2330 } 2331 return !(env->daif & PSTATE_I); 2332 default: 2333 g_assert_not_reached(); 2334 } 2335 2336 /* Use the target EL, current execution state and SCR/HCR settings to 2337 * determine whether the corresponding CPSR bit is used to mask the 2338 * interrupt. 2339 */ 2340 if ((target_el > cur_el) && (target_el != 1)) { 2341 /* Exceptions targeting a higher EL may not be maskable */ 2342 if (arm_feature(env, ARM_FEATURE_AARCH64)) { 2343 /* 64-bit masking rules are simple: exceptions to EL3 2344 * can't be masked, and exceptions to EL2 can only be 2345 * masked from Secure state. The HCR and SCR settings 2346 * don't affect the masking logic, only the interrupt routing. 2347 */ 2348 if (target_el == 3 || !secure) { 2349 unmasked = 1; 2350 } 2351 } else { 2352 /* The old 32-bit-only environment has a more complicated 2353 * masking setup. HCR and SCR bits not only affect interrupt 2354 * routing but also change the behaviour of masking. 2355 */ 2356 bool hcr, scr; 2357 2358 switch (excp_idx) { 2359 case EXCP_FIQ: 2360 /* If FIQs are routed to EL3 or EL2 then there are cases where 2361 * we override the CPSR.F in determining if the exception is 2362 * masked or not. If neither of these are set then we fall back 2363 * to the CPSR.F setting otherwise we further assess the state 2364 * below. 2365 */ 2366 hcr = arm_hcr_el2_fmo(env); 2367 scr = (env->cp15.scr_el3 & SCR_FIQ); 2368 2369 /* When EL3 is 32-bit, the SCR.FW bit controls whether the 2370 * CPSR.F bit masks FIQ interrupts when taken in non-secure 2371 * state. If SCR.FW is set then FIQs can be masked by CPSR.F 2372 * when non-secure but only when FIQs are only routed to EL3. 2373 */ 2374 scr = scr && !((env->cp15.scr_el3 & SCR_FW) && !hcr); 2375 break; 2376 case EXCP_IRQ: 2377 /* When EL3 execution state is 32-bit, if HCR.IMO is set then 2378 * we may override the CPSR.I masking when in non-secure state. 2379 * The SCR.IRQ setting has already been taken into consideration 2380 * when setting the target EL, so it does not have a further 2381 * affect here. 2382 */ 2383 hcr = arm_hcr_el2_imo(env); 2384 scr = false; 2385 break; 2386 default: 2387 g_assert_not_reached(); 2388 } 2389 2390 if ((scr || hcr) && !secure) { 2391 unmasked = 1; 2392 } 2393 } 2394 } 2395 2396 /* The PSTATE bits only mask the interrupt if we have not overriden the 2397 * ability above. 2398 */ 2399 return unmasked || pstate_unmasked; 2400 } 2401 2402 #define ARM_CPU_TYPE_SUFFIX "-" TYPE_ARM_CPU 2403 #define ARM_CPU_TYPE_NAME(name) (name ARM_CPU_TYPE_SUFFIX) 2404 #define CPU_RESOLVING_TYPE TYPE_ARM_CPU 2405 2406 #define cpu_signal_handler cpu_arm_signal_handler 2407 #define cpu_list arm_cpu_list 2408 2409 /* ARM has the following "translation regimes" (as the ARM ARM calls them): 2410 * 2411 * If EL3 is 64-bit: 2412 * + NonSecure EL1 & 0 stage 1 2413 * + NonSecure EL1 & 0 stage 2 2414 * + NonSecure EL2 2415 * + Secure EL1 & EL0 2416 * + Secure EL3 2417 * If EL3 is 32-bit: 2418 * + NonSecure PL1 & 0 stage 1 2419 * + NonSecure PL1 & 0 stage 2 2420 * + NonSecure PL2 2421 * + Secure PL0 & PL1 2422 * (reminder: for 32 bit EL3, Secure PL1 is *EL3*, not EL1.) 