x86/efi: Enforce CONFIG_RELOCATABLE for EFI boot stub
[linux/fpc-iii.git] / arch / metag / kernel / traps.c
blob25f9d1c2ffecd35f93b4517aa0f1baae815a9380
1 /*
2 * Meta exception handling.
4 * Copyright (C) 2005,2006,2007,2008,2009,2012 Imagination Technologies Ltd.
6 * This file is subject to the terms and conditions of the GNU General Public
7 * License. See the file COPYING in the main directory of this archive
8 * for more details.
9 */
11 #include <linux/export.h>
12 #include <linux/sched.h>
13 #include <linux/signal.h>
14 #include <linux/kernel.h>
15 #include <linux/mm.h>
16 #include <linux/types.h>
17 #include <linux/init.h>
18 #include <linux/interrupt.h>
19 #include <linux/preempt.h>
20 #include <linux/ptrace.h>
21 #include <linux/module.h>
22 #include <linux/kallsyms.h>
23 #include <linux/kdebug.h>
24 #include <linux/kexec.h>
25 #include <linux/unistd.h>
26 #include <linux/smp.h>
27 #include <linux/slab.h>
28 #include <linux/syscalls.h>
30 #include <asm/bug.h>
31 #include <asm/core_reg.h>
32 #include <asm/irqflags.h>
33 #include <asm/siginfo.h>
34 #include <asm/traps.h>
35 #include <asm/hwthread.h>
36 #include <asm/setup.h>
37 #include <asm/switch.h>
38 #include <asm/user_gateway.h>
39 #include <asm/syscall.h>
40 #include <asm/syscalls.h>
42 /* Passing syscall arguments as long long is quicker. */
43 typedef unsigned int (*LPSYSCALL) (unsigned long long,
44 unsigned long long,
45 unsigned long long);
48 * Users of LNKSET should compare the bus error bits obtained from DEFR
49 * against TXDEFR_LNKSET_SUCCESS only as the failure code will vary between
50 * different cores revisions.
52 #define TXDEFR_LNKSET_SUCCESS 0x02000000
53 #define TXDEFR_LNKSET_FAILURE 0x04000000
56 * Our global TBI handle. Initialised from setup.c/setup_arch.
58 DECLARE_PER_CPU(PTBI, pTBI);
60 #ifdef CONFIG_SMP
61 static DEFINE_PER_CPU(unsigned int, trigger_mask);
62 #else
63 unsigned int global_trigger_mask;
64 EXPORT_SYMBOL(global_trigger_mask);
65 #endif
67 unsigned long per_cpu__stack_save[NR_CPUS];
69 static const char * const trap_names[] = {
70 [TBIXXF_SIGNUM_IIF] = "Illegal instruction fault",
71 [TBIXXF_SIGNUM_PGF] = "Privilege violation",
72 [TBIXXF_SIGNUM_DHF] = "Unaligned data access fault",
73 [TBIXXF_SIGNUM_IGF] = "Code fetch general read failure",
74 [TBIXXF_SIGNUM_DGF] = "Data access general read/write fault",
75 [TBIXXF_SIGNUM_IPF] = "Code fetch page fault",
76 [TBIXXF_SIGNUM_DPF] = "Data access page fault",
77 [TBIXXF_SIGNUM_IHF] = "Instruction breakpoint",
78 [TBIXXF_SIGNUM_DWF] = "Read-only data access fault",
81 const char *trap_name(int trapno)
83 if (trapno >= 0 && trapno < ARRAY_SIZE(trap_names)
84 && trap_names[trapno])
85 return trap_names[trapno];
86 return "Unknown fault";
89 static DEFINE_SPINLOCK(die_lock);
91 void __noreturn die(const char *str, struct pt_regs *regs,
92 long err, unsigned long addr)
94 static int die_counter;
96 oops_enter();
98 spin_lock_irq(&die_lock);
99 console_verbose();
100 bust_spinlocks(1);
101 pr_err("%s: err %04lx (%s) addr %08lx [#%d]\n", str, err & 0xffff,
102 trap_name(err & 0xffff), addr, ++die_counter);
104 print_modules();
105 show_regs(regs);
107 pr_err("Process: %s (pid: %d, stack limit = %p)\n", current->comm,
108 task_pid_nr(current), task_stack_page(current) + THREAD_SIZE);
110 bust_spinlocks(0);
111 add_taint(TAINT_DIE, LOCKDEP_NOW_UNRELIABLE);
112 if (kexec_should_crash(current))
113 crash_kexec(regs);
115 if (in_interrupt())
116 panic("Fatal exception in interrupt");
118 if (panic_on_oops)
119 panic("Fatal exception");
121 spin_unlock_irq(&die_lock);
122 oops_exit();
123 do_exit(SIGSEGV);
126 #ifdef CONFIG_METAG_DSP
128 * The ECH encoding specifies the size of a DSPRAM as,
130 * "slots" / 4
132 * A "slot" is the size of two DSPRAM bank entries; an entry from
133 * DSPRAM bank A and an entry from DSPRAM bank B. One DSPRAM bank
134 * entry is 4 bytes.
