| blob | 2c9922dc292a6b52c25ae5eaaa3c7f76a1b449e3 |
1 /*
2 * ARM generic helpers.
3 *
4 * This code is licensed under the GNU GPL v2 or later.
5 *
6 * SPDX-License-Identifier: GPL-2.0-or-later
7 */
31 #ifdef CONFIG_TCG
35 #endif
39 {
40 /* Only APSR is actually writable */
46 }
49 }
51 }
52 }
55 {
60 }
65 }
66 }
67 /* EPSR reads as zero */
69 }
72 {
76 /* SFPA is RAZ/WI from NS; FPCA is stored in the M_REG_S bank */
78 }
80 }
82 #ifdef CONFIG_USER_ONLY
85 {
94 /* There are no sub-fields that are actually writable from EL0. */
97 /* Unprivileged writes to other registers are ignored */
99 }
100 }
103 {
110 /* Unprivileged reads others as zero. */
112 }
113 }
116 {
117 /* translate.c should never generate calls here in user-only mode */
119 }
122 {
123 /* translate.c should never generate calls here in user-only mode */
125 }
128 {
129 /* translate.c should never generate calls here in user-only mode */
131 }
134 {
135 /* translate.c should never generate calls here in user-only mode */
137 }
140 {
141 /* translate.c should never generate calls here in user-only mode */
143 }
146 {
147 /*
148 * The TT instructions can be used by unprivileged code, but in
149 * user-only emulation we don't have the MPU.
150 * Luckily since we know we are NonSecure unprivileged (and that in
151 * turn means that the A flag wasn't specified), all the bits in the
152 * register must be zero:
153 * IREGION: 0 because IRVALID is 0
154 * IRVALID: 0 because NS
155 * S: 0 because NS
156 * NSRW: 0 because NS
157 * NSR: 0 because NS
158 * RW: 0 because unpriv and A flag not set
159 * R: 0 because unpriv and A flag not set
160 * SRVALID: 0 because NS
161 * MRVALID: 0 because unpriv and A flag not set
162 * SREGION: 0 becaus SRVALID is 0
163 * MREGION: 0 because MRVALID is 0
164 */
166 }
168 #else
170 /*
171 * What kind of stack write are we doing? This affects how exceptions
172 * generated during the stacking are treated.
173 */
175 STACK_NORMAL,
176 STACK_IGNFAULTS,
177 STACK_LAZYFP,
182 {
185 MemTxAttrs attrs = {};
186 MemTxResult txres;
187 target_ulong page_size;
188 hwaddr physaddr;
190 ARMMMUFaultInfo fi = {};
191 ARMCacheAttrs cacheattrs = {};
198 /* MPU/SAU lookup failed */
202 "...SecureFault with SFSR.LSPERR "
207 "...SecureFault with SFSR.AUVIOL "
210 }
224 }
227 }
229 }
233 /* BusFault trying to write the data */
240 }
244 }
247 pend_fault:
248 /*
249 * By pending the exception at this point we are making
250 * the IMPDEF choice "overridden exceptions pended" (see the
251 * MergeExcInfo() pseudocode). The other choice would be to not
252 * pend them now and then make a choice about which to throw away
253 * later if we have two derived exceptions.
254 * The only case when we must not pend the exception but instead
255 * throw it away is if we are doing the push of the callee registers
256 * and we've already generated a derived exception (this is indicated
257 * by the caller passing STACK_IGNFAULTS). Even in this case we will
258 * still update the fault status registers.
259 */
269 }
271 }
274 ARMMMUIdx mmu_idx)
275 {
278 MemTxAttrs attrs = {};
279 MemTxResult txres;
280 target_ulong page_size;
281 hwaddr physaddr;
283 ARMMMUFaultInfo fi = {};
284 ARMCacheAttrs cacheattrs = {};
292 /* MPU/SAU lookup failed */
306 }
308 }
313 /* BusFault trying to read the data */
319 }
324 pend_fault:
325 /*
326 * By pending the exception at this point we are making
327 * the IMPDEF choice "overridden exceptions pended" (see the
328 * MergeExcInfo() pseudocode). The other choice would be to not
329 * pend them now and then make a choice about which to throw away
330 * later if we have two derived exceptions.
331 */
334 }
337 {
338 /*
339 * Preserve FP state (because LSPACT was set and we are about
340 * to execute an FP instruction). This corresponds to the
341 * PreserveFPState() pseudocode.
342 * We may throw an exception if the stacking fails.