2423 * 2424 * For QEMU, an mmu_idx is not quite the same as a translation regime because: 2425 * 1. we need to split the "EL1 & 0" regimes into two mmu_idxes, because they 2426 * may differ in access permissions even if the VA->PA map is the same 2427 * 2. we want to cache in our TLB the full VA->IPA->PA lookup for a stage 1+2 2428 * translation, which means that we have one mmu_idx that deals with two 2429 * concatenated translation regimes [this sort of combined s1+2 TLB is 2430 * architecturally permitted] 2431 * 3. we don't need to allocate an mmu_idx to translations that we won't be 2432 * handling via the TLB. The only way to do a stage 1 translation without 2433 * the immediate stage 2 translation is via the ATS or AT system insns, 2434 * which can be slow-pathed and always do a page table walk. 2435 * 4. we can also safely fold together the "32 bit EL3" and "64 bit EL3" 2436 * translation regimes, because they map reasonably well to each other 2437 * and they can't both be active at the same time. 2438 * This gives us the following list of mmu_idx values: 2439 * 2440 * NS EL0 (aka NS PL0) stage 1+2 2441 * NS EL1 (aka NS PL1) stage 1+2 2442 * NS EL2 (aka NS PL2) 2443 * S EL3 (aka S PL1) 2444 * S EL0 (aka S PL0) 2445 * S EL1 (not used if EL3 is 32 bit) 2446 * NS EL0+1 stage 2 2447 * 2448 * (The last of these is an mmu_idx because we want to be able to use the TLB 2449 * for the accesses done as part of a stage 1 page table walk, rather than 2450 * having to walk the stage 2 page table over and over.) 2451 * 2452 * R profile CPUs have an MPU, but can use the same set of MMU indexes 2453 * as A profile. They only need to distinguish NS EL0 and NS EL1 (and 2454 * NS EL2 if we ever model a Cortex-R52). 2455 * 2456 * M profile CPUs are rather different as they do not have a true MMU. 2457 * They have the following different MMU indexes: 2458 * User 2459 * Privileged 2460 * User, execution priority negative (ie the MPU HFNMIENA bit may apply) 2461 * Privileged, execution priority negative (ditto) 2462 * If the CPU supports the v8M Security Extension then there are also: 2463 * Secure User 2464 * Secure Privileged 2465 * Secure User, execution priority negative 2466 * Secure Privileged, execution priority negative 2467 * 2468 * The ARMMMUIdx and the mmu index value used by the core QEMU TLB code 2469 * are not quite the same -- different CPU types (most notably M profile 2470 * vs A/R profile) would like to use MMU indexes with different semantics, 2471 * but since we don't ever need to use all of those in a single CPU we 2472 * can avoid setting NB_MMU_MODES to more than 8. The lower bits of 2473 * ARMMMUIdx are the core TLB mmu index, and the higher bits are always 2474 * the same for any particular CPU. 2475 * Variables of type ARMMUIdx are always full values, and the core 2476 * index values are in variables of type 'int'. 2477 * 2478 * Our enumeration includes at the end some entries which are not "true" 2479 * mmu_idx values in that they don't have corresponding TLBs and are only 2480 * valid for doing slow path page table walks. 2481 * 2482 * The constant names here are patterned after the general style of the names 2483 * of the AT/ATS operations. 2484 * The values used are carefully arranged to make mmu_idx => EL lookup easy. 2485 * For M profile we arrange them to have a bit for priv, a bit for negpri 2486 * and a bit for secure. 