1 2 /*--------------------------------------------------------------------*/ 3 /*--- Create/destroy signal delivery frames. ---*/ 4 /*--- sigframe-ppc32-linux.c ---*/ 5 /*--------------------------------------------------------------------*/ 6 7 /* 8 This file is part of Valgrind, a dynamic binary instrumentation 9 framework. 10 11 Copyright (C) 2000-2015 Nicholas Nethercote 12 njn (at) valgrind.org 13 Copyright (C) 2004-2015 Paul Mackerras 14 paulus (at) samba.org 15 16 This program is free software; you can redistribute it and/or 17 modify it under the terms of the GNU General Public License as 18 published by the Free Software Foundation; either version 2 of the 19 License, or (at your option) any later version. 20 21 This program is distributed in the hope that it will be useful, but 22 WITHOUT ANY WARRANTY; without even the implied warranty of 23 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 24 General Public License for more details. 25 26 You should have received a copy of the GNU General Public License 27 along with this program; if not, write to the Free Software 28 Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 29 02111-1307, USA. 30 31 The GNU General Public License is contained in the file COPYING. 32 */ 33 34 #if defined(VGP_ppc32_linux) 35 36 #include "pub_core_basics.h" 37 #include "pub_core_vki.h" 38 #include "pub_core_vkiscnums.h" 39 #include "pub_core_threadstate.h" 40 #include "pub_core_aspacemgr.h" 41 #include "pub_core_libcbase.h" 42 #include "pub_core_libcassert.h" 43 #include "pub_core_libcprint.h" 44 #include "pub_core_machine.h" 45 #include "pub_core_options.h" 46 #include "pub_core_sigframe.h" 47 #include "pub_core_signals.h" 48 #include "pub_core_tooliface.h" 49 #include "pub_core_trampoline.h" 50 #include "pub_core_transtab.h" // VG_(discard_translations) 51 #include "priv_sigframe.h" 52 53 /* This module creates and removes signal frames for signal deliveries 54 on ppc32-linux. 55 56 Note, this file contains kernel-specific knowledge in the form of 57 'struct sigframe' and 'struct rt_sigframe'. How does that relate 58 to the vki kernel interface stuff? 59 60 Either a 'struct sigframe' or a 'struct rtsigframe' is pushed 61 onto the client's stack. This contains a subsidiary 62 vki_ucontext. That holds the vcpu's state across the signal, 63 so that the sighandler can mess with the vcpu state if it 64 really wants. 65 66 FIXME: sigcontexting is basically broken for the moment. When 67 delivering a signal, the integer registers and %eflags are 68 correctly written into the sigcontext, however the FP and SSE state 69 is not. When returning from a signal, only the integer registers 70 are restored from the sigcontext; the rest of the CPU state is 71 restored to what it was before the signal. 72 73 This will be fixed. 74 */ 75 76 77 /*------------------------------------------------------------*/ 78 /*--- Signal frame layouts ---*/ 79 /*------------------------------------------------------------*/ 80 81 // A structure in which to save the application's registers 82 // during the execution of signal handlers. 83 84 // Linux has 2 signal frame structures: one for normal signal 85 // deliveries, and one for SA_SIGINFO deliveries (also known as RT 86 // signals). 87 // 88 // In theory, so long as we get the arguments to the handler function 89 // right, it doesn't matter what the exact layout of the rest of the 90 // frame is. Unfortunately, things like gcc's exception unwinding 91 // make assumptions about the locations of various parts of the frame, 92 // so we need to duplicate it exactly. 