136 #define SLOT_SZ 8
137 static inline unsigned int decode_dspram_size(unsigned int size)
139 unsigned int _sz = size & 0x7f;
141 return _sz * SLOT_SZ * 4;
144 static void dspram_save(struct meta_ext_context *dsp_ctx,
145 unsigned int ramA_sz, unsigned int ramB_sz)
147 unsigned int ram_sz[2];
148 int i;
150 ram_sz[0] = ramA_sz;
151 ram_sz[1] = ramB_sz;
153 for (i = 0; i < 2; i++) {
154 if (ram_sz[i] != 0) {
155 unsigned int sz;
157 if (i == 0)
158 sz = decode_dspram_size(ram_sz[i] >> 8);
159 else
160 sz = decode_dspram_size(ram_sz[i]);
162 if (dsp_ctx->ram[i] == NULL) {
163 dsp_ctx->ram[i] = kmalloc(sz, GFP_KERNEL);
165 if (dsp_ctx->ram[i] == NULL)
166 panic("couldn't save DSP context");
167 } else {
168 if (ram_sz[i] > dsp_ctx->ram_sz[i]) {
169 kfree(dsp_ctx->ram[i]);
171 dsp_ctx->ram[i] = kmalloc(sz,
172 GFP_KERNEL);
174 if (dsp_ctx->ram[i] == NULL)
175 panic("couldn't save DSP context");
179 if (i == 0)
180 __TBIDspramSaveA(ram_sz[i], dsp_ctx->ram[i]);
181 else
182 __TBIDspramSaveB(ram_sz[i], dsp_ctx->ram[i]);
184 dsp_ctx->ram_sz[i] = ram_sz[i];
188 #endif /* CONFIG_METAG_DSP */
191 * Allow interrupts to be nested and save any "extended" register
192 * context state, e.g. DSP regs and RAMs.
194 static void nest_interrupts(TBIRES State, unsigned long mask)
196 #ifdef CONFIG_METAG_DSP
197 struct meta_ext_context *dsp_ctx;
198 unsigned int D0_8;
201 * D0.8 may contain an ECH encoding. The upper 16 bits
202 * tell us what DSP resources the current process is
203 * using. OR the bits into the SaveMask so that
204 * __TBINestInts() knows what resources to save as
205 * part of this context.
207 * Don't save the context if we're nesting interrupts in the
208 * kernel because the kernel doesn't use DSP hardware.
210 D0_8 = __core_reg_get(D0.8);
212 if (D0_8 && (State.Sig.SaveMask & TBICTX_PRIV_BIT)) {
213 State.Sig.SaveMask |= (D0_8 >> 16);
215 dsp_ctx = current->thread.dsp_context;
216 if (dsp_ctx == NULL) {
217 dsp_ctx = kzalloc(sizeof(*dsp_ctx), GFP_KERNEL);
218 if (dsp_ctx == NULL)
219 panic("couldn't save DSP context: ENOMEM");
221 current->thread.dsp_context = dsp_ctx;
224 current->thread.user_flags |= (D0_8 & 0xffff0000);
225 __TBINestInts(State, &dsp_ctx->regs, mask);
226 dspram_save(dsp_ctx, D0_8 & 0x7f00, D0_8 & 0x007f);
227 } else
228 __TBINestInts(State, NULL, mask);
229 #else
230 __TBINestInts(State, NULL, mask);
231 #endif
234 void head_end(TBIRES State, unsigned long mask)
236 unsigned int savemask = (unsigned short)State.Sig.SaveMask;
237 unsigned int ctx_savemask = (unsigned short)State.Sig.pCtx->SaveMask;
239 if (savemask & TBICTX_PRIV_BIT) {
240 ctx_savemask |= TBICTX_PRIV_BIT;
241 current->thread.user_flags = savemask;
244 /* Always undo the sleep bit */
245 ctx_savemask &= ~TBICTX_WAIT_BIT;
247 /* Always save the catch buffer and RD pipe if they are dirty */
248 savemask |= TBICTX_XCBF_BIT;
250 /* Only save the catch and RD if we have not already done so.
