better debug name for secondary GF dispatch functions
[sbcl.git] / src / runtime / x86-64-darwin-os.c
1 #ifdef LISP_FEATURE_SB_THREAD
2 #include <architecture/i386/table.h>
3 #include <i386/user_ldt.h>
4 #include <mach/mach_init.h>
5 #endif
6
7 #include "thread.h"
8 #include "validate.h"
9 #include "runtime.h"
10 #include "interrupt.h"
11 #include "x86-64-darwin-os.h"
12 #include "genesis/fdefn.h"
13
14 #include <mach/mach.h>
15 #include <mach/mach_error.h>
16 #include <mach/mach_types.h>
17 #include <mach/sync_policy.h>
18 #include <mach/machine/thread_state.h>
19 #include <mach/machine/thread_status.h>
20 #include <sys/_types.h>
21 #include <sys/ucontext.h>
22 #include <pthread.h>
23 #include <assert.h>
24 #include <stdlib.h>
25 #include <stdio.h>
26
27 #if __DARWIN_UNIX03
28 #include <sys/_structs.h>
29 #endif
30
31 #if __DARWIN_UNIX03
32
33 typedef struct __darwin_ucontext darwin_ucontext;
34 typedef struct __darwin_mcontext64 darwin_mcontext;
35
36 #define rip __rip
37 #define rsp __rsp
38 #define rbp __rbp
39 #define rax __rax
40 #define rbx __rbx
41 #define rcx __rcx
42 #define rdx __rdx
43 #define rsi __rsi
44 #define rdi __rdi
45 #define r8 __r8
46 #define r9 __r9
47 #define faultvaddr __faultvaddr
48 #define ss __ss
49 #define es __es
50 #define fs __fs
51
52 #define fpu_fcw __fpu_fcw
53 #define fpu_mxcsr __fpu_mxcsr
54
55 #else
56
57 typedef struct ucontext darwin_ucontext;
58 typedef struct mcontext darwin_mcontext;
59
60 #endif
61
62 #ifdef LISP_FEATURE_SB_THREAD
63 pthread_mutex_t mach_exception_lock = PTHREAD_MUTEX_INITIALIZER;
64 #endif
65
66 #ifdef LISP_FEATURE_MACH_EXCEPTION_HANDLER
67
68 void sigill_handler(int signal, siginfo_t *siginfo, os_context_t *context);
69 void sigtrap_handler(int signal, siginfo_t *siginfo, os_context_t *context);
70 void memory_fault_handler(int signal, siginfo_t *siginfo,
71                           os_context_t *context);
72
73 /* This executes in the faulting thread as part of the signal
74  * emulation.  It is passed a context with the uc_mcontext field
75  * pointing to a valid block of memory. */
76 void build_fake_signal_context(darwin_ucontext *context,
77                                x86_thread_state64_t *thread_state,
78                                x86_float_state64_t *float_state) {
79     pthread_sigmask(0, NULL, &context->uc_sigmask);
80     context->uc_mcontext->ss = *thread_state;
81     context->uc_mcontext->fs = *float_state;
82 }
83
84 /* This executes in the faulting thread as part of the signal
85  * emulation.  It is effectively the inverse operation from above. */
86 void update_thread_state_from_context(x86_thread_state64_t *thread_state,
87                                       x86_float_state64_t *float_state,
88                                       darwin_ucontext  *context) {
89     *thread_state = context->uc_mcontext->ss;
90     *float_state = context->uc_mcontext->fs;
91     pthread_sigmask(SIG_SETMASK, &context->uc_sigmask, NULL);
92 }
93
94 /* Modify a context to push new data on its stack. */
95 void push_context(u64 data, x86_thread_state64_t *context)
96 {
97     u64 *stack_pointer;
98
99     stack_pointer = (u64*) context->rsp;
100     *(--stack_pointer) = data;
101     context->rsp = (u64) stack_pointer;
102 }
103
104 void align_context_stack(x86_thread_state64_t *context)
105 {
106     /* 16byte align the stack (provided that the stack is, as it
107      * should be, 8byte aligned. */
108     while (context->rsp & 15) push_context(0, context);
109 }
110
111 /* Stack allocation starts with a context that has a mod-4 ESP value
112  * and needs to leave a context with a mod-16 ESP that will restore
113  * the old ESP value and other register state when activated.  The
114  * first part of this is the recovery trampoline, which loads ESP from
115  * EBP, pops EBP, and returns. */