93 94 /* Structure containing bits of information that we want to save 95 on signal delivery. */ 96 struct vg_sig_private { 97 UInt magicPI; 98 UInt sigNo_private; 99 VexGuestPPC32State vex_shadow1; 100 VexGuestPPC32State vex_shadow2; 101 }; 102 103 /* Structure put on stack for signal handlers with SA_SIGINFO clear. */ 104 struct nonrt_sigframe { 105 UInt gap1[16]; 106 struct vki_sigcontext sigcontext; 107 struct vki_mcontext mcontext; 108 struct vg_sig_private priv; 109 unsigned char abigap[224]; // unused 110 }; 111 112 /* Structure put on stack for signal handlers with SA_SIGINFO set. */ 113 struct rt_sigframe { 114 UInt gap1[20]; 115 vki_siginfo_t siginfo; 116 struct vki_ucontext ucontext; 117 struct vg_sig_private priv; 118 unsigned char abigap[224]; // unused 119 }; 120 121 #define SET_SIGNAL_LR(zztst, zzval) \ 122 do { tst->arch.vex.guest_LR = (zzval); \ 123 VG_TRACK( post_reg_write, Vg_CoreSignal, tst->tid, \ 124 offsetof(VexGuestPPC32State,guest_LR), \ 125 sizeof(UWord) ); \ 126 } while (0) 127 128 #define SET_SIGNAL_GPR(zztst, zzn, zzval) \ 129 do { tst->arch.vex.guest_GPR##zzn = (zzval); \ 130 VG_TRACK( post_reg_write, Vg_CoreSignal, tst->tid, \ 131 offsetof(VexGuestPPC32State,guest_GPR##zzn), \ 132 sizeof(UWord) ); \ 133 } while (0) 134 135 136 static 137 void stack_mcontext ( struct vki_mcontext *mc, 138 ThreadState* tst, 139 Bool use_rt_sigreturn, 140 UInt fault_addr ) 141 { 142 VG_TRACK( pre_mem_write, Vg_CoreSignal, tst->tid, "signal frame mcontext", 143 (Addr)mc, sizeof(struct vki_pt_regs) ); 144 145 # define DO(gpr) mc->mc_gregs[VKI_PT_R0+gpr] = tst->arch.vex.guest_GPR##gpr 146 DO(0); DO(1); DO(2); DO(3); DO(4); DO(5); DO(6); DO(7); 147 DO(8); DO(9); DO(10); DO(11); DO(12); DO(13); DO(14); DO(15); 148 DO(16); DO(17); DO(18); DO(19); DO(20); DO(21); DO(22); DO(23); 149 DO(24); DO(25); DO(26); DO(27); DO(28); DO(29); DO(30); DO(31); 150 # undef DO 151 152 mc->mc_gregs[VKI_PT_NIP] = tst->arch.vex.guest_CIA; 153 mc->mc_gregs[VKI_PT_MSR] = 0xf032; /* pretty arbitrary */ 154 mc->mc_gregs[VKI_PT_ORIG_R3] = tst->arch.vex.guest_GPR3; 155 mc->mc_gregs[VKI_PT_CTR] = tst->arch.vex.guest_CTR; 156 mc->mc_gregs[VKI_PT_LNK] = tst->arch.vex.guest_LR; 157 mc->mc_gregs[VKI_PT_XER] = LibVEX_GuestPPC32_get_XER(&tst->arch.vex); 158 mc->mc_gregs[VKI_PT_CCR] = LibVEX_GuestPPC32_get_CR(&tst->arch.vex); 159 mc->mc_gregs[VKI_PT_MQ] = 0; 160 mc->mc_gregs[VKI_PT_TRAP] = 0; 161 mc->mc_gregs[VKI_PT_DAR] = fault_addr; 162 mc->mc_gregs[VKI_PT_DSISR] = 0; 163 mc->mc_gregs[VKI_PT_RESULT] = 0; 164 VG_TRACK( post_mem_write, Vg_CoreSignal, tst->tid, 165 (Addr)mc, sizeof(struct vki_pt_regs) ); 166 167 /* XXX should do FP and vector regs */ 168 169 /* set up signal return trampoline */ 170 /* NB. 5 Sept 07. mc->mc_pad[0..1] used to contain a the code to 171 which the signal handler returns, and it just did sys_sigreturn 172 or sys_rt_sigreturn. But this doesn't work if the stack is 173 non-executable, and it isn't consistent with the x86-linux and 174 amd64-linux scheme for removing the stack frame. So instead be 175 consistent and use a stub in m_trampoline. Then it doesn't 176 matter whether or not the (guest) stack is executable. This 177 fixes #149519 and #145837. */ 178 VG_TRACK(pre_mem_write, Vg_CoreSignal, tst->tid, "signal frame mcontext", 179 (Addr)&mc->mc_pad, sizeof(mc->mc_pad)); 180 mc->mc_pad[0] = 0; /* invalid */ 181 mc->mc_pad[1] = 0; /* invalid */ 182 VG_TRACK( post_mem_write, Vg_CoreSignal, tst->tid, 183 (Addr)&mc->mc_pad, sizeof(mc->mc_pad) ); 184 /* invalidate any translation of this area */ 185 VG_(discard_translations)( (Addr)&mc->mc_pad, 186 sizeof(mc->mc_pad), "stack_mcontext" ); 187 188 /* set the signal handler to return to the trampoline */ 189 SET_SIGNAL_LR(tst, (Addr)(use_rt_sigreturn 190 ? (Addr)&VG_(ppc32_linux_SUBST_FOR_rt_sigreturn) 191 : (Addr)&VG_(ppc32_linux_SUBST_FOR_sigreturn) 192 )); 193 } 194 195 //:: /* Valgrind-specific parts of the signal frame */ 196 //:: struct vg_sigframe 197 //:: { 198 //:: /* Sanity check word. */ 199 //:: UInt magicPI; 200 //:: 201 //:: UInt handlerflags; /* flags for signal handler */ 202 //:: 203 //:: 204 //:: /* Safely-saved version of sigNo, as described above. */ 205 //:: Int sigNo_private; 206 //:: 207 //:: /* XXX This is wrong. Surely we should store the shadow values 208 //:: into the shadow memory behind the actual values? */ 209 //:: VexGuestPPC32State vex_shadow; 210 //:: 211 //:: /* HACK ALERT */ 212 //:: VexGuestPPC32State vex; 213 //:: /* end HACK ALERT */ 214 //:: 215 //:: /* saved signal mask to be restored when handler returns */ 216 //:: vki_sigset_t mask; 217 //:: 218 //:: /* Sanity check word. Is the highest-addressed word; do not 219 //:: move!