343 */
354 /* Take the iothread lock as we are going to touch the NVIC */
357 /* Check the background context had access to the FPU */
366 }
369 /* We only stack if the stack limit wasn't violated */
371 ARMMMUIdx mmu_idx;
382 }
386 }
395 }
396 }
398 /*
399 * We definitely pended an exception, but it's possible that it
400 * might not be able to be taken now. If its priority permits us
401 * to take it now, then we must not update the LSPACT or FP regs,
402 * but instead jump out to take the exception immediately.
403 * If it's just pending and won't be taken until the current
404 * handler exits, then we do update LSPACT and the FP regs.
405 */
413 }
418 /* Clear s0 to s31 and the FPSCR and VPR */
423 }
427 }
428 }
429 /*
430 * Otherwise s0 to s15, FPSCR and VPR are UNKNOWN; we choose to leave them
431 * unchanged.
432 */
433 }
435 /*
436 * Write to v7M CONTROL.SPSEL bit for the specified security bank.
437 * This may change the current stack pointer between Main and Process
438 * stack pointers if it is done for the CONTROL register for the current
439 * security state.
440 */
444 {
449 R_V7M_CONTROL_SPSEL_SHIFT,
460 }
461 }
462 }
464 /*
465 * Write to v7M CONTROL.SPSEL bit. This may change the current
466 * stack pointer between Main and Process stack pointers.
467 */
469 {
471 }
474 {
475 /*
476 * Write a new value to v7m.exception, thus transitioning into or out
477 * of Handler mode; this may result in a change of active stack pointer.
478 */
490 }
491 }
493 /* Switch M profile security state between NS and S */
495 {
500 }
502 /*
503 * All the banked state is accessed by looking at env->v7m.secure
504 * except for the stack pointer; rearrange the SP appropriately.
505 */
515 }
525 }
526 }
529 {
530 /*
531 * Handle v7M BXNS:
532 * - if the return value is a magic value, do exception return (like BX)
533 * - otherwise bit 0 of the return value is the target security state
534 */
538 /* Covers FNC_RETURN and EXC_RETURN magic */
541 /* EXC_RETURN magic only */
543 }
546 /*
547 * This is an exception return magic value; put it where
548 * do_v7m_exception_exit() expects and raise EXCEPTION_EXIT.
549 * Note that if we ever add gen_ss_advance() singlestep support to
550 * M profile this should count as an "instruction execution complete"
551 * event (compare gen_bx_excret_final_code()).
552 */
556 /* notreached */
557 }
559 /* translate.c should have made BXNS UNDEF unless we're secure */
564 }
569 }
572 {
573 /*
574 * Handle v7M BLXNS:
575 * - bit 0 of the destination address is the target security state
576 */
578 /* At this point regs[15] is the address just after the BLXNS */
583 /* translate.c will have made BLXNS UNDEF unless we're secure */
587 /*
588 * Target is Secure, so this is just a normal BLX,
589 * except that the low bit doesn't indicate Thumb/not.
590 */
595 }
597 /* Target is non-secure: first push a stack frame */
601 }
605 }
610 }
612 /* Note that these stores can throw exceptions on MPU faults */
619 /*
620 * Write a dummy value to IPSR, to avoid leaking the current secure
621 * exception number to non-secure code. This is guaranteed not
622 * to cause write_v7m_exception() to actually change stacks.
623 */
625 }
631 }
635 {
636 /*
637 * Return a pointer to the location where we currently store the
638 * stack pointer for the requested security state and thread mode.
639 * This pointer will become invalid if the CPU state is updated
640 * such that the stack pointers are switched around (eg changing
641 * the SPSEL control bit).
642 * Compare the v8M ARM ARM pseudocode LookUpSP_with_security_mode().
643 * Unlike that pseudocode, we require the caller to pass us in the
644 * SPSEL control bit value; this is because we also use this
645 * function in handling of pushing of the callee-saves registers
646 * part of the v8M stack frame (pseudocode PushCalleeStack()),
647 * and in the tailchain codepath the SPSEL bit comes from the exception
648 * return magic LR value from the previous exception. The pseudocode
649 * opencodes the stack-selection in PushCalleeStack(), but we prefer
650 * to make this utility function generic enough to do the job.
651 */
659 }
665 }
666 }
667 }
671 {
674 MemTxResult result;
677 MemTxAttrs attrs = {};
678 ARMMMUIdx mmu_idx;
683 /*
684 * We don't do a get_phys_addr() here because the rules for vector
685 * loads are special: they always use the default memory map, and
686 * the default memory map permits reads from all addresses.