2487 */ 2488 #define ARM_MMU_IDX_A 0x10 /* A profile */ 2489 #define ARM_MMU_IDX_NOTLB 0x20 /* does not have a TLB */ 2490 #define ARM_MMU_IDX_M 0x40 /* M profile */ 2491 2492 /* meanings of the bits for M profile mmu idx values */ 2493 #define ARM_MMU_IDX_M_PRIV 0x1 2494 #define ARM_MMU_IDX_M_NEGPRI 0x2 2495 #define ARM_MMU_IDX_M_S 0x4 2496 2497 #define ARM_MMU_IDX_TYPE_MASK (~0x7) 2498 #define ARM_MMU_IDX_COREIDX_MASK 0x7 2499 2500 typedef enum ARMMMUIdx { 2501 ARMMMUIdx_S12NSE0 = 0 | ARM_MMU_IDX_A, 2502 ARMMMUIdx_S12NSE1 = 1 | ARM_MMU_IDX_A, 2503 ARMMMUIdx_S1E2 = 2 | ARM_MMU_IDX_A, 2504 ARMMMUIdx_S1E3 = 3 | ARM_MMU_IDX_A, 2505 ARMMMUIdx_S1SE0 = 4 | ARM_MMU_IDX_A, 2506 ARMMMUIdx_S1SE1 = 5 | ARM_MMU_IDX_A, 2507 ARMMMUIdx_S2NS = 6 | ARM_MMU_IDX_A, 2508 ARMMMUIdx_MUser = 0 | ARM_MMU_IDX_M, 2509 ARMMMUIdx_MPriv = 1 | ARM_MMU_IDX_M, 2510 ARMMMUIdx_MUserNegPri = 2 | ARM_MMU_IDX_M, 2511 ARMMMUIdx_MPrivNegPri = 3 | ARM_MMU_IDX_M, 2512 ARMMMUIdx_MSUser = 4 | ARM_MMU_IDX_M, 2513 ARMMMUIdx_MSPriv = 5 | ARM_MMU_IDX_M, 2514 ARMMMUIdx_MSUserNegPri = 6 | ARM_MMU_IDX_M, 2515 ARMMMUIdx_MSPrivNegPri = 7 | ARM_MMU_IDX_M, 2516 /* Indexes below here don't have TLBs and are used only for AT system 2517 * instructions or for the first stage of an S12 page table walk. 2518 */ 2519 ARMMMUIdx_S1NSE0 = 0 | ARM_MMU_IDX_NOTLB, 2520 ARMMMUIdx_S1NSE1 = 1 | ARM_MMU_IDX_NOTLB, 2521 } ARMMMUIdx; 2522 2523 /* Bit macros for the core-mmu-index values for each index, 2524 * for use when calling tlb_flush_by_mmuidx() and friends. 2525 */ 2526 typedef enum ARMMMUIdxBit { 2527 ARMMMUIdxBit_S12NSE0 = 1 << 0, 2528 ARMMMUIdxBit_S12NSE1 = 1 << 1, 2529 ARMMMUIdxBit_S1E2 = 1 << 2, 2530 ARMMMUIdxBit_S1E3 = 1 << 3, 2531 ARMMMUIdxBit_S1SE0 = 1 << 4, 2532 ARMMMUIdxBit_S1SE1 = 1 << 5, 2533 ARMMMUIdxBit_S2NS = 1 << 6, 2534 ARMMMUIdxBit_MUser = 1 << 0, 2535 ARMMMUIdxBit_MPriv = 1 << 1, 2536 ARMMMUIdxBit_MUserNegPri = 1 << 2, 2537 ARMMMUIdxBit_MPrivNegPri = 1 << 3, 2538 ARMMMUIdxBit_MSUser = 1 << 4, 2539 ARMMMUIdxBit_MSPriv = 1 << 5, 2540 ARMMMUIdxBit_MSUserNegPri = 1 << 6, 2541 ARMMMUIdxBit_MSPrivNegPri = 1 << 7, 2542 } ARMMMUIdxBit; 2543 2544 #define MMU_USER_IDX 0 2545 2546 static inline int arm_to_core_mmu_idx(ARMMMUIdx mmu_idx) 2547 { 2548 return mmu_idx & ARM_MMU_IDX_COREIDX_MASK; 2549 } 2550 2551 static inline ARMMMUIdx core_to_arm_mmu_idx(CPUARMState *env, int mmu_idx) 2552 { 2553 if (arm_feature(env, ARM_FEATURE_M)) { 2554 return mmu_idx | ARM_MMU_IDX_M; 2555 } else { 2556 return mmu_idx | ARM_MMU_IDX_A; 2557 } 2558 } 2559 2560 /* Return the exception level we're running at if this is our mmu_idx */ 2561 static inline int arm_mmu_idx_to_el(ARMMMUIdx mmu_idx) 2562 { 2563 switch (mmu_idx & ARM_MMU_IDX_TYPE_MASK) { 2564 case ARM_MMU_IDX_A: 2565 return mmu_idx & 3; 2566 case ARM_MMU_IDX_M: 2567 return mmu_idx & ARM_MMU_IDX_M_PRIV; 2568 default: 2569 g_assert_not_reached(); 2570 } 2571 } 2572 2573 /* Return the MMU index for a v7M CPU in the specified security and 2574 * privilege state 2575 */ 2576 static inline ARMMMUIdx arm_v7m_mmu_idx_for_secstate_and_priv(CPUARMState *env, 2577 bool secstate, 2578 bool priv) 2579 { 2580 ARMMMUIdx mmu_idx = ARM_MMU_IDX_M; 2581 2582 if (priv) { 2583 mmu_idx |= ARM_MMU_IDX_M_PRIV; 2584 } 2585 2586 if (armv7m_nvic_neg_prio_requested(env->nvic, secstate)) { 2587 mmu_idx |= ARM_MMU_IDX_M_NEGPRI; 2588 } 2589 2590 if (secstate) { 2591 mmu_idx |= ARM_MMU_IDX_M_S; 2592 } 2593 2594 return mmu_idx; 2595 } 2596 2597 /* Return the MMU index for a v7M CPU in the specified security state */ 2598 static inline ARMMMUIdx arm_v7m_mmu_idx_for_secstate(CPUARMState *env, 2599 bool secstate) 2600 { 2601 bool priv = arm_current_el(env) != 0; 2602 2603 return arm_v7m_mmu_idx_for_secstate_and_priv(env, secstate, priv); 2604 } 2605 2606 /* Determine the current mmu_idx to use for normal loads/stores */ 2607 static inline int cpu_mmu_index(CPUARMState *env, bool ifetch) 2608 { 2609 int el = arm_current_el(env); 2610 2611 if (arm_feature(env, ARM_FEATURE_M)) { 2612 ARMMMUIdx mmu_idx = arm_v7m_mmu_idx_for_secstate(env, env->v7m.secure); 2613 2614 return arm_to_core_mmu_idx(mmu_idx); 2615 } 2616 2617 if (el < 2 && arm_is_secure_below_el3(env)) { 2618 return arm_to_core_mmu_idx(ARMMMUIdx_S1SE0 + el); 2619 } 2620 return el; 2621 } 2622 2623 /* Indexes used when registering address spaces with cpu_address_space_init */ 2624 typedef enum ARMASIdx { 2625 ARMASIdx_NS = 0, 2626 ARMASIdx_S = 1, 2627 } ARMASIdx; 2628 2629 /* Return the Exception Level targeted by debug exceptions. */ 2630 static inline int arm_debug_target_el(CPUARMState *env) 2631 { 2632 bool secure = arm_is_secure(env); 2633 bool route_to_el2 = false; 2634 2635 if (arm_feature(env, ARM_FEATURE_EL2) && !secure) { 2636 route_to_el2 = env->cp15.hcr_el2 & HCR_TGE || 2637 env->cp15.mdcr_el2 & (1 << 8); 2638 } 2639 2640 if (route_to_el2) { 2641 return 2; 2642 } else if (arm_feature(env, ARM_FEATURE_EL3) && 2643 !arm_el_is_aa64(env, 3) && secure) { 2644 return 3; 2645 } else { 2646 return 1; 2647 } 2648 } 2649 2650 static inline bool arm_v7m_csselr_razwi(ARMCPU *cpu) 2651 { 2652 /* If all the CLIDR.Ctypem bits are 0 there are no caches, and 2653 * CSSELR is RAZ/WI. 2654 */ 2655 return (cpu->clidr & R_V7M_CLIDR_CTYPE_ALL_MASK) != 0; 2656 } 2657 2658 static inline bool aa64_generate_debug_exceptions(CPUARMState *env) 2659 { 2660 if (arm_is_secure(env)) { 2661 /* MDCR_EL3.SDD disables debug events from Secure state */ 2662 if (extract32(env->cp15.mdcr_el3, 16, 1) != 0 2663 || arm_current_el(env) == 3) { 2664 return false; 2665 } 2666 } 2667 2668 if (arm_current_el(env) == arm_debug_target_el(env)) { 2669 if ((extract32(env->cp15.mdscr_el1, 13, 1) == 0) 2670 || (env->daif & PSTATE_D)) { 2671 return false; 2672 } 2673 } 2674 return true; 2675 } 2676 2677 static inline bool aa32_generate_debug_exceptions(CPUARMState *env) 2678 { 2679 int el = arm_current_el(env); 2680 2681 if (el == 0 && arm_el_is_aa64(env, 1)) { 2682 return aa64_generate_debug_exceptions(env); 2683 } 2684 2685 if (arm_is_secure(env)) { 2686 int spd; 2687 2688 if (el == 0 && (env->cp15.sder & 1)) { 2689 /* SDER.SUIDEN means debug exceptions from Secure EL0 2690 * are always enabled. Otherwise they are controlled by 2691 * SDCR.SPD like those from other Secure ELs. 2692 */ 2693 return true; 2694 } 2695 2696 spd = extract32(env->cp15.mdcr_el3, 14, 2); 2697 switch (spd) { 2698 case 1: 2699 /* SPD == 0b01 is reserved, but behaves as 0b00. */ 2700 case 0: 2701 /* For 0b00 we return true if external secure invasive debug 2702 * is enabled. On real hardware this is controlled by external 2703 * signals to the core. QEMU always permits debug, and behaves 2704 * as if DBGEN, SPIDEN, NIDEN and SPNIDEN are all tied high. 2705 */ 2706 return true; 2707 case 2: 2708 return false; 2709 case 3: 2710 return true; 2711 } 2712 } 2713 2714 return el != 2; 2715 } 2716 2717 /* Return true if debugging exceptions are currently enabled. 