*/ 220 //:: UInt magicE; 221 //:: }; 222 //:: 223 //:: struct sigframe 224 //:: { 225 //:: /* Sig handler's return address */ 226 //:: Addr retaddr; 227 //:: Int sigNo; 228 //:: 229 //:: struct vki_sigcontext sigContext; 230 //:: //.. struct _vki_fpstate fpstate; 231 //:: 232 //:: struct vg_sigframe vg; 233 //:: }; 234 //:: 235 //:: struct rt_sigframe 236 //:: { 237 //:: /* Sig handler's return address */ 238 //:: Addr retaddr; 239 //:: Int sigNo; 240 //:: 241 //:: /* ptr to siginfo_t. */ 242 //:: Addr psigInfo; 243 //:: 244 //:: /* ptr to ucontext */ 245 //:: Addr puContext; 246 //:: /* pointed to by psigInfo */ 247 //:: vki_siginfo_t sigInfo; 248 //:: 249 //:: /* pointed to by puContext */ 250 //:: struct vki_ucontext uContext; 251 //:: //.. struct _vki_fpstate fpstate; 252 //:: 253 //:: struct vg_sigframe vg; 254 //:: }; 255 256 257 //:: /*------------------------------------------------------------*/ 258 //:: /*--- Signal operations ---*/ 259 //:: /*------------------------------------------------------------*/ 260 //:: 261 //:: /* 262 //:: Great gobs of FP state conversion taken wholesale from 263 //:: linux/arch/i386/kernel/i387.c 264 //:: */ 265 //:: 266 //:: /* 267 //:: * FXSR floating point environment conversions. 268 //:: */ 269 //:: #define X86_FXSR_MAGIC 0x0000 270 //:: 271 //:: /* 272 //:: * FPU tag word conversions. 273 //:: */ 274 //:: 275 //:: static inline unsigned short twd_i387_to_fxsr( unsigned short twd ) 276 //:: { 277 //:: unsigned int tmp; /* to avoid 16 bit prefixes in the code */ 278 //:: 279 //:: /* Transform each pair of bits into 01 (valid) or 00 (empty) */ 280 //:: tmp = ~twd; 281 //:: tmp = (tmp | (tmp>>1)) & 0x5555; /* 0V0V0V0V0V0V0V0V */ 282 //:: /* and move the valid bits to the lower byte. */ 283 //:: tmp = (tmp | (tmp >> 1)) & 0x3333; /* 00VV00VV00VV00VV */ 284 //:: tmp = (tmp | (tmp >> 2)) & 0x0f0f; /* 0000VVVV0000VVVV */ 285 //:: tmp = (tmp | (tmp >> 4)) & 0x00ff; /* 00000000VVVVVVVV */ 286 //:: return tmp; 287 //:: } 288 //:: 289 //:: static unsigned long twd_fxsr_to_i387( const struct i387_fxsave_struct *fxsave ) 290 //:: { 291 //:: struct _vki_fpxreg *st = NULL; 292 //:: unsigned long twd = (unsigned long) fxsave->twd; 293 //:: unsigned long tag; 294 //:: unsigned long ret = 0xffff0000u; 295 //:: int i; 296 //:: 297 //:: #define FPREG_ADDR(f, n) ((char *)&(f)->st_space + (n) * 16); 298 //:: 299 //:: for ( i = 0 ; i < 8 ; i++ ) { 300 //:: if ( twd & 0x1 ) { 301 //:: st = (struct _vki_fpxreg *) FPREG_ADDR( fxsave, i ); 302 //:: 303 //:: switch ( st->exponent & 0x7fff ) { 304 //:: case 0x7fff: 305 //:: tag = 2; /* Special */ 306 //:: break; 307 //:: case 0x0000: 308 //:: if ( !st->significand[0] && 309 //:: !st->significand[1] && 310 //:: !st->significand[2] && 311 //:: !st->significand[3] ) { 312 //:: tag = 1; /* Zero */ 313 //:: } else { 314 //:: tag = 2; /* Special */ 315 //:: } 316 //:: break; 317 //:: default: 318 //:: if ( st->significand[3] & 0x8000 ) { 319 //:: tag = 0; /* Valid */ 320 //:: } else { 321 //:: tag = 2; /* Special */ 322 //:: } 323 //:: break; 324 //:: } 325 //:: } else { 326 //:: tag = 3; /* Empty */ 327 //:: } 328 //:: ret |= (tag << (2 * i)); 329 //:: twd = twd >> 1; 330 //:: } 331 //:: return ret; 332 //:: } 333 //:: 334 //:: static void convert_fxsr_to_user( struct _vki_fpstate *buf, 335 //:: const struct i387_fxsave_struct *fxsave ) 336 //:: { 337 //:: unsigned long env[7]; 338 //:: struct _vki_fpreg *to; 339 //:: struct _vki_fpxreg *from; 340 //:: int i; 341 //:: 342 //:: env[0] = (unsigned long)fxsave->cwd | 0xffff0000ul; 343 //:: env[1] = (unsigned long)fxsave->swd | 0xffff0000ul; 344 //:: env[2] = twd_fxsr_to_i387(fxsave); 345 //:: env[3] = fxsave->fip; 346 //:: env[4] = fxsave->fcs | ((unsigned long)fxsave->fop << 16); 347 //:: env[5] = fxsave->foo; 348 //:: env[6] = fxsave->fos; 