687 * Since there's no easy way to pass through to pmsav8_mpu_lookup()
688 * that we want this special case which would always say "yes",
689 * we just do the SAU lookup here followed by a direct physical load.
690 */
695 V8M_SAttributes sattrs = {};
701 /*
702 * NS access to S memory: the underlying exception which we escalate
703 * to HardFault is SecureFault, which always targets Secure.
704 */
707 }
708 }
713 /*
714 * Underlying exception is BusFault: its target security state
715 * depends on BFHFNMINS.
716 */
719 }
723 load_fail:
724 /*
725 * All vector table fetch fails are reported as HardFault, with
726 * HFSR.VECTTBL and .FORCED set. (FORCED is set because
727 * technically the underlying exception is a SecureFault or BusFault
728 * that is escalated to HardFault.) This is a terminal exception,
729 * so we will either take the HardFault immediately or else enter
730 * lockup (the latter case is handled in armv7m_nvic_set_pending_derived()).
731 * The HardFault is Secure if BFHFNMINS is 0 (meaning that all HFs are
732 * secure); otherwise it targets the same security state as the
733 * underlying exception.
734 * In v8.1M HardFaults from vector table fetch fails don't set FORCED.
735 */
738 }
742 }
745 }
748 {
749 /*
750 * Return the integrity signature value for the callee-saves
751 * stack frame section. @lr is the exception return payload/LR value
752 * whose FType bit forms bit 0 of the signature if FP is present.
753 */
759 }
761 }
765 {
766 /*
767 * For v8M, push the callee-saves register part of the stack frame.
768 * Compare the v8M pseudocode PushCalleeStack().
769 * In the tailchaining case this may not be the current stack.
770 */
774 ARMMMUIdx mmu_idx;
794 }
799 }
803 /*
804 * Stack limit failure: set SP to the limit value, and generate
805 * STKOF UsageFault. Stack pushes below the limit must not be
806 * performed. It is IMPDEF whether pushes above the limit are
807 * performed; we choose not to.
808 */
816 }
818 /*
819 * Write as much of the stack frame as we can. A write failure may
820 * cause us to pend a derived exception.
821 */
823 stacked_ok =
834 /* Update SP regardless of whether any of the stack accesses failed. */
838 }
842 {
843 /*
844 * Do the "take the exception" parts of exception entry,
845 * but not the pushing of state to the stack. This is
846 * similar to the pseudocode ExceptionTaken() function.
847 */
859 /* Sanitize LR FType and PREFIX bits */
862 }
864 }
869 /*
870 * The background code (the owner of the registers in the
871 * exception frame) is Secure. This means it may either already
872 * have or now needs to push callee-saves registers.
873 */
876 /*
877 * We took an exception from Secure to NonSecure
878 * (which means the callee-saved registers got stacked)
879 * and are now tailchaining to a Secure exception.
880 * Clear DCRS so eventual return from this Secure
881 * exception unstacks the callee-saved registers.
882 */
884 }
886 /*
887 * We're going to a non-secure exception; push the
888 * callee-saves registers to the stack now, if they're
889 * not already saved.
890 */
894 ignore_stackfaults);
895 }
897 }
898 }
903 }
907 }
909 /*
910 * Clear registers if necessary to prevent non-secure exception
911 * code being able to see register values from secure code.
912 * Where register values become architecturally UNKNOWN we leave
913 * them with their previous values. v8.1M is tighter than v8.0M
914 * here and always zeroes the caller-saved registers regardless
915 * of the security state the exception is targeting.
916 */
919 /*
920 * Always clear the caller-saved registers (they have been
921 * pushed to the stack earlier in v7m_push_stack()).
922 * Clear callee-saved registers if the background code is
923 * Secure (in which case these regs were saved in
924 * v7m_push_callee_stack()).
925 */
927 /*
928 * r4..r11 are callee-saves, zero only if background
929 * state was Secure (EXCRET.S == 1) and exception
930 * targets Non-secure state
931 */
938 }
939 }
940 /* Clear EAPSR */
942 }
943 }
944 }
947 /*
948 * Derived exception on callee-saves register stacking:
949 * we might now want to take a different exception which
950 * targets a different security state, so try again from the top.
951 */
956 }
959 /* Vector load failed: derived exception */
963 }
965 /*
966 * Now we've done everything that might cause a derived exception
967 * we can go ahead and activate whichever exception we're going to
968 * take (which might now be the derived exception).
969 */
972 /* Switch to target security state -- must do this before writing SPSEL */
976 /* Clear SFPA and FPCA (has no effect if no FPU) */
979 /* Clear IT bits */
985 }
989 {
990 /*
991 * Like the pseudocode UpdateFPCCR: save state in FPCAR and FPCCR
992 * that we will need later in order to do lazy FP reg stacking.