251 * Note - the RD bits are in the pCtx only, and not in the
252 * State.SaveMask.
254 if ((savemask & TBICTX_CBUF_BIT) ||
255 (ctx_savemask & TBICTX_CBRP_BIT)) {
256 /* Have we already saved the buffers though?
257 * - See TestTrack 5071 */
258 if (ctx_savemask & TBICTX_XCBF_BIT) {
259 /* Strip off the bits so the call to __TBINestInts
260 * won't save the buffers again. */
261 savemask &= ~TBICTX_CBUF_BIT;
262 ctx_savemask &= ~TBICTX_CBRP_BIT;
266 #ifdef CONFIG_METAG_META21
268 unsigned int depth, txdefr;
271 * Save TXDEFR state.
273 * The process may have been interrupted after a LNKSET, but
274 * before it could read the DEFR state, so we mustn't lose that
275 * state or it could end up retrying an atomic operation that
276 * succeeded.
278 * All interrupts are disabled at this point so we
279 * don't need to perform any locking. We must do this
280 * dance before we use LNKGET or LNKSET.
282 BUG_ON(current->thread.int_depth > HARDIRQ_BITS);
284 depth = current->thread.int_depth++;
286 txdefr = __core_reg_get(TXDEFR);
288 txdefr &= TXDEFR_BUS_STATE_BITS;
289 if (txdefr & TXDEFR_LNKSET_SUCCESS)
290 current->thread.txdefr_failure &= ~(1 << depth);
291 else
292 current->thread.txdefr_failure |= (1 << depth);
294 #endif
296 State.Sig.SaveMask = savemask;
297 State.Sig.pCtx->SaveMask = ctx_savemask;
299 nest_interrupts(State, mask);
301 #ifdef CONFIG_METAG_POISON_CATCH_BUFFERS
302 /* Poison the catch registers. This shows up any mistakes we have
303 * made in their handling MUCH quicker.
305 __core_reg_set(TXCATCH0, 0x87650021);
306 __core_reg_set(TXCATCH1, 0x87654322);
307 __core_reg_set(TXCATCH2, 0x87654323);
308 __core_reg_set(TXCATCH3, 0x87654324);
309 #endif /* CONFIG_METAG_POISON_CATCH_BUFFERS */
312 TBIRES tail_end_sys(TBIRES State, int syscall, int *restart)
314 struct pt_regs *regs = (struct pt_regs *)State.Sig.pCtx;
315 unsigned long flags;
317 local_irq_disable();
319 if (user_mode(regs)) {
320 flags = current_thread_info()->flags;
321 if (flags & _TIF_WORK_MASK &&
322 do_work_pending(regs, flags, syscall)) {
323 *restart = 1;
324 return State;
327 #ifdef CONFIG_METAG_FPU
328 if (current->thread.fpu_context &&
329 current->thread.fpu_context->needs_restore) {
330 __TBICtxFPURestore(State, current->thread.fpu_context);
332 * Clearing this bit ensures the FP unit is not made
333 * active again unless it is used.
335 State.Sig.SaveMask &= ~TBICTX_FPAC_BIT;
336 current->thread.fpu_context->needs_restore = false;
338 State.Sig.TrigMask |= TBI_TRIG_BIT(TBID_SIGNUM_DFR);
339 #endif
342 /* TBI will turn interrupts back on at some point. */
343 if (!irqs_disabled_flags((unsigned long)State.Sig.TrigMask))
344 trace_hardirqs_on();
346 #ifdef CONFIG_METAG_DSP
348 * If we previously saved an extended context then restore it
349 * now. Otherwise, clear D0.8 because this process is not
350 * using DSP hardware.