2718 * This corresponds to what in ARM ARM pseudocode would be 2719 * if UsingAArch32() then 2720 * return AArch32.GenerateDebugExceptions() 2721 * else 2722 * return AArch64.GenerateDebugExceptions() 2723 * We choose to push the if() down into this function for clarity, 2724 * since the pseudocode has it at all callsites except for the one in 2725 * CheckSoftwareStep(), where it is elided because both branches would 2726 * always return the same value. 2727 * 2728 * Parts of the pseudocode relating to EL2 and EL3 are omitted because we 2729 * don't yet implement those exception levels or their associated trap bits. 2730 */ 2731 static inline bool arm_generate_debug_exceptions(CPUARMState *env) 2732 { 2733 if (env->aarch64) { 2734 return aa64_generate_debug_exceptions(env); 2735 } else { 2736 return aa32_generate_debug_exceptions(env); 2737 } 2738 } 2739 2740 /* Is single-stepping active? (Note that the "is EL_D AArch64?" check 2741 * implicitly means this always returns false in pre-v8 CPUs.) 2742 */ 2743 static inline bool arm_singlestep_active(CPUARMState *env) 2744 { 2745 return extract32(env->cp15.mdscr_el1, 0, 1) 2746 && arm_el_is_aa64(env, arm_debug_target_el(env)) 2747 && arm_generate_debug_exceptions(env); 2748 } 2749 2750 static inline bool arm_sctlr_b(CPUARMState *env) 2751 { 2752 return 2753 /* We need not implement SCTLR.ITD in user-mode emulation, so 2754 * let linux-user ignore the fact that it conflicts with SCTLR_B. 2755 * This lets people run BE32 binaries with "-cpu any". 2756 */ 2757 #ifndef CONFIG_USER_ONLY 2758 !arm_feature(env, ARM_FEATURE_V7) && 2759 #endif 2760 (env->cp15.sctlr_el[1] & SCTLR_B) != 0; 2761 } 2762 2763 /* Return true if the processor is in big-endian mode. */ 2764 static inline bool arm_cpu_data_is_big_endian(CPUARMState *env) 2765 { 2766 int cur_el; 2767 2768 /* In 32bit endianness is determined by looking at CPSR's E bit */ 2769 if (!is_a64(env)) { 2770 return 2771 #ifdef CONFIG_USER_ONLY 2772 /* In system mode, BE32 is modelled in line with the 2773 * architecture (as word-invariant big-endianness), where loads 2774 * and stores are done little endian but from addresses which 2775 * are adjusted by XORing with the appropriate constant. So the 2776 * endianness to use for the raw data access is not affected by 2777 * SCTLR.B. 2778 * In user mode, however, we model BE32 as byte-invariant 2779 * big-endianness (because user-only code cannot tell the 2780 * difference), and so we need to use a data access endianness 2781 * that depends on SCTLR.B. 2782 */ 2783 arm_sctlr_b(env) || 2784 #endif 2785 ((env->uncached_cpsr & CPSR_E) ? 