993 */
996 /*
997 * Some bits are unbanked and live always in fpccr[M_REG_S]; some bits
998 * are banked and we want to update the bit in the bank for the
999 * current security state; and in one case we want to specifically
1000 * update the NS banked version of a bit even if we are secure.
1001 */
1017 }
1049 }
1050 }
1053 {
1054 /* fptr is the value of Rn, the frame pointer we store the FP regs to */
1064 }
1066 /* Check access to the coprocessor is permitted */
1069 }
1072 /* LSPACT should not be active when there is active FP state */
1074 }
1078 }
1080 /*
1081 * Note that we do not use v7m_stack_write() here, because the
1082 * accesses should not set the FSR bits for stacking errors if they
1083 * fail. (In pseudocode terms, they are AccType_NORMAL, not AccType_STACK
1084 * or AccType_LAZYFP). Faults in cpu_stl_data_ra() will throw exceptions
1085 * and longjmp out.
1086 */
1099 }
1102 }
1106 }
1108 /*
1109 * If TS is 0 then s0 to s15, FPSCR and VPR are UNKNOWN; we choose to
1110 * leave them unchanged, matching our choice in v7m_preserve_fp_state.
1111 */
1115 }
1119 }
1120 }
1123 }
1126 }
1129 {
1133 /* fptr is the value of Rn, the frame pointer we load the FP regs from */
1138 }
1140 /* Check access to the coprocessor is permitted */
1143 }
1146 /* State in FP is still valid */
1155 }
1164 }
1171 }
1176 }
1177 }
1180 }
1183 {
1184 /*
1185 * Do the "set up stack frame" part of exception entry,
1186 * similar to pseudocode PushStack().
1187 * Return true if we generate a derived exception (and so
1188 * should ignore further stack faults trying to process
1189 * that derived exception.)
1190 */
1206 }
1209 }
1211 /* Align stack pointer if the guest wants that */
1216 }
1222 }
1230 /*
1231 * Stack limit failure: set SP to the limit value, and generate
1232 * STKOF UsageFault. Stack pushes below the limit must not be
1233 * performed. It is IMPDEF whether pushes above the limit are
1234 * performed; we choose not to.
1235 */
1242 /*
1243 * We won't try to perform any further memory accesses but
1244 * we must continue through the following code to check for
1245 * permission faults during FPU state preservation, and we
1246 * must update FPCCR if lazy stacking is enabled.
1247 */
1250 }
1251 }
1253 /*
1254 * Write as much of the stack frame as we can. If we fail a stack
1255 * write this will result in a derived exception being pended
1256 * (which may be taken in preference to the one we started with
1257 * if it has higher priority).
1258 */
1276 /* FPU is active, try to save its registers */
1287 "...Secure UsageFault with CFSR.NOCP because "
1293 /* Lazy stacking disabled, save registers now */
1299 /*
1300 * Take UsageFault if CPACR forbids access. The pseudocode
1301 * here does a full CheckCPEnabled() but we know the NSACR
1302 * check can never fail as we have already handled that.
1303 */
1305 "...UsageFault with CFSR.NOCP because "
1311 }
1321 }
1327 }
1335 }
1339 }
1343 }
1344 }
1346 /* Lazy stacking enabled, save necessary info to stack later */
1348 }
1349 }
1350 }
1352 /*
1353 * If we broke a stack limit then SP was already updated earlier;
1354 * otherwise we update SP regardless of whether any of the stack
1355 * accesses failed or we took some other kind of fault.
1356 */
1359 }
1362 }
1365 {
1379 /*
1380 * If we're not in Handler mode then jumps to magic exception-exit
1381 * addresses don't have magic behaviour. However for the v8M
1382 * security extensions the magic secure-function-return has to
1383 * work in thread mode too, so to avoid doing an extra check in
1384 * the generated code we allow exception-exit magic to also cause the
1385 * internal exception and bring us here in thread mode. Correct code
1386 * will never try to do this (the following insn fetch will always
1387 * fault) so we the overhead of having taken an unnecessary exception
1388 * doesn't matter.
1389 */
1392 }
1394 /*
1395 * In the spec pseudocode ExceptionReturn() is called directly
1396 * from BXWritePC() and gets the full target PC value including
1397 * bit zero. In QEMU's implementation we treat it as a normal
1398 * jump-to-register (which is then caught later on), and so split
1399 * the target value up between env->regs[15] and env->thumb in
1400 * gen_bx(). Reconstitute it.