349 //:: 350 //:: VG_(memcpy)(buf, env, 7 * sizeof(unsigned long)); 351 //:: 352 //:: to = &buf->_st[0]; 353 //:: from = (struct _vki_fpxreg *) &fxsave->st_space[0]; 354 //:: for ( i = 0 ; i < 8 ; i++, to++, from++ ) { 355 //:: unsigned long __user *t = (unsigned long __user *)to; 356 //:: unsigned long *f = (unsigned long *)from; 357 //:: 358 //:: t[0] = f[0]; 359 //:: t[1] = f[1]; 360 //:: to->exponent = from->exponent; 361 //:: } 362 //:: } 363 //:: 364 //:: static void convert_fxsr_from_user( struct i387_fxsave_struct *fxsave, 365 //:: const struct _vki_fpstate *buf ) 366 //:: { 367 //:: unsigned long env[7]; 368 //:: struct _vki_fpxreg *to; 369 //:: const struct _vki_fpreg *from; 370 //:: int i; 371 //:: 372 //:: VG_(memcpy)(env, buf, 7 * sizeof(long)); 373 //:: 374 //:: fxsave->cwd = (unsigned short)(env[0] & 0xffff); 375 //:: fxsave->swd = (unsigned short)(env[1] & 0xffff); 376 //:: fxsave->twd = twd_i387_to_fxsr((unsigned short)(env[2] & 0xffff)); 377 //:: fxsave->fip = env[3]; 378 //:: fxsave->fop = (unsigned short)((env[4] & 0xffff0000ul) >> 16); 379 //:: fxsave->fcs = (env[4] & 0xffff); 380 //:: fxsave->foo = env[5]; 381 //:: fxsave->fos = env[6]; 382 //:: 383 //:: to = (struct _vki_fpxreg *) &fxsave->st_space[0]; 384 //:: from = &buf->_st[0]; 385 //:: for ( i = 0 ; i < 8 ; i++, to++, from++ ) { 386 //:: unsigned long *t = (unsigned long *)to; 387 //:: unsigned long __user *f = (unsigned long __user *)from; 388 //:: 389 //:: t[0] = f[0]; 390 //:: t[1] = f[1]; 391 //:: to->exponent = from->exponent; 392 //:: } 393 //:: } 394 //:: 395 //:: static inline void save_i387_fsave( arch_thread_t *regs, struct _vki_fpstate *buf ) 396 //:: { 397 //:: struct i387_fsave_struct *fs = ®s->m_sse.fsave; 398 //:: 399 //:: fs->status = fs->swd; 400 //:: VG_(memcpy)(buf, fs, sizeof(*fs)); 401 //:: } 402 //:: 403 //:: static void save_i387_fxsave( arch_thread_t *regs, struct _vki_fpstate *buf ) 404 //:: { 405 //:: const struct i387_fxsave_struct *fx = ®s->m_sse.fxsave; 406 //:: convert_fxsr_to_user( buf, fx ); 407 //:: 408 //:: buf->status = fx->swd; 409 //:: buf->magic = X86_FXSR_MAGIC; 410 //:: VG_(memcpy)(buf->_fxsr_env, fx, sizeof(struct i387_fxsave_struct)); 411 //:: } 412 //:: 413 //:: static void save_i387( arch_thread_t *regs, struct _vki_fpstate *buf ) 414 //:: { 415 //:: if ( VG_(have_ssestate) ) 416 //:: save_i387_fxsave( regs, buf ); 417 //:: else 418 //:: save_i387_fsave( regs, buf ); 419 //:: } 420 //:: 421 //:: static inline void restore_i387_fsave( arch_thread_t *regs, const struct _vki_fpstate __user *buf ) 422 //:: { 423 //:: VG_(memcpy)( ®s->m_sse.fsave, buf, sizeof(struct i387_fsave_struct) ); 424 //:: } 425 //:: 426 //:: static void restore_i387_fxsave( arch_thread_t *regs, const struct _vki_fpstate __user *buf ) 427 //:: { 428 //:: VG_(memcpy)(®s->m_sse.fxsave, &buf->_fxsr_env[0], 429 //:: sizeof(struct i387_fxsave_struct) ); 430 //:: /* mxcsr reserved bits must be masked to zero for security reasons */ 431 //:: regs->m_sse.fxsave.mxcsr &= 0xffbf; 432 //:: convert_fxsr_from_user( ®s->m_sse.fxsave, buf ); 433 //:: } 434 //:: 435 //:: static void restore_i387( arch_thread_t *regs, const struct _vki_fpstate __user *buf ) 436 //:: { 437 //:: if ( VG_(have_ssestate) ) { 438 //:: restore_i387_fxsave( regs, buf ); 439 //:: } else { 440 //:: restore_i387_fsave( regs, buf ); 441 //:: } 442 //:: } 443 444 445 446 447 /*------------------------------------------------------------*/ 448 /*--- Creating signal frames ---*/ 449 /*------------------------------------------------------------*/ 450 451 //.. /* Create a plausible-looking sigcontext from the thread's 452 //.. Vex guest state. NOTE: does not fill in the FP or SSE 453 //.. bits of sigcontext at the moment. 454 //.. */ 455 //.. static 456 //.. void synth_ucontext(ThreadId tid, const vki_siginfo_t *si, 457 //.. const vki_sigset_t *set, struct vki_ucontext *uc) 458 //.. { 459 //.. ThreadState *tst = VG_(get_ThreadState)(tid); 460 //.. struct vki_sigcontext *sc = &uc->uc_mcontext; 461 //.. 