116 asm(".globl _stack_allocation_recover; \
117     .align 4; \
118  _stack_allocation_recover: \
119     lea -48(%rbp), %rsp; \
120     pop %rsi; \
121     pop %rdi; \
122     pop %rdx; \
123     pop %rcx; \
124     pop %r8; \
125     pop %r9; \
126     pop %rbp; \
127     ret;");
128
129 void open_stack_allocation(x86_thread_state64_t *context)
130 {
131     void stack_allocation_recover(void);
132
133     push_context(context->rip, context);
134     push_context(context->rbp, context);
135     context->rbp = context->rsp;
136
137     push_context(context->r9, context);
138     push_context(context->r8, context);
139     push_context(context->rcx, context);
140     push_context(context->rdx, context);
141     push_context(context->rsi, context);
142     push_context(context->rdi, context);
143
144     context->rip = (u64) stack_allocation_recover;
145
146     align_context_stack(context);
147 }
148
149 /* Stack allocation of data starts with a context with a mod-16 ESP
150  * value and reserves some space on it by manipulating the ESP
151  * register. */
152 void *stack_allocate(x86_thread_state64_t *context, size_t size)
153 {
154     /* round up size to 16byte multiple */
155     size = (size + 15) & -16;
156
157     context->rsp = ((u64)context->rsp) - size;
158
159     return (void *)context->rsp;
160 }
161
162 /* Arranging to invoke a C function is tricky, as we have to assume
163  * cdecl calling conventions (caller removes args) and x86/darwin
164  * alignment requirements.  The simplest way to arrange this,
165  * actually, is to open a new stack allocation.
166  * WARNING!!! THIS DOES NOT PRESERVE REGISTERS! */
167 void call_c_function_in_context(x86_thread_state64_t *context,
168                                 void *function,
169                                 int nargs,
170                                 ...)
171 {
172     va_list ap;
173     int i;
174     u64 *stack_pointer;
175
176     /* Set up to restore stack on exit. */
177     open_stack_allocation(context);
178
179     /* Have to keep stack 16byte aligned on x86/darwin. */
180     for (i = (1 & -nargs); i; i--) {
181         push_context(0, context);
182     }
183
184     context->rsp = ((u64)context->rsp) - nargs * 8;
185     stack_pointer = (u64 *)context->rsp;
186
187     va_start(ap, nargs);
188     if (nargs > 0) context->rdi = va_arg(ap, u64);
189     if (nargs > 1) context->rsi = va_arg(ap, u64);
190     if (nargs > 2) context->rdx = va_arg(ap, u64);
191     if (nargs > 3) context->rcx = va_arg(ap, u64);
192     if (nargs > 4) context->r8 = va_arg(ap, u64);
193     if (nargs > 5) context->r9 = va_arg(ap, u64);
194     for (i = 6; i < nargs; i++) {
195         stack_pointer[i] = va_arg(ap, u64);
196     }
197     va_end(ap);
198
199     push_context(context->rip, context);
200     context->rip = (u64) function;
201 }
202
203 void signal_emulation_wrapper(x86_thread_state64_t *thread_state,
204                               x86_float_state64_t *float_state,
205                               int signal,
206                               siginfo_t *siginfo,
207                               void (*handler)(int, siginfo_t *, void *))
208 {
209
210     /* CLH: FIXME **NOTE: HACK ALERT!** Ideally, we would allocate
211      * context and regs on the stack as local variables, but this
212      * causes problems for the lisp debugger. When it walks the stack
213      * for a back trace, it sees the 1) address of the local variable
214      * on the stack and thinks that is a frame pointer to a lisp
215      * frame, and, 2) the address of the sap that we alloc'ed in
216      * dynamic space and thinks that is a return address, so it,
217      * heuristicly (and wrongly), chooses that this should be
218      * interpreted as a lisp frame instead of as a C frame.