1401 */
1405 }
1414 excret);
1415 }
1423 excret);
1425 }
1428 /*
1429 * EXC_RETURN.ES validation check (R_SMFL). We must do this before
1430 * we pick which FAULTMASK to clear.
1431 */
1436 /* For all other purposes, treat ES as 0 (R_HXSR) */
1438 }
1440 }
1443 /*
1444 * Auto-clear FAULTMASK on return from other than NMI.
1445 * If the security extension is implemented then this only
1446 * happens if the raw execution priority is >= 0; the
1447 * value of the ES bit in the exception return value indicates
1448 * which security state's faultmask to clear. (v8M ARM ARM R_KBNF.)
1449 */
1453 }
1456 }
1457 }
1460 exc_secure)) {
1462 /* attempt to exit an exception that isn't active */
1466 /* still an irq active now */
1469 /*
1470 * We returned to base exception level, no nesting.
1471 * (In the pseudocode this is written using "NestedActivation != 1"
1472 * where we have 'rettobase == false'.)
1473 */
1478 }
1487 /*
1488 * UNPREDICTABLE if S == 1 or DCRS == 0 or ES == 1 (R_XLCP);
1489 * we choose to take the UsageFault.
1490 */
1495 }
1496 }
1499 }
1501 /* For v7M we only recognize certain combinations of the low bits */
1507 /*
1508 * We only need to check NONBASETHRDENA for v7M, because in
1509 * v8M this bit does not exist (it is RES1).
1510 */
1513 R_V7M_CCR_NONBASETHRDENA_MASK)) {
1515 }
1519 }
1520 }
1522 /*
1523 * Set CONTROL.SPSEL from excret.SPSEL. Since we're still in
1524 * Handler mode (and will be until we write the new XPSR.Interrupt
1525 * field) this does not switch around the current stack pointer.
1526 * We must do this before we do any kind of tailchaining, including
1527 * for the derived exceptions on integrity check failures, or we will
1528 * give the guest an incorrect EXCRET.SPSEL value on exception entry.
1529 */
1532 /*
1533 * Clear scratch FP values left in caller saved registers; this
1534 * must happen before any kind of tail chaining.
1535 */
1547 /* v8.1M adds this NOCP check */
1560 exc_secure);
1566 }
1567 }
1568 /* Clear s0..s15, FPSCR and VPR */
1573 }
1577 }
1578 }
1579 }
1588 }
1591 /*
1592 * Bad exception return: instead of popping the exception
1593 * stack, directly take a usage fault on the current stack.
1594 */
1601 }
1603 /*
1604 * Tailchaining: if there is currently a pending exception that
1605 * is high enough priority to preempt execution at the level we're
1606 * about to return to, then just directly take that exception now,
1607 * avoiding an unstack-and-then-stack. Note that now we have
1608 * deactivated the previous exception by calling armv7m_nvic_complete_irq()
1609 * our current execution priority is already the execution priority we are
1610 * returning to -- none of the state we would unstack or set based on
1611 * the EXCRET value affects it.
1612 */
1617 }
1621 {
1622 /*
1623 * The stack pointer we should be reading the exception frame from
1624 * depends on bits in the magic exception return type value (and
1625 * for v8M isn't necessarily the stack pointer we will eventually
1626 * end up resuming execution with). Get a pointer to the location
1627 * in the CPU state struct where the SP we need is currently being
1628 * stored; we will use and modify it in place.
1629 * We use this limited C variable scope so we don't accidentally
1630 * use 'frame_sp_p' after we do something that makes it invalid.
1631 */
1634 return_to_secure,
1636 spsel);
1639 ARMMMUIdx mmu_idx;
1644 return_to_priv);
1649 "M profile exception return with non-8-aligned SP "
1651 }
1653 /* Do we need to pop callee-saved registers? */
1662 /* Take a SecureFault on the current stack */
1666 "stackframe: failed exception return integrity "
1670 }
1683 }
1685 /* Pop registers */
1697 /*
1698 * v7m_stack_read() pended a fault, so take it (as a tail
1699 * chained exception on the same stack frame)
1700 */
1704 }
1706 /*
1707 * Returning from an exception with a PC with bit 0 set is defined
1708 * behaviour on v8M (bit 0 is ignored), but for v7M it was specified
1709 * to be UNPREDICTABLE. In practice actual v7M hardware seems to ignore
1710 * the lsbit, and there are several RTOSes out there which incorrectly
1711 * assume the r15 in the stack frame should be a Thumb-style "lsbit
1712 * indicates ARM/Thumb" value, so ignore the bit on v7M as well, but
1713 * complain about the badly behaved guest.