1 : 0); 2786 } 2787 2788 cur_el = arm_current_el(env); 2789 2790 if (cur_el == 0) { 2791 return (env->cp15.sctlr_el[1] & SCTLR_E0E) != 0; 2792 } 2793 2794 return (env->cp15.sctlr_el[cur_el] & SCTLR_EE) != 0; 2795 } 2796 2797 #include "exec/cpu-all.h" 2798 2799 /* Bit usage in the TB flags field: bit 31 indicates whether we are 2800 * in 32 or 64 bit mode. The meaning of the other bits depends on that. 2801 * We put flags which are shared between 32 and 64 bit mode at the top 2802 * of the word, and flags which apply to only one mode at the bottom. 2803 */ 2804 #define ARM_TBFLAG_AARCH64_STATE_SHIFT 31 2805 #define ARM_TBFLAG_AARCH64_STATE_MASK (1U << ARM_TBFLAG_AARCH64_STATE_SHIFT) 2806 #define ARM_TBFLAG_MMUIDX_SHIFT 28 2807 #define ARM_TBFLAG_MMUIDX_MASK (0x7 << ARM_TBFLAG_MMUIDX_SHIFT) 2808 #define ARM_TBFLAG_SS_ACTIVE_SHIFT 27 2809 #define ARM_TBFLAG_SS_ACTIVE_MASK (1 << ARM_TBFLAG_SS_ACTIVE_SHIFT) 2810 #define ARM_TBFLAG_PSTATE_SS_SHIFT 26 2811 #define ARM_TBFLAG_PSTATE_SS_MASK (1 << ARM_TBFLAG_PSTATE_SS_SHIFT) 2812 /* Target EL if we take a floating-point-disabled exception */ 2813 #define ARM_TBFLAG_FPEXC_EL_SHIFT 24 2814 #define ARM_TBFLAG_FPEXC_EL_MASK (0x3 << ARM_TBFLAG_FPEXC_EL_SHIFT) 2815 2816 /* Bit usage when in AArch32 state: */ 2817 #define ARM_TBFLAG_THUMB_SHIFT 0 2818 #define ARM_TBFLAG_THUMB_MASK (1 << ARM_TBFLAG_THUMB_SHIFT) 2819 #define ARM_TBFLAG_VECLEN_SHIFT 1 2820 #define ARM_TBFLAG_VECLEN_MASK (0x7 << ARM_TBFLAG_VECLEN_SHIFT) 2821 #define ARM_TBFLAG_VECSTRIDE_SHIFT 4 2822 #define ARM_TBFLAG_VECSTRIDE_MASK (0x3 << ARM_TBFLAG_VECSTRIDE_SHIFT) 2823 #define ARM_TBFLAG_VFPEN_SHIFT 7 2824 #define ARM_TBFLAG_VFPEN_MASK (1 << ARM_TBFLAG_VFPEN_SHIFT) 2825 #define ARM_TBFLAG_CONDEXEC_SHIFT 8 2826 #define ARM_TBFLAG_CONDEXEC_MASK (0xff << ARM_TBFLAG_CONDEXEC_SHIFT) 2827 #define ARM_TBFLAG_SCTLR_B_SHIFT 16 2828 #define ARM_TBFLAG_SCTLR_B_MASK (1 << ARM_TBFLAG_SCTLR_B_SHIFT) 2829 /* We store the bottom two bits of the CPAR as TB flags and handle 2830 * checks on the other bits at runtime 2831 */ 2832 #define ARM_TBFLAG_XSCALE_CPAR_SHIFT 17 2833 #define ARM_TBFLAG_XSCALE_CPAR_MASK (3 << ARM_TBFLAG_XSCALE_CPAR_SHIFT) 2834 /* Indicates whether cp register reads and writes by guest code should access 2835 * the secure or nonsecure bank of banked registers; note that this is not 2836 * the same thing as the current security state of the processor! 2837 */ 2838 #define ARM_TBFLAG_NS_SHIFT 19 2839 #define ARM_TBFLAG_NS_MASK (1 << ARM_TBFLAG_NS_SHIFT) 2840 #define ARM_TBFLAG_BE_DATA_SHIFT 20 2841 #define ARM_TBFLAG_BE_DATA_MASK (1 << ARM_TBFLAG_BE_DATA_SHIFT) 2842 /* For M profile only, Handler (ie not Thread) mode */ 2843 #define ARM_TBFLAG_HANDLER_SHIFT 21 2844 #define ARM_TBFLAG_HANDLER_MASK (1 << ARM_TBFLAG_HANDLER_SHIFT) 2845 2846 /* Bit usage when in AArch64 state */ 2847 #define ARM_TBFLAG_TBI0_SHIFT 0 /* TBI0 for EL0/1 or TBI for EL2/3 */ 2848 #define ARM_TBFLAG_TBI0_MASK (0x1ull << ARM_TBFLAG_TBI0_SHIFT) 2849 #define ARM_TBFLAG_TBI1_SHIFT 1 /* TBI1 for EL0/1 */ 2850 #define ARM_TBFLAG_TBI1_MASK (0x1ull << ARM_TBFLAG_TBI1_SHIFT) 2851 #define ARM_TBFLAG_SVEEXC_EL_SHIFT 2 2852 #define ARM_TBFLAG_SVEEXC_EL_MASK (0x3 << ARM_TBFLAG_SVEEXC_EL_SHIFT) 2853 #define ARM_TBFLAG_ZCR_LEN_SHIFT 4 2854 #define ARM_TBFLAG_ZCR_LEN_MASK (0xf << ARM_TBFLAG_ZCR_LEN_SHIFT) 2855 2856 /* some convenience accessor macros */ 2857 #define ARM_TBFLAG_AARCH64_STATE(F) \ 2858 (((F) & ARM_TBFLAG_AARCH64_STATE_MASK) >> ARM_TBFLAG_AARCH64_STATE_SHIFT) 2859 #define