352 if (State.Sig.pCtx->SaveMask & TBICTX_XEXT_BIT) {
353 unsigned int D0_8;
354 struct meta_ext_context *dsp_ctx = current->thread.dsp_context;
356 /* Make sure we're going to return to userland. */
357 BUG_ON(current->thread.int_depth != 1);
359 if (dsp_ctx->ram_sz[0] > 0)
360 __TBIDspramRestoreA(dsp_ctx->ram_sz[0],
361 dsp_ctx->ram[0]);
362 if (dsp_ctx->ram_sz[1] > 0)
363 __TBIDspramRestoreB(dsp_ctx->ram_sz[1],
364 dsp_ctx->ram[1]);
366 State.Sig.SaveMask |= State.Sig.pCtx->SaveMask;
367 __TBICtxRestore(State, current->thread.dsp_context);
368 D0_8 = __core_reg_get(D0.8);
369 D0_8 |= current->thread.user_flags & 0xffff0000;
370 D0_8 |= (dsp_ctx->ram_sz[1] | dsp_ctx->ram_sz[0]) & 0xffff;
371 __core_reg_set(D0.8, D0_8);
372 } else
373 __core_reg_set(D0.8, 0);
374 #endif /* CONFIG_METAG_DSP */
376 #ifdef CONFIG_METAG_META21
378 unsigned int depth, txdefr;
381 * If there hasn't been a LNKSET since the last LNKGET then the
382 * link flag will be set, causing the next LNKSET to succeed if
383 * the addresses match. The two LNK operations may not be a pair
384 * (e.g. see atomic_read()), so the LNKSET should fail.
385 * We use a conditional-never LNKSET to clear the link flag
386 * without side effects.
388 asm volatile("LNKSETDNV [D0Re0],D0Re0");
390 depth = --current->thread.int_depth;
392 BUG_ON(user_mode(regs) && depth);
394 txdefr = __core_reg_get(TXDEFR);
396 txdefr &= ~TXDEFR_BUS_STATE_BITS;
398 /* Do we need to restore a failure code into TXDEFR? */
399 if (current->thread.txdefr_failure & (1 << depth))
400 txdefr |= (TXDEFR_LNKSET_FAILURE | TXDEFR_BUS_TRIG_BIT);
401 else
402 txdefr |= (TXDEFR_LNKSET_SUCCESS | TXDEFR_BUS_TRIG_BIT);
404 __core_reg_set(TXDEFR, txdefr);
406 #endif
407 return State;
410 #ifdef CONFIG_SMP
412 * If we took an interrupt in the middle of __kuser_get_tls then we need
413 * to rewind the PC to the start of the function in case the process
414 * gets migrated to another thread (SMP only) and it reads the wrong tls
415 * data.
417 static inline void _restart_critical_section(TBIRES State)
419 unsigned long get_tls_start;
420 unsigned long get_tls_end;
422 get_tls_start = (unsigned long)__kuser_get_tls -
423 (unsigned long)&__user_gateway_start;
425 get_tls_start += USER_GATEWAY_PAGE;
427 get_tls_end = (unsigned long)__kuser_get_tls_end -
428 (unsigned long)&__user_gateway_start;
430 get_tls_end += USER_GATEWAY_PAGE;
432 if ((State.Sig.pCtx->CurrPC >= get_tls_start) &&
433 (State.Sig.pCtx->CurrPC < get_tls_end))
434 State.Sig.pCtx->CurrPC = get_tls_start;
436 #else
438 * If we took an interrupt in the middle of
439 * __kuser_cmpxchg then we need to rewind the PC to the
440 * start of the function.