1714 */
1719 "M profile return from interrupt with misaligned "
1721 }
1722 }
1725 /*
1726 * For v8M we have to check whether the xPSR exception field
1727 * matches the EXCRET value for return to handler/thread
1728 * before we commit to changing the SP and xPSR.
1729 */
1732 /*
1733 * Take an INVPC UsageFault on the current stack.
1734 * By this point we will have switched to the security state
1735 * for the background state, so this UsageFault will target
1736 * that state.
1737 */
1742 "stackframe: failed exception return integrity "
1746 }
1747 }
1750 /* FP present and we need to handle it */
1756 "...taking SecureFault on existing stackframe: "
1757 "Secure LSPACT set but exception return is "
1761 }
1767 /* State in FPU is still valid, just clear LSPACT */
1775 return_to_priv);
1781 return_to_secure);
1784 "...taking UsageFault on existing "
1785 "stackframe: CPACR.CP10 prevents unstacking "
1793 "...taking Secure UsageFault on existing "
1794 "stackframe: NSACR.CP10 prevents unstacking "
1798 }
1807 }
1815 }
1819 }
1824 }
1829 }
1831 /*
1832 * These regs are 0 if security extension present;
1833 * otherwise merely UNKNOWN. We zero always.
1834 */
1837 }
1841 }
1842 }
1843 }
1844 }
1848 /* Commit to consuming the stack frame */
1854 }
1855 }
1856 /*
1857 * Undo stack alignment (the SPREALIGN bit indicates that the original
1858 * pre-exception SP was not 8-aligned and we added a padding word to
1859 * align it, so we undo this by ORing in the bit that increases it
1860 * from the current 8-aligned value to the 8-unaligned value. (Adding 4
1861 * would work too but a logical OR is how the pseudocode specifies it.)
1862 */
1865 }
1867 }
1872 }
1873 /* This xpsr_write() will invalidate frame_sp_p as it may switch stack */
1881 }
1883 /*
1884 * The restored xPSR exception field will be zero if we're
1885 * resuming in Thread mode. If that doesn't match what the
1886 * exception return excret specified then this is a UsageFault.
1887 * v7M requires we make this check here; v8M did it earlier.
1888 */
1890 /*
1891 * Take an INVPC UsageFault by pushing the stack again;
1892 * we know we're v7M so this is never a Secure UsageFault.
1893 */
1904 }
1906 /* Otherwise, we have a successful exception exit. */
1910 }
1913 {
1914 /*
1915 * v8M security extensions magic function return.
1916 * We may either:
1917 * (1) throw an exception (longjump)
1918 * (2) return true if we successfully handled the function return
1919 * (3) return false if we failed a consistency check and have
1920 * pended a UsageFault that needs to be taken now
1921 *
1922 * At this point the magic return value is split between env->regs[15]
1923 * and env->thumb. We don't bother to reconstitute it because we don't
1924 * need it (all values are handled the same way).
1925 */
1931 {
1933 MemOpIdx oi;
1934 ARMMMUIdx mmu_idx;
1938 /* Pull the return address and IPSR from the Secure stack */
1945 /*
1946 * These loads may throw an exception (for MPU faults). We want to
1947 * do them as secure, so work out what MMU index that is.
1948 */
1954 /* Consistency checks on new IPSR */
1958 /* Pend the fault and tell our caller to take it */
1963 "...taking INVPC UsageFault: "
1966 }
1969 }
1971 /* This invalidates frame_sp_p */
1977 }
1985 }
1989 {
1990 /*
1991 * Load a 16-bit portion of a v7M instruction, returning true on success,
1992 * or false on failure (in which case we will have pended the appropriate
1993 * exception).
1994 * We need to do the instruction fetch's MPU and SAU checks
1995 * like this because there is no MMU index that would allow
1996 * doing the load with a single function call. Instead we must
1997 * first check that the security attributes permit the load
1998 * and that they don't mismatch on the two halves of the instruction,
1999 * and then we do the load as a secure load (ie using the security
2000 * attributes of the address, not the CPU, as architecturally required).
2001 */
2004 V8M_SAttributes sattrs = {};
2005 MemTxAttrs attrs = {};
2006 ARMMMUFaultInfo fi = {};
2007 ARMCacheAttrs cacheattrs = {};
2008 MemTxResult txres;
2009 target_ulong page_size;
2010 hwaddr physaddr;
2015 /*
2016 * This must be the second half of the insn, and it straddles a
2017 * region boundary with the second half not being S&NSC.