462 //.. VG_(memset)(uc, 0, sizeof(*uc)); 463 //.. 464 //.. uc->uc_flags = 0; 465 //.. uc->uc_link = 0; 466 //.. uc->uc_sigmask = *set; 467 //.. uc->uc_stack = tst->altstack; 468 //.. sc->fpstate = fpstate; 469 //.. 470 //.. // FIXME: save_i387(&tst->arch, fpstate); 471 //.. 472 //.. # define SC2(reg,REG) sc->reg = tst->arch.vex.guest_##REG 473 //.. SC2(gs,GS); 474 //.. SC2(fs,FS); 475 //.. SC2(es,ES); 476 //.. SC2(ds,DS); 477 //.. 478 //.. SC2(edi,EDI); 479 //.. SC2(esi,ESI); 480 //.. SC2(ebp,EBP); 481 //.. SC2(esp,ESP); 482 //.. SC2(ebx,EBX); 483 //.. SC2(edx,EDX); 484 //.. SC2(ecx,ECX); 485 //.. SC2(eax,EAX); 486 //.. 487 //.. SC2(eip,EIP); 488 //.. SC2(cs,CS); 489 //.. sc->eflags = LibVEX_GuestX86_get_eflags(&tst->arch.vex); 490 //.. SC2(ss,SS); 491 //.. /* XXX esp_at_signal */ 492 //.. /* XXX trapno */ 493 //.. /* XXX err */ 494 //.. # undef SC2 495 //.. 496 //.. sc->cr2 = (UInt)si->_sifields._sigfault._addr; 497 //.. } 498 /* 499 //.. #define SET_SIGNAL_ESP(zztid, zzval) \ 500 //.. SET_THREAD_REG(zztid, zzval, STACK_PTR, post_reg_write, \ 501 //.. Vg_CoreSignal, zztid, VG_O_STACK_PTR, sizeof(Addr)) 502 */ 503 504 505 //.. /* Build the Valgrind-specific part of a signal frame. */ 506 //.. 507 //.. static void build_vg_sigframe(struct vg_sigframe *frame, 508 //.. ThreadState *tst, 509 //.. const vki_sigset_t *mask, 510 //.. UInt flags, 511 //.. Int sigNo) 512 //.. { 513 //.. frame->sigNo_private = sigNo; 514 //.. frame->magicPI = 0x31415927; 515 //.. frame->vex_shadow = tst->arch.vex_shadow; 516 //.. /* HACK ALERT */ 517 //.. frame->vex = tst->arch.vex; 518 //.. /* end HACK ALERT */ 519 //.. frame->mask = tst->sig_mask; 520 //.. frame->handlerflags = flags; 521 //.. frame->magicE = 0x27182818; 522 //.. } 523 524 525 //.. static Addr build_sigframe(ThreadState *tst, 526 //.. Addr esp_top_of_frame, 527 //.. const vki_siginfo_t *siginfo, 528 //.. void *handler, UInt flags, 529 //.. const vki_sigset_t *mask, 530 //.. void *restorer) 531 //.. { 532 //.. struct sigframe *frame; 533 //.. Addr esp = esp_top_of_frame; 534 //.. Int sigNo = siginfo->si_signo; 535 //.. struct vki_ucontext uc; 536 //.. 537 //.. vg_assert((flags & VKI_SA_SIGINFO) == 0); 538 //.. 539 //.. esp -= sizeof(*frame); 540 //.. esp = ROUNDDN(esp, 16); 541 //.. frame = (struct sigframe *)esp; 542 //.. 543 //.. if (!extend(tst, esp, sizeof(*frame))) 544 //.. return esp_top_of_frame; 545 //.. 546 //.. /* retaddr, sigNo, siguContext fields are to be written */ 547 //.. VG_TRACK( pre_mem_write, Vg_CoreSignal, tst->tid, "signal handler frame", 548 //.. esp, offsetof(struct sigframe, vg) ); 549 //.. 550 //.. frame->sigNo = sigNo; 551 //.. 552 //.. if (flags & VKI_SA_RESTORER) 553 //.. frame->retaddr = (Addr)restorer; 554 //.. else 555 //.. frame->retaddr 556 //.. = VG_(client_trampoline_code)+VG_(tramp_sigreturn_offset); 557 //.. 558 //.. synth_ucontext(tst->tid, siginfo, mask, &uc, &frame->fpstate); 559 //.. 560 //.. VG_(memcpy)(&frame->sigContext, &uc.uc_mcontext, 561 //.. sizeof(struct vki_sigcontext)); 562 //.. frame->sigContext.oldmask = mask->sig[0]; 563 //.. 564 //.. VG_TRACK( post_mem_write, Vg_CoreSignal, tst->tid, 565 //.. esp, offsetof(struct sigframe, vg) ); 566 //.. 567 //.. build_vg_sigframe(&frame->vg, tst, mask, flags, sigNo); 568 //.. 569 //.. return esp; 570 //.. } 571 572 573 //.. static Addr build_rt_sigframe(ThreadState *tst, 574 //.. Addr esp_top_of_frame, 575 //.. const vki_siginfo_t *siginfo, 576 //.. void *handler, UInt flags, 577 //.. const vki_sigset_t *mask, 578 //.. void *restorer) 579 //.. { 580 //.. struct rt_sigframe *frame; 581 //.. Addr esp = esp_top_of_frame; 582 //.. Int sigNo = siginfo->si_signo; 583 //.. 584 //.. vg_assert((flags & VKI_SA_SIGINFO) != 0); 585 //.. 586 //.. esp -= sizeof(*frame); 587 //.. esp = ROUNDDN(esp, 16); 588 //.. frame = (struct rt_sigframe *)esp; 589 //.. 590 //.. if (!extend(tst, esp, sizeof(*frame))) 591 //.. return esp_top_of_frame; 592 //.. 