442 static inline void _restart_critical_section(TBIRES State)
444 unsigned long cmpxchg_start;
445 unsigned long cmpxchg_end;
447 cmpxchg_start = (unsigned long)__kuser_cmpxchg -
448 (unsigned long)&__user_gateway_start;
450 cmpxchg_start += USER_GATEWAY_PAGE;
452 cmpxchg_end = (unsigned long)__kuser_cmpxchg_end -
453 (unsigned long)&__user_gateway_start;
455 cmpxchg_end += USER_GATEWAY_PAGE;
457 if ((State.Sig.pCtx->CurrPC >= cmpxchg_start) &&
458 (State.Sig.pCtx->CurrPC < cmpxchg_end))
459 State.Sig.pCtx->CurrPC = cmpxchg_start;
461 #endif
463 /* Used by kick_handler() */
464 void restart_critical_section(TBIRES State)
466 _restart_critical_section(State);
469 TBIRES trigger_handler(TBIRES State, int SigNum, int Triggers, int Inst,
470 PTBI pTBI)
472 head_end(State, ~INTS_OFF_MASK);
474 /* If we interrupted user code handle any critical sections. */
475 if (State.Sig.SaveMask & TBICTX_PRIV_BIT)
476 _restart_critical_section(State);
478 trace_hardirqs_off();
480 do_IRQ(SigNum, (struct pt_regs *)State.Sig.pCtx);
482 return tail_end(State);
485 static unsigned int load_fault(PTBICTXEXTCB0 pbuf)
487 return pbuf->CBFlags & TXCATCH0_READ_BIT;
490 static unsigned long fault_address(PTBICTXEXTCB0 pbuf)
492 return pbuf->CBAddr;
495 static void unhandled_fault(struct pt_regs *regs, unsigned long addr,
496 int signo, int code, int trapno)
498 if (user_mode(regs)) {
499 siginfo_t info;
501 if (show_unhandled_signals && unhandled_signal(current, signo)
502 && printk_ratelimit()) {
504 pr_info("pid %d unhandled fault: pc 0x%08x, addr 0x%08lx, trap %d (%s)\n",
505 current->pid, regs->ctx.CurrPC, addr,
506 trapno, trap_name(trapno));
507 print_vma_addr(" in ", regs->ctx.CurrPC);
508 print_vma_addr(" rtp in ", regs->ctx.DX[4].U1);
509 printk("\n");
510 show_regs(regs);
513 info.si_signo = signo;
514 info.si_errno = 0;
515 info.si_code = code;
516 info.si_addr = (__force void __user *)addr;
517 info.si_trapno = trapno;
518 force_sig_info(signo, &info, current);
519 } else {
520 die("Oops", regs, trapno, addr);
524 static int handle_data_fault(PTBICTXEXTCB0 pcbuf, struct pt_regs *regs,
525 unsigned int data_address, int trapno)
527 int ret;
529 ret = do_page_fault(regs, data_address, !load_fault(pcbuf), trapno);
531 return ret;
534 static unsigned long get_inst_fault_address(struct pt_regs *regs)
536 return regs->ctx.CurrPC;
539 TBIRES fault_handler(TBIRES State, int SigNum, int Triggers,
540 int Inst, PTBI pTBI)
542 struct pt_regs *regs = (struct pt_regs *)State.Sig.pCtx;
543 PTBICTXEXTCB0 pcbuf = (PTBICTXEXTCB0)&regs->extcb0;
544 unsigned long data_address;
546 head_end(State, ~INTS_OFF_MASK);
548 /* Hardware breakpoint or data watch */
549 if ((SigNum == TBIXXF_SIGNUM_IHF) ||
550 ((SigNum == TBIXXF_SIGNUM_DHF) &&
551 (pcbuf[0].CBFlags & (TXCATCH0_WATCH1_BIT |
552 TXCATCH0_WATCH0_BIT)))) {
553 State = __TBIUnExpXXX(State, SigNum, Triggers, Inst,
554 pTBI);
555 return tail_end(State);
558 local_irq_enable();
560 data_address = fault_address(pcbuf);
562 switch (SigNum) {
563 case TBIXXF_SIGNUM_IGF:
564 /* 1st-level entry invalid (instruction fetch) */
565 case TBIXXF_SIGNUM_IPF: {
566 /* 2nd-level entry invalid (instruction fetch) */
567 unsigned long addr = get_inst_fault_address(regs);
568 do_page_fault(regs, addr, 0, SigNum);
569 break;
572 case TBIXXF_SIGNUM_DGF:
573 /* 1st-level entry invalid (data access) */
574 case TBIXXF_SIGNUM_DPF:
575 /* 2nd-level entry invalid (data access) */
576 case TBIXXF_SIGNUM_DWF:
577 /* Write to read only page */
578 handle_data_fault(pcbuf, regs, data_address, SigNum);
579 break;
581 case TBIXXF_SIGNUM_IIF:
582 /* Illegal instruction */
583 unhandled_fault(regs, regs->ctx.CurrPC, SIGILL, ILL_ILLOPC,
584 SigNum);
585 break;
587 case TBIXXF_SIGNUM_DHF:
588 /* Unaligned access */
589 unhandled_fault(regs, data_address, SIGBUS, BUS_ADRALN,
590 SigNum);
591 break;
592 case TBIXXF_SIGNUM_PGF:
593 /* Privilege violation */
594 unhandled_fault(regs, data_address, SIGSEGV, SEGV_ACCERR,
595 SigNum);
596 break;
597 default:
598 BUG();
599 break;
602 return tail_end(State);
605 static bool switch_is_syscall(unsigned int inst)
607 return inst == __METAG_SW_ENCODING(SYS);
610 static bool switch_is_legacy_syscall(unsigned int inst)
612 return inst == __METAG_SW_ENCODING(SYS_LEGACY);
615 static inline void step_over_switch(struct pt_regs *regs, unsigned int inst)
617 regs->ctx.CurrPC += 4;
620 static inline int test_syscall_work(void)
622 return current_thread_info()->flags & _TIF_WORK_SYSCALL_MASK;
625 TBIRES switch1_handler(TBIRES State, int SigNum, int Triggers,
626 int Inst, PTBI pTBI)
628 struct pt_regs *regs = (struct pt_regs *)State.Sig.pCtx;
629 unsigned int sysnumber;
630 unsigned long long a1_a2, a3_a4, a5_a6;
631 LPSYSCALL syscall_entry;
632 int restart;
634 head_end(State, ~INTS_OFF_MASK);
637 * If this is not a syscall SWITCH it could be a breakpoint.