2018 */
2024 }
2027 /* the MPU lookup failed */
2032 }
2040 }
2042 }
2046 {
2047 /*
2048 * Read a word of data from the stack for the SG instruction,
2049 * writing the value into *spdata. If the load succeeds, return
2050 * true; otherwise pend an appropriate exception and return false.
2051 * (We can't use data load helpers here that throw an exception
2052 * because of the context we're called in, which is halfway through
2053 * arm_v7m_cpu_do_interrupt().)
2054 */
2057 MemTxAttrs attrs = {};
2058 MemTxResult txres;
2059 target_ulong page_size;
2060 hwaddr physaddr;
2062 ARMMMUFaultInfo fi = {};
2063 ARMCacheAttrs cacheattrs = {};
2068 /* MPU/SAU lookup failed */
2079 R_V7M_CFSR_MMARVALID_MASK;
2082 }
2084 }
2088 /* BusFault trying to read the data */
2096 }
2100 }
2103 {
2104 /*
2105 * Check whether this attempt to execute code in a Secure & NS-Callable
2106 * memory region is for an SG instruction; if so, then emulate the
2107 * effect of the SG instruction and return true. Otherwise pend
2108 * the correct kind of exception and return false.
2109 */
2111 ARMMMUIdx mmu_idx;
2114 /*
2115 * We should never get here unless get_phys_addr_pmsav8() caused
2116 * an exception for NS executing in S&NSC memory.
2117 */
2121 /* We want to do the MPU lookup as secure; work out what mmu_idx that is */
2126 }
2130 }
2133 /*
2134 * Not an SG instruction first half (we choose the IMPDEF
2135 * early-SG-check option).
2136 */
2138 }
2142 }
2145 /*
2146 * Not an SG instruction second half (yes, both halves of the SG
2147 * insn have the same hex value)
2148 */
2150 }
2152 /*
2153 * OK, we have confirmed that we really have an SG instruction.
2154 * We know we're NS in S memory so don't need to repeat those checks.
2155 */
2161 /*
2162 * v8.1M exception stack frame integrity check. Note that we
2163 * must perform the memory access even if CCR_S.TRD is zero
2164 * and we aren't going to check what the data loaded is.
2165 */
2168 /*
2169 * We know we are currently NS, so the S stack pointers must be
2170 * in other_ss_{psp,msp}, not in regs[13]/other_sp.
2171 */
2174 /* Stack access failed and an exception has been pended */
2176 }
2182 }
2183 }
2184 }
2194 gen_invep:
2200 }
2203 {
2211 /*
2212 * For exceptions we just mark as pending on the NVIC, and let that
2213 * handle it.
2214 */
2221 {
2222 /*
2223 * NOCP might be directed to something other than the current
2224 * security state if this fault is because of NSACR; we indicate
2225 * the target security state using exception.target_el.
2226 */
2233 }
2237 }
2251 /* Unaligned faults reported by M-profile aware code */
2260 /* The PC already points to the next instruction. */
2265 /*
2266 * Note that for M profile we don't have a guest facing FSR, but
2267 * the env->exception.fsr will be populated by the code that
2268 * raises the fault, in the A profile short-descriptor format.
2269 */
2272 /*
2273 * Exception generated when we try to execute code at an address
2274 * which is marked as Secure & Non-Secure Callable and the CPU
2275 * is in the Non-Secure state. The only instruction which can
2276 * be executed like this is SG (and that only if both halves of
2277 * the SG instruction have the same security attributes.)
2278 * Everything else must generate an INVEP SecureFault, so we
2279 * emulate the SG instruction here.
2280 */
2283 }
2286 /*
2287 * Various flavours of SecureFault for attempts to execute or
2288 * access data in the wrong security state.
2289 */
2300 }
2303 /* This must be an NS access to S memory */
2308 }
2325 }
2336 /*
2337 * All other FSR values are either MPU faults or "can't happen
2338 * for M profile" cases.
2339 */
2353 }
2357 }
2363 #ifdef CONFIG_TCG
2365 #else
2367 #endif
2377 /* Must be v8M security extension function return */
2382 }
2386 }
2389 /*
2390 * We already pended the specific exception in the NVIC in the
2391 * v7m_preserve_fp_state() helper function.
2392 */
2397 }
2401 R_V7M_EXCRET_DCRS_MASK;
2402 /*
2403 * The S bit indicates whether we should return to Secure
2404 * or NonSecure (ie our current state).