593 //.. /* retaddr, sigNo, pSiginfo, puContext fields are to be written */ 594 //.. VG_TRACK( pre_mem_write, Vg_CoreSignal, tst->tid, "rt signal handler frame", 595 //.. esp, offsetof(struct rt_sigframe, vg) ); 596 //.. 597 //.. frame->sigNo = sigNo; 598 //.. 599 //.. if (flags & VKI_SA_RESTORER) 600 //.. frame->retaddr = (Addr)restorer; 601 //.. else 602 //.. frame->retaddr 603 //.. = VG_(client_trampoline_code)+VG_(tramp_rt_sigreturn_offset); 604 //.. 605 //.. frame->psigInfo = (Addr)&frame->sigInfo; 606 //.. frame->puContext = (Addr)&frame->uContext; 607 //.. VG_(memcpy)(&frame->sigInfo, siginfo, sizeof(vki_siginfo_t)); 608 //.. 609 //.. /* SIGILL defines addr to be the faulting address */ 610 //.. if (sigNo == VKI_SIGILL && siginfo->si_code > 0) 611 //.. frame->sigInfo._sifields._sigfault._addr 612 //.. = (void*)tst->arch.vex.guest_CIA; 613 //.. 614 //.. synth_ucontext(tst->tid, siginfo, mask, &frame->uContext, &frame->fpstate); 615 //.. 616 //.. VG_TRACK( post_mem_write, Vg_CoreSignal, tst->tid, 617 //.. esp, offsetof(struct rt_sigframe, vg) ); 618 //.. 619 //.. build_vg_sigframe(&frame->vg, tst, mask, flags, sigNo); 620 //.. 621 //.. return esp; 622 //.. } 623 624 625 /* EXPORTED */ 626 void VG_(sigframe_create)( ThreadId tid, 627 Bool on_altstack, 628 Addr sp_top_of_frame, 629 const vki_siginfo_t *siginfo, 630 const struct vki_ucontext *siguc, 631 void *handler, 632 UInt flags, 633 const vki_sigset_t *mask, 634 void *restorer ) 635 { 636 struct vg_sig_private *priv; 637 Addr sp; 638 ThreadState *tst; 639 Int sigNo = siginfo->si_signo; 640 Addr faultaddr; 641 642 /* Stack must be 16-byte aligned */ 643 sp_top_of_frame &= ~0xf; 644 645 if (flags & VKI_SA_SIGINFO) { 646 sp = sp_top_of_frame - sizeof(struct rt_sigframe); 647 } else { 648 sp = sp_top_of_frame - sizeof(struct nonrt_sigframe); 649 } 650 651 tst = VG_(get_ThreadState)(tid); 652 653 if (! ML_(sf_maybe_extend_stack)(tst, sp, sp_top_of_frame - sp, flags)) 654 return; 655 656 vg_assert(VG_IS_16_ALIGNED(sp)); 657 658 /* Set up the stack chain pointer */ 659 VG_TRACK( pre_mem_write, Vg_CoreSignal, tid, "signal handler frame", 660 sp, sizeof(UWord) ); 661 *(Addr *)sp = tst->arch.vex.guest_GPR1; 662 VG_TRACK( post_mem_write, Vg_CoreSignal, tid, 663 sp, sizeof(UWord) ); 664 665 faultaddr = (Addr)siginfo->_sifields._sigfault._addr; 666 if (sigNo == VKI_SIGILL && siginfo->si_code > 0) 667 faultaddr = tst->arch.vex.guest_CIA; 668 669 if (flags & VKI_SA_SIGINFO) { 670 struct rt_sigframe *frame = (struct rt_sigframe *) sp; 671 struct vki_ucontext *ucp = &frame->ucontext; 672 673 VG_TRACK( pre_mem_write, Vg_CoreSignal, tid, "signal frame siginfo", 674 (Addr)&frame->siginfo, sizeof(frame->siginfo) ); 675 VG_(memcpy)(&frame->siginfo, siginfo, sizeof(*siginfo)); 676 VG_TRACK( post_mem_write, Vg_CoreSignal, tid, 677 (Addr)&frame->siginfo, sizeof(frame->siginfo) ); 678 679 VG_TRACK( pre_mem_write, Vg_CoreSignal, tid, "signal frame ucontext", 680 (Addr)ucp, offsetof(struct vki_ucontext, uc_pad) ); 681 ucp->uc_flags = 0; 682 ucp->uc_link = 0; 683 ucp->uc_stack = tst->altstack; 684 VG_TRACK( post_mem_write, Vg_CoreSignal, tid, (Addr)ucp, 685 offsetof(struct vki_ucontext, uc_pad) ); 686 687 VG_TRACK( pre_mem_write, Vg_CoreSignal, tid, "signal frame ucontext", 688 (Addr)&ucp->uc_regs, 689 sizeof(ucp->uc_regs) + sizeof(ucp->uc_sigmask) ); 690 ucp->uc_regs = &ucp->uc_mcontext; 691 ucp->uc_sigmask = tst->sig_mask; 692 VG_TRACK( post_mem_write, Vg_CoreSignal, tid, 693 (Addr)&ucp->uc_regs, 694 sizeof(ucp->uc_regs) + sizeof(ucp->uc_sigmask) ); 695 696 stack_mcontext(&ucp->uc_mcontext, tst, True/*use_rt_sigreturn*/, faultaddr); 697 priv = &frame->priv; 698 699 SET_SIGNAL_GPR(tid, 4, (Addr) &frame->siginfo); 700 SET_SIGNAL_GPR(tid, 5, (Addr) ucp); 701 /* the kernel sets this, though it doesn't seem to be in the ABI */ 702 SET_SIGNAL_GPR(tid, 6, (Addr) &frame->siginfo); 703 704 } else { 705 /* non-RT signal delivery */ 706 struct nonrt_sigframe *frame = (struct nonrt_sigframe *) sp; 707 struct vki_sigcontext *scp = &frame->sigcontext; 708 709 VG_TRACK( pre_mem_write, Vg_CoreSignal, tid, "signal frame sigcontext", 710 (Addr)&scp->_unused[3], sizeof(*scp) - 3 * sizeof(UInt) ); 711 scp->signal = sigNo; 712 scp->handler = (Addr) handler; 713 scp->oldmask = tst->sig_mask.sig[0]; 714 scp->_unused[3] = tst->sig_mask.sig[1]; 715 VG_TRACK( post_mem_write, Vg_CoreSignal, tid, 716 (Addr)&scp->_unused[3], sizeof(*scp) - 3 * sizeof(UInt) ); 717 718 stack_mcontext(&frame->mcontext, tst, False/*!use_rt_sigreturn*/, faultaddr); 719 priv = &frame->priv; 720 721 SET_SIGNAL_GPR(tid, 4, (Addr) scp); 722 } 723 724 priv->magicPI = 0x31415927; 725 priv->sigNo_private = sigNo; 726 priv->vex_shadow1 = tst->arch.vex_shadow1; 727 priv->vex_shadow2 = tst->arch.vex_shadow2; 728 729 SET_SIGNAL_GPR(tid, 1, sp); 730 SET_SIGNAL_GPR(tid, 3, sigNo); 731 tst->arch.vex.guest_CIA = (Addr) handler; 732 733 //.. Addr esp; 734 //.. ThreadState* tst = VG_(get_ThreadState)(tid); 735 //.. 736 //.. if (flags & VKI_SA_SIGINFO) 737 //.. esp = build_rt_sigframe(tst, esp_top_of_frame, siginfo, 738 //.. handler, flags, mask, restorer); 739 //.. else 740 //.. esp = build_sigframe(tst, esp_top_of_frame, 741 //.. siginfo, handler, flags, mask, restorer); 742 //.. 743 //.. /* Set the thread so it will next run the handler. */ 744 //.. /* tst->m_esp = esp; */ 745 //.. SET_SIGNAL_ESP(tid, esp); 746 //.. 747 //.. //VG_(printf)("handler = %p\n", handler); 748 //.. tst->arch.vex.guest_CIA = (Addr) handler; 749 //.. /* This thread needs to be marked runnable, but we leave that the 750 //.. caller to do. */ 751 752 if (0) 753 VG_(printf)("pushed signal frame; %%R1 now = %#lx, " 754 "next %%CIA = %#x, status=%d\n", 755 sp, tst->arch.vex.guest_CIA, (Int)tst->status); 756 } 757 758 759 /*------------------------------------------------------------*/ 760 /*--- Destroying signal frames ---*/ 761 /*------------------------------------------------------------*/ 762 763 //.. /* Return False and don't do anything, just set the client to take a 764 //.. segfault, if it looks like the frame is corrupted. */ 765 //.. static 766 //.. Bool restore_vg_sigframe ( ThreadState *tst, 767 //.. struct vg_sigframe *frame, Int *sigNo ) 768 //.. { 769 //.. if (frame->magicPI != 0x31415927 || 770 //.. frame->magicE != 0x27182818) { 771 //.. VG_(message)(Vg_UserMsg, "Thread %d return signal frame " 772 //.. "corrupted. Killing process.", 773 //.. tst->tid); 774 //.. VG_(set_default_handler)(VKI_SIGSEGV); 775 //.. VG_(synth_fault)(tst->tid); 776 //.. *sigNo = VKI_SIGSEGV; 777 //.. return False; 778 //.. } 779 //.. tst->sig_mask = frame->mask; 780 //.. tst->tmp_sig_mask = frame->mask; 781 //.. tst->arch.vex_shadow = frame->vex_shadow; 782 //.. /* HACK ALERT */ 783 //.. tst->arch.vex = frame->vex; 784 //.. /* end HACK ALERT */ 785 //.. *sigNo = frame->sigNo_private; 786 //.. return True; 787 //.. } 788 789 //.. static 790 //.. void restore_sigcontext( ThreadState *tst, 791 //.. struct vki_sigcontext *sc ) 792 //.. //.. struct vki_sigcontext *sc, struct _vki_fpstate *fpstate ) 793 //.. { 794 //.. tst->arch.vex.guest_EAX = sc->eax; 795 //.. tst->arch.vex.guest_ECX = sc->ecx; 796 //.. tst->arch.vex.guest_EDX = sc->edx; 797 //.. tst->arch.vex.guest_EBX = sc->ebx; 798 //.. tst->arch.vex.guest_EBP = sc->ebp; 799 //.. tst->arch.vex.guest_ESP = sc->esp; 800 //.. tst->arch.vex.guest_ESI = sc->esi; 801 //.. tst->arch.vex.guest_EDI = sc->edi; 802 //.. //:: tst->arch.vex.guest_eflags = sc->eflags; 803 //.. //:: tst->arch.vex.guest_EIP = sc->eip; 804 //.. 805 //.. tst->arch.vex.guest_CS = sc->cs; 806 //.. tst->arch.vex.guest_SS = sc->ss; 807 //.. tst->arch.vex.guest_DS = sc->ds; 808 //.. tst->arch.vex.guest_ES = sc->es; 809 //.. tst->arch.vex.guest_FS = sc->fs; 810 //.. tst->arch.vex.guest_GS = sc->gs; 811 //.. 