639 if (!switch_is_syscall(Inst)) {
641 * Alert the user if they're trying to use legacy system
642 * calls. This suggests they need to update their C
643 * library and build against up to date kernel headers.
645 if (switch_is_legacy_syscall(Inst))
646 pr_warn_once("WARNING: A legacy syscall was made. Your userland needs updating.\n");
648 * We don't know how to handle the SWITCH and cannot
649 * safely ignore it, so treat all unknown switches
650 * (including breakpoints) as traps.
652 force_sig(SIGTRAP, current);
653 return tail_end(State);
656 local_irq_enable();
658 restart_syscall:
659 restart = 0;
660 sysnumber = regs->ctx.DX[0].U1;
662 if (test_syscall_work())
663 sysnumber = syscall_trace_enter(regs);
665 /* Skip over the SWITCH instruction - or you just get 'stuck' on it! */
666 step_over_switch(regs, Inst);
668 if (sysnumber >= __NR_syscalls) {
669 pr_debug("unknown syscall number: %d\n", sysnumber);
670 syscall_entry = (LPSYSCALL) sys_ni_syscall;
671 } else {
672 syscall_entry = (LPSYSCALL) sys_call_table[sysnumber];
675 /* Use 64bit loads for speed. */
676 a5_a6 = *(unsigned long long *)&regs->ctx.DX[1];
677 a3_a4 = *(unsigned long long *)&regs->ctx.DX[2];
678 a1_a2 = *(unsigned long long *)&regs->ctx.DX[3];
680 /* here is the actual call to the syscall handler functions */
681 regs->ctx.DX[0].U0 = syscall_entry(a1_a2, a3_a4, a5_a6);
683 if (test_syscall_work())
684 syscall_trace_leave(regs);
686 State = tail_end_sys(State, sysnumber, &restart);
687 /* Handlerless restarts shouldn't go via userland */
688 if (restart)
689 goto restart_syscall;
690 return State;
693 TBIRES switchx_handler(TBIRES State, int SigNum, int Triggers,
694 int Inst, PTBI pTBI)
696 struct pt_regs *regs = (struct pt_regs *)State.Sig.pCtx;
699 * This can be caused by any user process simply executing an unusual
700 * SWITCH instruction. If there's no DA, __TBIUnExpXXX will cause the
701 * thread to stop, so signal a SIGTRAP instead.