ARM_TBFLAG_MMUIDX(F) \ 2860 (((F) & ARM_TBFLAG_MMUIDX_MASK) >> ARM_TBFLAG_MMUIDX_SHIFT) 2861 #define ARM_TBFLAG_SS_ACTIVE(F) \ 2862 (((F) & ARM_TBFLAG_SS_ACTIVE_MASK) >> ARM_TBFLAG_SS_ACTIVE_SHIFT) 2863 #define ARM_TBFLAG_PSTATE_SS(F) \ 2864 (((F) & ARM_TBFLAG_PSTATE_SS_MASK) >> ARM_TBFLAG_PSTATE_SS_SHIFT) 2865 #define ARM_TBFLAG_FPEXC_EL(F) \ 2866 (((F) & ARM_TBFLAG_FPEXC_EL_MASK) >> ARM_TBFLAG_FPEXC_EL_SHIFT) 2867 #define ARM_TBFLAG_THUMB(F) \ 2868 (((F) & ARM_TBFLAG_THUMB_MASK) >> ARM_TBFLAG_THUMB_SHIFT) 2869 #define ARM_TBFLAG_VECLEN(F) \ 2870 (((F) & ARM_TBFLAG_VECLEN_MASK) >> ARM_TBFLAG_VECLEN_SHIFT) 2871 #define ARM_TBFLAG_VECSTRIDE(F) \ 2872 (((F) & ARM_TBFLAG_VECSTRIDE_MASK) >> ARM_TBFLAG_VECSTRIDE_SHIFT) 2873 #define ARM_TBFLAG_VFPEN(F) \ 2874 (((F) & ARM_TBFLAG_VFPEN_MASK) >> ARM_TBFLAG_VFPEN_SHIFT) 2875 #define ARM_TBFLAG_CONDEXEC(F) \ 2876 (((F) & ARM_TBFLAG_CONDEXEC_MASK) >> ARM_TBFLAG_CONDEXEC_SHIFT) 2877 #define ARM_TBFLAG_SCTLR_B(F) \ 2878 (((F) & ARM_TBFLAG_SCTLR_B_MASK) >> ARM_TBFLAG_SCTLR_B_SHIFT) 2879 #define ARM_TBFLAG_XSCALE_CPAR(F) \ 2880 (((F) & ARM_TBFLAG_XSCALE_CPAR_MASK) >> ARM_TBFLAG_XSCALE_CPAR_SHIFT) 2881 #define ARM_TBFLAG_NS(F) \ 2882 (((F) & ARM_TBFLAG_NS_MASK) >> ARM_TBFLAG_NS_SHIFT) 2883 #define ARM_TBFLAG_BE_DATA(F) \ 2884 (((F) & ARM_TBFLAG_BE_DATA_MASK) >> ARM_TBFLAG_BE_DATA_SHIFT) 2885 #define ARM_TBFLAG_HANDLER(F) \ 2886 (((F) & ARM_TBFLAG_HANDLER_MASK) >> ARM_TBFLAG_HANDLER_SHIFT) 2887 #define ARM_TBFLAG_TBI0(F) \ 2888 (((F) & ARM_TBFLAG_TBI0_MASK) >> ARM_TBFLAG_TBI0_SHIFT) 2889 #define ARM_TBFLAG_TBI1(F) \ 2890 (((F) & ARM_TBFLAG_TBI1_MASK) >> ARM_TBFLAG_TBI1_SHIFT) 2891 #define ARM_TBFLAG_SVEEXC_EL(F) \ 2892 (((F) & ARM_TBFLAG_SVEEXC_EL_MASK) >> ARM_TBFLAG_SVEEXC_EL_SHIFT) 2893 #define ARM_TBFLAG_ZCR_LEN(F) \ 2894 (((F) & ARM_TBFLAG_ZCR_LEN_MASK) >> ARM_TBFLAG_ZCR_LEN_SHIFT) 2895 2896 static inline bool bswap_code(bool sctlr_b) 2897 { 2898 #ifdef CONFIG_USER_ONLY 2899 /* BE8 (SCTLR.B = 0, TARGET_WORDS_BIGENDIAN = 1) is mixed endian. 2900 * The invalid combination SCTLR.B=1/CPSR.E=1/TARGET_WORDS_BIGENDIAN=0 2901 * would also end up as a mixed-endian mode with BE code, LE data. 2902 */ 2903 return 2904 #ifdef TARGET_WORDS_BIGENDIAN 2905 1 ^ 2906 #endif 2907 sctlr_b; 2908 #else 2909 /* All code access in ARM is little endian, and there are no loaders 2910 * doing swaps that need to be reversed 2911 */ 2912 return 0; 2913 #endif 2914 } 2915 2916 #ifdef CONFIG_USER_ONLY 2917 static inline bool arm_cpu_bswap_data(CPUARMState *env) 2918 { 2919 return 2920 #ifdef TARGET_WORDS_BIGENDIAN 2921 1 ^ 2922 #endif 2923 arm_cpu_data_is_big_endian(env); 2924 } 2925 #endif 2926 2927 #ifndef CONFIG_USER_ONLY 2928 /** 2929 * arm_regime_tbi0: 2930 * @env: CPUARMState 2931 * @mmu_idx: MMU index indicating required translation regime 2932 * 2933 * Extracts the TBI0 value from the appropriate TCR for the current EL 2934 * 2935 * Returns: the TBI0 value. 2936 */ 2937 uint32_t arm_regime_tbi0(CPUARMState *env, ARMMMUIdx mmu_idx); 2938 2939 /** 2940 * arm_regime_tbi1: 2941 * @env: CPUARMState 2942 * @mmu_idx: MMU index indicating required translation regime 2943 * 2944 * Extracts the TBI1 value from the appropriate TCR for the current EL 2945 * 2946 * Returns: the TBI1 value. 