219      * We can work around this in this case by os_validating the
220      * context (and regs just for symmetry).
221      */
222
223     darwin_ucontext  *context;
224     darwin_mcontext *regs;
225
226     context = (darwin_ucontext *) os_validate(0, sizeof(darwin_ucontext));
227     regs = (darwin_mcontext*) os_validate(0, sizeof(darwin_mcontext));
228     context->uc_mcontext = regs;
229
230     /* when BSD signals are fired, they mask they signals in sa_mask
231        which always seem to be the blockable_sigset, for us, so we
232        need to:
233        1) save the current sigmask
234        2) block blockable signals
235        3) call the signal handler
236        4) restore the sigmask */
237
238     build_fake_signal_context(context, thread_state, float_state);
239
240     block_blockable_signals(0, 0);
241
242     handler(signal, siginfo, context);
243
244     update_thread_state_from_context(thread_state, float_state, context);
245
246     os_invalidate((os_vm_address_t)context, sizeof(darwin_ucontext));
247     os_invalidate((os_vm_address_t)regs, sizeof(darwin_mcontext));
248
249     /* Trap to restore the signal context. */
250     asm volatile (".quad 0xffffffffffff0b0f"
251                   : : "a" (thread_state), "b" (float_state));
252 }
253
254 #if defined DUMP_CONTEXT
255 void dump_context(x86_thread_state64_t *context)
256 {
257     int i;
258     u64 *stack_pointer;
259
260     printf("rax: %08lx  rcx: %08lx  rdx: %08lx  rbx: %08lx\n",
261            context->rax, context->rcx, context->rdx, context->rbx);
262     printf("rsp: %08lx  rbp: %08lx  rsi: %08lx  rdi: %08lx\n",
263            context->rsp, context->rbp, context->rsi, context->rdi);
264     printf("rip: %08lx  eflags: %08lx\n",
265            context->rip, context->rflags);
266     printf("cs: %04hx  ds: %04hx  es: %04hx  "
267            "ss: %04hx  fs: %04hx  gs: %04hx\n",
268            context->cs, context->ds, context->rs,
269            context->ss, context->fs, context->gs);
270
271     stack_pointer = (u64 *)context->rsp;
272     for (i = 0; i < 48; i+=4) {
273         printf("%08x:  %08x %08x %08x %08x\n",
274                context->rsp + (i * 4),
275                stack_pointer[i],
276                stack_pointer[i+1],
277                stack_pointer[i+2],
278                stack_pointer[i+3]);
279     }
280 }
281 #endif
282
283 void
284 control_stack_exhausted_handler(int signal, siginfo_t *siginfo,
285                                 os_context_t *context) {
286     unblock_signals_in_context_and_maybe_warn(context);
287     arrange_return_to_lisp_function
288         (context, StaticSymbolFunction(CONTROL_STACK_EXHAUSTED_ERROR));
289 }
290
291 void
292 undefined_alien_handler(int signal, siginfo_t *siginfo, os_context_t *context) {
293     arrange_return_to_lisp_function
294         (context, StaticSymbolFunction(UNDEFINED_ALIEN_VARIABLE_ERROR));
295 }
296
297 kern_return_t
298 catch_exception_raise(mach_port_t exception_port,
299                       mach_port_t thread,
300                       mach_port_t task,
301                       exception_type_t exception,
302                       exception_data_t code_vector,
303                       mach_msg_type_number_t code_count)
304 {
305     kern_return_t ret, dealloc_ret;
306     int signal;
307     siginfo_t* siginfo;
308
309 #ifdef LISP_FEATURE_SB_THREAD
310     thread_mutex_lock(&mach_exception_lock);
311 #endif
312
313     x86_thread_state64_t thread_state;
314     mach_msg_type_number_t thread_state_count = x86_THREAD_STATE64_COUNT;
315
316     x86_float_state64_t float_state;
317     mach_msg_type_number_t float_state_count = x86_FLOAT_STATE64_COUNT;
318
319     x86_exception_state64_t exception_state;
320     mach_msg_type_number_t exception_state_count = x86_EXCEPTION_STATE64_COUNT;
321
322     x86_thread_state64_t backup_thread_state;
323     x86_thread_state64_t *target_thread_state;
324     x86_float_state64_t *target_float_state;
325
326     os_vm_address_t addr;
327
328     struct thread *th;
329
330     FSHOW((stderr,"/entering catch_exception_raise with exception: %d\n", exception));
331     th = *(struct thread**)exception_port;
332
333     switch (exception) {
334
335     case EXC_BAD_ACCESS:
336         signal = SIGBUS;