2405 * The ES bit indicates whether we're taking this exception
2406 * to Secure or NonSecure (ie our target state). We set it
2407 * later, in v7m_exception_taken().
2408 * The SPSEL bit is also set in v7m_exception_taken() for v8M.
2409 * This corresponds to the ARM ARM pseudocode for v8M setting
2410 * some LR bits in PushStack() and some in ExceptionTaken();
2411 * the distinction matters for the tailchain cases where we
2412 * can take an exception without pushing the stack.
2413 */
2416 }
2419 R_V7M_EXCRET_S_MASK |
2420 R_V7M_EXCRET_DCRS_MASK |
2421 R_V7M_EXCRET_ES_MASK;
2424 }
2425 }
2428 }
2431 }
2435 }
2438 {
2441 /* First handle registers which unprivileged can read */
2448 /*
2449 * We have to handle this here because unprivileged Secure code
2450 * can read the NS CONTROL register.
2451 */
2454 }
2457 }
2461 }
2468 }
2473 }
2478 }
2483 }
2488 }
2493 }
2498 }
2501 {
2502 /*
2503 * This gives the non-secure SP selected based on whether we're
2504 * currently in handler mode or not, using the NS CONTROL.SPSEL.
2505 */
2510 }
2515 }
2516 }
2519 }
2520 }
2530 }
2535 }
2545 bad_reg:
2549 }
2550 }
2553 {
2554 /*
2555 * We're passed bits [11..0] of the instruction; extract
2556 * SYSm and the mask bits.
2557 * Invalid combinations of SYSm and mask are UNPREDICTABLE;
2558 * we choose to treat them as if the mask bits were valid.
2559 * NB that the pseudocode 'mask' variable is bits [11..10],
2560 * whereas ours is [11..8].
2561 */
2567 /*
2568 * only xPSR sub-fields and CONTROL.SFPA may be written by
2569 * unprivileged code
2570 */
2572 }
2579 }
2585 }
2591 }
2597 }
2603 }
2609 }
2615 }
2621 }
2624 M_REG_NS);
2628 }
2629 /*
2630 * SFPA is RAZ/WI from NS. FPCA is RO if NSACR.CP10 == 0,
2631 * RES0 if the FPU is not present, and is stored in the S bank
2632 */
2637 }
2640 {
2641 /*
2642 * This gives the non-secure SP selected based on whether we're
2643 * currently in handler mode or not, using the NS CONTROL.SPSEL.
2644 */
2651 }
2659 }
2665 }
2667 }
2670 }
2671 }
2682 }
2689 }
2694 }
2700 }
2709 }
2715 }
2720 }
2725 }
2729 /*
2730 * Writing to the SPSEL bit only has an effect if we are in
2731 * thread mode; other bits can be updated by any privileged code.
2732 * write_v7m_control_spsel() deals with updating the SPSEL bit in
2733 * env->v7m.control, so we only need update the others.
2734 * For v7M, we must just ignore explicit writes to SPSEL in handler
2735 * mode; for v8M the write is permitted but will have no effect.
2736 * All these bits are writes-ignored from non-privileged code,
2737 * except for SFPA.
2738 */
2742 }
2746 }
2748 /*
2749 * SFPA is RAZ/WI from NS or if no FPU.
2750 * FPCA is RO if NSACR.CP10 == 0, RES0 if the FPU is not present.
2751 * Both are stored in the S bank.
2752 */
2756 }
2762 }
2763 }
2766 bad_reg:
2770 }
2771 }
2774 {
2775 /* Implement the TT instruction. op is bits [7:6] of the insn. */
2778 V8M_SAttributes sattrs = {};
2782 ARMMMUFaultInfo fi = {};
2783 MemTxAttrs attrs = {};
2784 hwaddr phys_addr;
2785 ARMMMUIdx mmu_idx;
2791 /*
2792 * Work out what the security state and privilege level we're
2793 * interested in is...
2794 */
2797 }
2804 }
2806 /* ...and then figure out which MMU index this is */
2809 /*
2810 * We know that the MPU and SAU don't care about the access type
2811 * for our purposes beyond that we don't want to claim to be
2812 * an insn fetch, so we arbitrarily call this a read.
2813 */
2815 /*
2816 * MPU region info only available for privileged or if
2817 * inspecting the other MPU state.
2818 */
2820 /* We can ignore the return value as prot is always set */
2829 }
2837 }
2847 }
2859 mregion;
2862 }
2868 {
2873 }
2877 }
2881 }
2884 }
2888 {
2892 }
2894 /* Return the MMU index for a v7M CPU in the specified security state */
2896 {
2901 }