703 head_end(State, ~INTS_OFF_MASK);
704 if (user_mode(regs))
705 force_sig(SIGTRAP, current);
706 else
707 State = __TBIUnExpXXX(State, SigNum, Triggers, Inst, pTBI);
708 return tail_end(State);
711 #ifdef CONFIG_METAG_META21
712 TBIRES fpe_handler(TBIRES State, int SigNum, int Triggers, int Inst, PTBI pTBI)
714 struct pt_regs *regs = (struct pt_regs *)State.Sig.pCtx;
715 unsigned int error_state = Triggers;
716 siginfo_t info;
718 head_end(State, ~INTS_OFF_MASK);
720 local_irq_enable();
722 info.si_signo = SIGFPE;
724 if (error_state & TXSTAT_FPE_INVALID_BIT)
725 info.si_code = FPE_FLTINV;
726 else if (error_state & TXSTAT_FPE_DIVBYZERO_BIT)
727 info.si_code = FPE_FLTDIV;
728 else if (error_state & TXSTAT_FPE_OVERFLOW_BIT)
729 info.si_code = FPE_FLTOVF;
730 else if (error_state & TXSTAT_FPE_UNDERFLOW_BIT)
731 info.si_code = FPE_FLTUND;
732 else if (error_state & TXSTAT_FPE_INEXACT_BIT)
733 info.si_code = FPE_FLTRES;
734 else
735 info.si_code = 0;
736 info.si_errno = 0;
737 info.si_addr = (__force void __user *)regs->ctx.CurrPC;
738 force_sig_info(SIGFPE, &info, current);
740 return tail_end(State);
742 #endif
744 #ifdef CONFIG_METAG_SUSPEND_MEM
745 struct traps_context {
746 PTBIAPIFN fnSigs[TBID_SIGNUM_MAX + 1];
749 static struct traps_context *metag_traps_context;
751 int traps_save_context(void)
753 unsigned long cpu = smp_processor_id();
754 PTBI _pTBI = per_cpu(pTBI, cpu);
755 struct traps_context *context;
757 context = kzalloc(sizeof(*context), GFP_ATOMIC);
758 if (!context)
759 return -ENOMEM;
761 memcpy(context->fnSigs, (void *)_pTBI->fnSigs, sizeof(context->fnSigs));
763 metag_traps_context = context;
764 return 0;
767 int traps_restore_context(void)
769 unsigned long cpu = smp_processor_id();
770 PTBI _pTBI = per_cpu(pTBI, cpu);
771 struct traps_context *context = metag_traps_context;
773 metag_traps_context = NULL;
775 memcpy((void *)_pTBI->fnSigs, context->fnSigs, sizeof(context->fnSigs));
777 kfree(context);
778 return 0;
780 #endif
782 #ifdef CONFIG_SMP
783 static inline unsigned int _get_trigger_mask(void)
785 unsigned long cpu = smp_processor_id();
786 return per_cpu(trigger_mask, cpu);
789 unsigned int get_trigger_mask(void)
791 return _get_trigger_mask();
793 EXPORT_SYMBOL(get_trigger_mask);
795 static void set_trigger_mask(unsigned int mask)
797 unsigned long cpu = smp_processor_id();
798 per_cpu(trigger_mask, cpu) = mask;
801 void arch_local_irq_enable(void)
803 preempt_disable();
804 arch_local_irq_restore(_get_trigger_mask());
805 preempt_enable_no_resched();
807 EXPORT_SYMBOL(arch_local_irq_enable);
808 #else
809 static void set_trigger_mask(unsigned int mask)
811 global_trigger_mask = mask;
813 #endif
815 void per_cpu_trap_init(unsigned long cpu)
817 TBIRES int_context;
818 unsigned int thread = cpu_2_hwthread_id[cpu];
820 set_trigger_mask(TBI_INTS_INIT(thread) | /* interrupts */
821 TBI_TRIG_BIT(TBID_SIGNUM_LWK) | /* low level kick */
822 TBI_TRIG_BIT(TBID_SIGNUM_SW1) |
823 TBI_TRIG_BIT(TBID_SIGNUM_SWS));
825 /* non-priv - use current stack */
826 int_context.Sig.pCtx = NULL;
827 /* Start with interrupts off */
828 int_context.Sig.TrigMask = INTS_OFF_MASK;
829 int_context.Sig.SaveMask = 0;
831 /* And call __TBIASyncTrigger() */
832 __TBIASyncTrigger(int_context);
835 void __init trap_init(void)
837 unsigned long cpu = smp_processor_id();
838 PTBI _pTBI = per_cpu(pTBI, cpu);
840 _pTBI->fnSigs[TBID_SIGNUM_XXF] = fault_handler;
841 _pTBI->fnSigs[TBID_SIGNUM_SW0] = switchx_handler;