337         ret = thread_get_state(thread,
338                                x86_THREAD_STATE64,
339                                (thread_state_t)&thread_state,
340                                &thread_state_count);
341         ret = thread_get_state(thread,
342                                x86_FLOAT_STATE64,
343                                (thread_state_t)&float_state,
344                                &float_state_count);
345         ret = thread_get_state(thread,
346                                x86_EXCEPTION_STATE64,
347                                (thread_state_t)&exception_state,
348                                &exception_state_count);
349         addr = (void*)exception_state.faultvaddr;
350         /* note the os_context hackery here.  When the signal handler returns,
351          * it won't go back to what it was doing ... */
352         if(addr >= CONTROL_STACK_GUARD_PAGE(th) &&
353            addr < CONTROL_STACK_GUARD_PAGE(th) + os_vm_page_size) {
354             /* We hit the end of the control stack: disable guard page
355              * protection so the error handler has some headroom, protect the
356              * previous page so that we can catch returns from the guard page
357              * and restore it. */
358             lower_thread_control_stack_guard_page(th);
359
360             backup_thread_state = thread_state;
361             open_stack_allocation(&thread_state);
362             /* Reserve a 256 byte zone for signal handlers
363              * to use on the interrupted thread stack.
364              */
365             stack_allocate(&thread_state, 256);
366
367             /* Save thread state */
368             target_thread_state =
369                 stack_allocate(&thread_state, sizeof(*target_thread_state));
370             (*target_thread_state) = backup_thread_state;
371
372             /* Save float state */
373             target_float_state =
374                 stack_allocate(&thread_state, sizeof(*target_float_state));
375             (*target_float_state) = float_state;
376
377             /* Set up siginfo */
378             siginfo = stack_allocate(&thread_state, sizeof(*siginfo));
379             /* what do we need to put in our fake siginfo?  It looks like
380              * the x86 code only uses si_signo and si_adrr. */
381             siginfo->si_signo = signal;
382             siginfo->si_addr = (void*)exception_state.faultvaddr;
383
384             call_c_function_in_context(&thread_state,
385                                        signal_emulation_wrapper,
386                                        5,
387                                        target_thread_state,
388                                        target_float_state,
389                                        signal,
390                                        siginfo,
391                                        control_stack_exhausted_handler);
392         }
393         else if(addr >= CONTROL_STACK_RETURN_GUARD_PAGE(th) &&
394                 addr < CONTROL_STACK_RETURN_GUARD_PAGE(th) + os_vm_page_size) {
395             /* We're returning from the guard page: reprotect it, and
396              * unprotect this one. This works even if we somehow missed
397              * the return-guard-page, and hit it on our way to new
398              * exhaustion instead. */
399             reset_thread_control_stack_guard_page(th);
400         }
401         else if (addr >= undefined_alien_address &&
402                  addr < undefined_alien_address + os_vm_page_size) {
403             backup_thread_state = thread_state;
404             open_stack_allocation(&thread_state);
405             stack_allocate(&thread_state, 256);
406
407             /* Save thread state */
408             target_thread_state =
409                 stack_allocate(&thread_state, sizeof(*target_thread_state));
410             (*target_thread_state) = backup_thread_state;
411
412             target_float_state =
413                 stack_allocate(&thread_state, sizeof(*target_float_state));
414             (*target_float_state) = float_state;
415
416             /* Set up siginfo */
417             siginfo = stack_allocate(&thread_state, sizeof(*siginfo));
418             /* what do we need to put in our fake siginfo?  It looks like