2947 */ 2948 uint32_t arm_regime_tbi1(CPUARMState *env, ARMMMUIdx mmu_idx); 2949 #else 2950 /* We can't handle tagged addresses properly in user-only mode */ 2951 static inline uint32_t arm_regime_tbi0(CPUARMState *env, ARMMMUIdx mmu_idx) 2952 { 2953 return 0; 2954 } 2955 2956 static inline uint32_t arm_regime_tbi1(CPUARMState *env, ARMMMUIdx mmu_idx) 2957 { 2958 return 0; 2959 } 2960 #endif 2961 2962 void cpu_get_tb_cpu_state(CPUARMState *env, target_ulong *pc, 2963 target_ulong *cs_base, uint32_t *flags); 2964 2965 enum { 2966 QEMU_PSCI_CONDUIT_DISABLED = 0, 2967 QEMU_PSCI_CONDUIT_SMC = 1, 2968 QEMU_PSCI_CONDUIT_HVC = 2, 2969 }; 2970 2971 #ifndef CONFIG_USER_ONLY 2972 /* Return the address space index to use for a memory access */ 2973 static inline int arm_asidx_from_attrs(CPUState *cs, MemTxAttrs attrs) 2974 { 2975 return attrs.secure ? ARMASIdx_S : ARMASIdx_NS; 2976 } 2977 2978 /* Return the AddressSpace to use for a memory access 2979 * (which depends on whether the access is S or NS, and whether 2980 * the board gave us a separate AddressSpace for S accesses). 2981 */ 2982 static inline AddressSpace *arm_addressspace(CPUState *cs, MemTxAttrs attrs) 2983 { 2984 return cpu_get_address_space(cs, arm_asidx_from_attrs(cs, attrs)); 2985 } 2986 #endif 2987 2988 /** 2989 * arm_register_pre_el_change_hook: 2990 * Register a hook function which will be called immediately before this 2991 * CPU changes exception level or mode. The hook function will be 2992 * passed a pointer to the ARMCPU and the opaque data pointer passed 2993 * to this function when the hook was registered. 2994 * 2995 * Note that if a pre-change hook is called, any registered post-change hooks 2996 * are guaranteed to subsequently be called. 2997 */ 2998 void arm_register_pre_el_change_hook(ARMCPU *cpu, ARMELChangeHookFn *hook, 2999 void *opaque); 3000 /** 3001 * arm_register_el_change_hook: 3002 * Register a hook function which will be called immediately after this 3003 * CPU changes exception level or mode. The hook function will be 3004 * passed a pointer to the ARMCPU and the opaque data pointer passed 3005 * to this function when the hook was registered. 3006 * 3007 * Note that any registered hooks registered here are guaranteed to be called 3008 * if pre-change hooks have been. 3009 */ 3010 void arm_register_el_change_hook(ARMCPU *cpu, ARMELChangeHookFn *hook, void 3011 *opaque); 3012 3013 /** 3014 * aa32_vfp_dreg: 3015 * Return a pointer to the Dn register within env in 32-bit mode. 3016 */ 3017 static inline uint64_t *aa32_vfp_dreg(CPUARMState *env, unsigned regno) 3018 { 3019 return &env->vfp.zregs[regno >> 1].d[regno & 1]; 3020 } 3021 3022 /** 3023 * aa32_vfp_qreg: 3024 * Return a pointer to the Qn register within env in 32-bit mode. 3025 */ 3026 static inline uint64_t *aa32_vfp_qreg(CPUARMState *env, unsigned regno) 3027 { 3028 return &env->vfp.zregs[regno].d[0]; 3029 } 3030 3031 /** 3032 * aa64_vfp_qreg: 3033 * Return a pointer to the Qn register within env in 64-bit mode. 3034 */ 3035 static inline uint64_t *aa64_vfp_qreg(CPUARMState *env, unsigned regno) 3036 { 3037 return &env->vfp.zregs[regno].d[0]; 3038 } 3039 3040 /* Shared between translate-sve.c and sve_helper.c. */ 3041 extern const uint64_t pred_esz_masks[4]; 3042 3043 #endif 3044