842 _pTBI->fnSigs[TBID_SIGNUM_SW1] = switch1_handler;
843 _pTBI->fnSigs[TBID_SIGNUM_SW2] = switchx_handler;
844 _pTBI->fnSigs[TBID_SIGNUM_SW3] = switchx_handler;
845 _pTBI->fnSigs[TBID_SIGNUM_SWK] = kick_handler;
847 #ifdef CONFIG_METAG_META21
848 _pTBI->fnSigs[TBID_SIGNUM_DFR] = __TBIHandleDFR;
849 _pTBI->fnSigs[TBID_SIGNUM_FPE] = fpe_handler;
850 #endif
852 per_cpu_trap_init(cpu);
855 void tbi_startup_interrupt(int irq)
857 unsigned long cpu = smp_processor_id();
858 PTBI _pTBI = per_cpu(pTBI, cpu);
860 BUG_ON(irq > TBID_SIGNUM_MAX);
862 /* For TR1 and TR2, the thread id is encoded in the irq number */
863 if (irq >= TBID_SIGNUM_T10 && irq < TBID_SIGNUM_TR3)
864 cpu = hwthread_id_2_cpu[(irq - TBID_SIGNUM_T10) % 4];
866 set_trigger_mask(get_trigger_mask() | TBI_TRIG_BIT(irq));
868 _pTBI->fnSigs[irq] = trigger_handler;
871 void tbi_shutdown_interrupt(int irq)
873 unsigned long cpu = smp_processor_id();
874 PTBI _pTBI = per_cpu(pTBI, cpu);
876 BUG_ON(irq > TBID_SIGNUM_MAX);
878 set_trigger_mask(get_trigger_mask() & ~TBI_TRIG_BIT(irq));
880 _pTBI->fnSigs[irq] = __TBIUnExpXXX;
883 int ret_from_fork(TBIRES arg)
885 struct task_struct *prev = arg.Switch.pPara;
886 struct task_struct *tsk = current;
887 struct pt_regs *regs = task_pt_regs(tsk);
888 int (*fn)(void *);
889 TBIRES Next;
891 schedule_tail(prev);
893 if (tsk->flags & PF_KTHREAD) {
894 fn = (void *)regs->ctx.DX[4].U1;
895 BUG_ON(!fn);
897 fn((void *)regs->ctx.DX[3].U1);
900 if (test_syscall_work())
901 syscall_trace_leave(regs);
903 preempt_disable();
905 Next.Sig.TrigMask = get_trigger_mask();
906 Next.Sig.SaveMask = 0;
907 Next.Sig.pCtx = &regs->ctx;
909 set_gateway_tls(current->thread.tls_ptr);
911 preempt_enable_no_resched();
913 /* And interrupts should come back on when we resume the real usermode
914 * code. Call __TBIASyncResume()
916 __TBIASyncResume(tail_end(Next));
917 /* ASyncResume should NEVER return */
918 BUG();
919 return 0;
922 void show_trace(struct task_struct *tsk, unsigned long *sp,
923 struct pt_regs *regs)
925 unsigned long addr;
926 #ifdef CONFIG_FRAME_POINTER
927 unsigned long fp, fpnew;
928 unsigned long stack;
929 #endif
931 if (regs && user_mode(regs))
932 return;
934 printk("\nCall trace: ");
935 #ifdef CONFIG_KALLSYMS
936 printk("\n");
937 #endif
939 if (!tsk)
940 tsk = current;
942 #ifdef CONFIG_FRAME_POINTER
943 if (regs) {
944 print_ip_sym(regs->ctx.CurrPC);
945 fp = regs->ctx.AX[1].U0;
946 } else {
947 fp = __core_reg_get(A0FrP);
950 /* detect when the frame pointer has been used for other purposes and
951 * doesn't point to the stack (it may point completely elsewhere which
952 * kstack_end may not detect).
954 stack = (unsigned long)task_stack_page(tsk);
955 while (fp >= stack && fp + 8 <= stack + THREAD_SIZE) {
956 addr = __raw_readl((unsigned long *)(fp + 4)) - 4;
957 if (kernel_text_address(addr))
958 print_ip_sym(addr);
959 else
960 break;
961 /* stack grows up, so frame pointers must decrease */
962 fpnew = __raw_readl((unsigned long *)(fp + 0));
963 if (fpnew >= fp)
964 break;
965 fp = fpnew;
967 #else
968 while (!kstack_end(sp)) {
969 addr = (*sp--) - 4;
970 if (kernel_text_address(addr))
971 print_ip_sym(addr);
973 #endif
975 printk("\n");
977 debug_show_held_locks(tsk);
980 void show_stack(struct task_struct *tsk, unsigned long *sp)
982 if (!tsk)
983 tsk = current;
984 if (tsk == current)
985 sp = (unsigned long *)current_stack_pointer;
986 else
987 sp = (unsigned long *)tsk->thread.kernel_context->AX[0].U0;
989 show_trace(tsk, sp, NULL);