419              * the x86 code only uses si_signo and si_adrr. */
420             siginfo->si_signo = signal;
421             siginfo->si_addr = (void*)exception_state.faultvaddr;
422
423             call_c_function_in_context(&thread_state,
424                                        signal_emulation_wrapper,
425                                        5,
426                                        target_thread_state,
427                                        target_float_state,
428                                        signal,
429                                        siginfo,
430                                        undefined_alien_handler);
431         } else {
432
433             backup_thread_state = thread_state;
434             open_stack_allocation(&thread_state);
435             stack_allocate(&thread_state, 256);
436
437             /* Save thread state */
438             target_thread_state =
439                 stack_allocate(&thread_state, sizeof(*target_thread_state));
440             (*target_thread_state) = backup_thread_state;
441
442             target_float_state =
443                 stack_allocate(&thread_state, sizeof(*target_float_state));
444             (*target_float_state) = float_state;
445
446             /* Set up siginfo */
447             siginfo = stack_allocate(&thread_state, sizeof(*siginfo));
448             /* what do we need to put in our fake siginfo?  It looks like
449              * the x86 code only uses si_signo and si_adrr. */
450             siginfo->si_signo = signal;
451             siginfo->si_addr = (void*)exception_state.faultvaddr;
452
453             call_c_function_in_context(&thread_state,
454                                        signal_emulation_wrapper,
455                                        5,
456                                        target_thread_state,
457                                        target_float_state,
458                                        signal,
459                                        siginfo,
460                                        memory_fault_handler);
461         }
462         ret = thread_set_state(thread,
463                                x86_THREAD_STATE64,
464                                (thread_state_t)&thread_state,
465                                thread_state_count);
466
467         ret = thread_set_state(thread,
468                                x86_FLOAT_STATE64,
469                                (thread_state_t)&float_state,
470                                float_state_count);
471 #ifdef LISP_FEATURE_SB_THREAD
472         thread_mutex_unlock(&mach_exception_lock);
473 #endif
474         ret = KERN_SUCCESS;
475         break;
476
477     case EXC_BAD_INSTRUCTION:
478
479         ret = thread_get_state(thread,
480                                x86_THREAD_STATE64,
481                                (thread_state_t)&thread_state,
482                                &thread_state_count);
483         ret = thread_get_state(thread,
484                                x86_FLOAT_STATE64,
485                                (thread_state_t)&float_state,
486                                &float_state_count);
487         ret = thread_get_state(thread,
488                                x86_EXCEPTION_STATE64,
489                                (thread_state_t)&exception_state,
490                                &exception_state_count);
491         if (0xffffffffffff0b0f == *((u64 *)thread_state.rip)) {
492             /* fake sigreturn. */
493
494             /* When we get here, thread_state.rax is a pointer to a
495              * thread_state to restore. */
496             /* thread_state = *((thread_state_t *)thread_state.rax); */
497
498             ret = thread_set_state(thread,
499                                    x86_THREAD_STATE64,
500                                    (thread_state_t) thread_state.rax,
501                                    /* &thread_state, */
502                                    thread_state_count);
503
504             ret = thread_set_state(thread,
505                                    x86_FLOAT_STATE64,
506                                    (thread_state_t) thread_state.rbx,
507                                    /* &thread_state, */