812 //.. //:: restore_i387(&tst->arch, fpstate); 813 //.. } 814 815 816 //.. static 817 //.. SizeT restore_sigframe ( ThreadState *tst, 818 //.. struct sigframe *frame, Int *sigNo ) 819 //.. { 820 //.. if (restore_vg_sigframe(tst, &frame->vg, sigNo)) 821 //.. restore_sigcontext(tst, &frame->sigContext, &frame->fpstate); 822 //.. return sizeof(*frame); 823 //.. } 824 825 //.. static 826 //.. SizeT restore_rt_sigframe ( ThreadState *tst, 827 //.. struct rt_sigframe *frame, Int *sigNo ) 828 //.. { 829 //.. if (restore_vg_sigframe(tst, &frame->vg, sigNo)) 830 //.. restore_sigcontext(tst, &frame->uContext.uc_mcontext, &frame->fpstate); 831 //.. return sizeof(*frame); 832 //.. } 833 834 835 /* EXPORTED */ 836 void VG_(sigframe_destroy)( ThreadId tid, Bool isRT ) 837 { 838 ThreadState *tst; 839 struct vg_sig_private *priv; 840 Addr sp; 841 UInt frame_size; 842 struct vki_mcontext *mc; 843 Int sigNo; 844 Bool has_siginfo = isRT; 845 846 vg_assert(VG_(is_valid_tid)(tid)); 847 tst = VG_(get_ThreadState)(tid); 848 849 /* Check that the stack frame looks valid */ 850 sp = tst->arch.vex.guest_GPR1; 851 vg_assert(VG_IS_16_ALIGNED(sp)); 852 /* JRS 17 Nov 05: This code used to check that *sp -- which should 853 have been set by the stwu at the start of the handler -- points 854 to just above the frame (ie, the previous frame). However, that 855 isn't valid when delivering signals on alt stacks. So I removed 856 it. The frame is still sanity-checked using the priv->magicPI 857 field. */ 858 859 if (has_siginfo) { 860 struct rt_sigframe *frame = (struct rt_sigframe *)sp; 861 frame_size = sizeof(*frame); 862 mc = &frame->ucontext.uc_mcontext; 863 priv = &frame->priv; 864 vg_assert(priv->magicPI == 0x31415927); 865 tst->sig_mask = frame->ucontext.uc_sigmask; 866 } else { 867 struct nonrt_sigframe *frame = (struct nonrt_sigframe *)sp; 868 frame_size = sizeof(*frame); 869 mc = &frame->mcontext; 870 priv = &frame->priv; 871 vg_assert(priv->magicPI == 0x31415927); 872 tst->sig_mask.sig[0] = frame->sigcontext.oldmask; 873 tst->sig_mask.sig[1] = frame->sigcontext._unused[3]; 874 } 875 tst->tmp_sig_mask = tst->sig_mask; 876 877 sigNo = priv->sigNo_private; 878 879 # define DO(gpr) tst->arch.vex.guest_GPR##gpr = mc->mc_gregs[VKI_PT_R0+gpr] 880 DO(0); DO(1); DO(2); DO(3); DO(4); DO(5); DO(6); DO(7); 881 DO(8); DO(9); DO(10); DO(11); DO(12); DO(13); DO(14); DO(15); 882 DO(16); DO(17); DO(18); DO(19); DO(20); DO(21); DO(22); DO(23); 883 DO(24); DO(25); DO(26); DO(27); DO(28); DO(29); DO(30); DO(31); 884 # undef DO 885 886 tst->arch.vex.guest_CIA = mc->mc_gregs[VKI_PT_NIP]; 887 888 // Umm ... ? (jrs 2005 July 8) 889 // tst->arch.m_orig_gpr3 = mc->mc_gregs[VKI_PT_ORIG_R3]; 890 891 LibVEX_GuestPPC32_put_CR( mc->mc_gregs[VKI_PT_CCR], &tst->arch.vex ); 892 893 tst->arch.vex.guest_LR = mc->mc_gregs[VKI_PT_LNK]; 894 tst->arch.vex.guest_CTR = mc->mc_gregs[VKI_PT_CTR]; 895 LibVEX_GuestPPC32_put_XER( mc->mc_gregs[VKI_PT_XER], &tst->arch.vex ); 896 897 tst->arch.vex_shadow1 = priv->vex_shadow1; 898 tst->arch.vex_shadow2 = priv->vex_shadow2; 899 900 VG_TRACK(die_mem_stack_signal, sp, frame_size); 901 902 if (VG_(clo_trace_signals)) 903 VG_(message)(Vg_DebugMsg, 904 "vg_pop_signal_frame (thread %u): " 905 "isRT=%d valid magic; EIP=%#x\n", 906 tid, has_siginfo, tst->arch.vex.guest_CIA); 907 908 /* tell the tools */ 909 VG_TRACK( post_deliver_signal, tid, sigNo ); 910 911 //.. Addr esp; 912 //.. ThreadState* tst; 913 //.. SizeT size; 914 //.. Int sigNo; 915 //.. 916 //.. tst = VG_(get_ThreadState)(tid); 917 //.. 918 //.. /* Correctly reestablish the frame base address. */ 919 //.. esp = tst->arch.vex.guest_ESP; 920 //.. 921 //.. if (!isRT) 922 //.. size = restore_sigframe(tst, (struct sigframe *)esp, &sigNo); 923 //.. else 924 //.. size = restore_rt_sigframe(tst, (struct rt_sigframe *)esp, &sigNo); 925 //.. 926 //.. VG_TRACK( die_mem_stack_signal, esp, size ); 927 //.. 928 //.. if (VG_(clo_trace_signals)) 929 //.. VG_(message)( 930 //.. Vg_DebugMsg, 931 //.. "VG_(signal_return) (thread %u): isRT=%d valid magic; EIP=%p", 932 //.. tid, isRT, tst->arch.vex.guest_EIP); 933 //.. 934 //.. /* tell the tools */ 935 //.. VG_TRACK( post_deliver_signal, tid, sigNo ); 936 } 937 938 #endif // defined(VGP_ppc32_linux) 939 940 /*--------------------------------------------------------------------*/ 941 /*--- end ---*/ 942 /*--------------------------------------------------------------------*/ 943