508                                    float_state_count);
509         } else {
510
511             backup_thread_state = thread_state;
512             open_stack_allocation(&thread_state);
513             stack_allocate(&thread_state, 256);
514
515             /* Save thread state */
516             target_thread_state =
517                 stack_allocate(&thread_state, sizeof(*target_thread_state));
518             (*target_thread_state) = backup_thread_state;
519
520             target_float_state =
521                 stack_allocate(&thread_state, sizeof(*target_float_state));
522             (*target_float_state) = float_state;
523
524             /* Set up siginfo */
525             siginfo = stack_allocate(&thread_state, sizeof(*siginfo));
526             /* what do we need to put in our fake siginfo?  It looks like
527              * the x86 code only uses si_signo and si_adrr. */
528             if (*((unsigned short *)target_thread_state->rip) == 0x0b0f) {
529                 signal = SIGTRAP;
530                 siginfo->si_signo = signal;
531                 siginfo->si_addr = (void*)exception_state.faultvaddr;
532                 target_thread_state->rip += 2;
533                 call_c_function_in_context(&thread_state,
534                                            signal_emulation_wrapper,
535                                            5,
536                                            target_thread_state,
537                                            target_float_state,
538                                            signal,
539                                            siginfo,
540                                            sigtrap_handler);
541             } else {
542                 signal = SIGILL;
543                 siginfo->si_signo = signal;
544                 siginfo->si_addr = (void*)exception_state.faultvaddr;
545
546                 call_c_function_in_context(&thread_state,
547                                            signal_emulation_wrapper,
548                                            5,
549                                            target_thread_state,
550                                            target_float_state,
551                                            signal,
552                                            siginfo,
553                                            sigill_handler);
554             }
555             ret = thread_set_state(thread,
556                                    x86_THREAD_STATE64,
557                                    (thread_state_t)&thread_state,
558                                    thread_state_count);
559             ret = thread_set_state(thread,
560                                    x86_FLOAT_STATE64,
561                                    (thread_state_t)&float_state,
562                                    float_state_count);
563         }
564 #ifdef LISP_FEATURE_SB_THREAD
565         thread_mutex_unlock(&mach_exception_lock);
566 #endif
567         ret = KERN_SUCCESS;
568         break;
569
570     default:
571 #ifdef LISP_FEATURE_SB_THREAD
572         thread_mutex_unlock(&mach_exception_lock);
573 #endif
574         ret = KERN_INVALID_RIGHT;
575     }
576
577     dealloc_ret = mach_port_deallocate (current_mach_task, thread);
578     if (dealloc_ret) {
579       lose("mach_port_deallocate (thread) failed with return_code %d\n", dealloc_ret);
580     }
581
582     dealloc_ret = mach_port_deallocate (current_mach_task, task);
583     if (dealloc_ret) {
584       lose("mach_port_deallocate (task) failed with return_code %d\n", dealloc_ret);
585     }
586
587     return ret;
588 }
589
590 void
591 os_restore_fp_control(os_context_t *context)
592 {
593     /* KLUDGE: The x87 FPU control word is some nasty bitfield struct
594      * thing.  Rather than deal with that, just grab it as a 16-bit
595      * integer. */
596     unsigned short fpu_control_word =
597         *((unsigned short *)&context->uc_mcontext->fs.fpu_fcw);
598     /* reset exception flags and restore control flags on SSE2 FPU */
599     unsigned int temp = (context->uc_mcontext->fs.fpu_mxcsr) & ~0x3F;
600     asm ("ldmxcsr %0" : : "m" (temp));
601     /* same for x87 FPU. */
602     asm ("fldcw %0" : : "m" (fpu_control_word));
603 }
604
605 #endif