github.com/MerlinKodo/gvisor@v0.0.0-20231110090155-957f62ecf90e/pkg/abi/linux/signal.go (about) 1 // Copyright 2018 The gVisor Authors. 2 // 3 // Licensed under the Apache License, Version 2.0 (the "License"); 4 // you may not use this file except in compliance with the License. 5 // You may obtain a copy of the License at 6 // 7 // http://www.apache.org/licenses/LICENSE-2.0 8 // 9 // Unless required by applicable law or agreed to in writing, software 10 // distributed under the License is distributed on an "AS IS" BASIS, 11 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 12 // See the License for the specific language governing permissions and 13 // limitations under the License. 14 15 package linux 16 17 import ( 18 "github.com/MerlinKodo/gvisor/pkg/bits" 19 "github.com/MerlinKodo/gvisor/pkg/hostarch" 20 ) 21 22 const ( 23 // SignalMaximum is the highest valid signal number. 24 SignalMaximum = 64 25 26 // FirstStdSignal is the lowest standard signal number. 27 FirstStdSignal = 1 28 29 // LastStdSignal is the highest standard signal number. 30 LastStdSignal = 31 31 32 // FirstRTSignal is the lowest real-time signal number. 33 // 34 // 32 (SIGCANCEL) and 33 (SIGSETXID) are used internally by glibc. 35 FirstRTSignal = 32 36 37 // LastRTSignal is the highest real-time signal number. 38 LastRTSignal = 64 39 40 // NumStdSignals is the number of standard signals. 41 NumStdSignals = LastStdSignal - FirstStdSignal + 1 42 43 // NumRTSignals is the number of realtime signals. 44 NumRTSignals = LastRTSignal - FirstRTSignal + 1 45 ) 46 47 // Signal is a signal number. 48 type Signal int 49 50 // IsValid returns true if s is a valid standard or realtime signal. (0 is not 51 // considered valid; interfaces special-casing signal number 0 should check for 52 // 0 first before asserting validity.) 53 func (s Signal) IsValid() bool { 54 return s > 0 && s <= SignalMaximum 55 } 56 57 // IsStandard returns true if s is a standard signal. 58 // 59 // Preconditions: s.IsValid(). 60 func (s Signal) IsStandard() bool { 61 return s <= LastStdSignal 62 } 63 64 // IsRealtime returns true if s is a realtime signal. 65 // 66 // Preconditions: s.IsValid(). 67 func (s Signal) IsRealtime() bool { 68 return s >= FirstRTSignal 69 } 70 71 // Index returns the index for signal s into arrays of both standard and 72 // realtime signals (e.g. signal masks). 73 // 74 // Preconditions: s.IsValid(). 75 func (s Signal) Index() int { 76 return int(s - 1) 77 } 78 79 // Signals. 80 const ( 81 SIGABRT = Signal(6) 82 SIGALRM = Signal(14) 83 SIGBUS = Signal(7) 84 SIGCHLD = Signal(17) 85 SIGCLD = Signal(17) 86 SIGCONT = Signal(18) 87 SIGFPE = Signal(8) 88 SIGHUP = Signal(1) 89 SIGILL = Signal(4) 90 SIGINT = Signal(2) 91 SIGIO = Signal(29) 92 SIGIOT = Signal(6) 93 SIGKILL = Signal(9) 94 SIGPIPE = Signal(13) 95 SIGPOLL = Signal(29) 96 SIGPROF = Signal(27) 97 SIGPWR = Signal(30) 98 SIGQUIT = Signal(3) 99 SIGSEGV = Signal(11) 100 SIGSTKFLT = Signal(16) 101 SIGSTOP = Signal(19) 102 SIGSYS = Signal(31) 103 SIGTERM = Signal(15) 104 SIGTRAP = Signal(5) 105 SIGTSTP = Signal(20) 106 SIGTTIN = Signal(21) 107 SIGTTOU = Signal(22) 108 SIGUNUSED = Signal(31) 109 SIGURG = Signal(23) 110 SIGUSR1 = Signal(10) 111 SIGUSR2 = Signal(12) 112 SIGVTALRM = Signal(26) 113 SIGWINCH = Signal(28) 114 SIGXCPU = Signal(24) 115 SIGXFSZ = Signal(25) 116 ) 117 118 // SignalSet is a signal mask with a bit corresponding to each signal. 119 // 120 // +marshal 121 type SignalSet uint64 122 123 // SignalSetSize is the size in bytes of a SignalSet. 124 const SignalSetSize = 8 125 126 // MakeSignalSet returns SignalSet with the bit corresponding to each of the 127 // given signals set. 128 func MakeSignalSet(sigs ...Signal) SignalSet { 129 indices := make([]int, len(sigs)) 130 for i, sig := range sigs { 131 indices[i] = sig.Index() 132 } 133 return SignalSet(bits.Mask64(indices...)) 134 } 135 136 // SignalSetOf returns a SignalSet with a single signal set. 137 func SignalSetOf(sig Signal) SignalSet { 138 return SignalSet(bits.MaskOf64(sig.Index())) 139 } 140 141 // ForEachSignal invokes f for each signal set in the given mask. 142 func ForEachSignal(mask SignalSet, f func(sig Signal)) { 143 bits.ForEachSetBit64(uint64(mask), func(i int) { 144 f(Signal(i + 1)) 145 }) 146 } 147 148 // 'how' values for rt_sigprocmask(2). 149 const ( 150 // SIG_BLOCK blocks the signals in the set. 151 SIG_BLOCK = 0 152 153 // SIG_UNBLOCK blocks the signals in the set. 154 SIG_UNBLOCK = 1 155 156 // SIG_SETMASK sets the signal mask to set. 157 SIG_SETMASK = 2 158 ) 159 160 // Signal actions for rt_sigaction(2), from uapi/asm-generic/signal-defs.h. 161 const ( 162 // SIG_DFL performs the default action. 163 SIG_DFL = 0 164 165 // SIG_IGN ignores the signal. 166 SIG_IGN = 1 167 ) 168 169 // Signal action flags for rt_sigaction(2), from uapi/asm-generic/signal.h. 170 const ( 171 SA_NOCLDSTOP = 0x00000001 172 SA_NOCLDWAIT = 0x00000002 173 SA_SIGINFO = 0x00000004 174 SA_RESTORER = 0x04000000 175 SA_ONSTACK = 0x08000000 176 SA_RESTART = 0x10000000 177 SA_NODEFER = 0x40000000 178 SA_RESETHAND = 0x80000000 179 SA_NOMASK = SA_NODEFER 180 SA_ONESHOT = SA_RESETHAND 181 ) 182 183 // Signal stack flags for signalstack(2), from include/uapi/linux/signal.h. 184 const ( 185 SS_ONSTACK = 1 186 SS_DISABLE = 2 187 ) 188 189 // SIGPOLL si_codes. 190 const ( 191 // SI_POLL is defined as __SI_POLL in Linux 2.6. 192 SI_POLL = 2 << 16 193 194 // POLL_IN indicates that data input available. 195 POLL_IN = SI_POLL | 1 196 197 // POLL_OUT indicates that output buffers available. 198 POLL_OUT = SI_POLL | 2 199 200 // POLL_MSG indicates that an input message available. 201 POLL_MSG = SI_POLL | 3 202 203 // POLL_ERR indicates that there was an i/o error. 204 POLL_ERR = SI_POLL | 4 205 206 // POLL_PRI indicates that a high priority input available. 207 POLL_PRI = SI_POLL | 5 208 209 // POLL_HUP indicates that a device disconnected. 210 POLL_HUP = SI_POLL | 6 211 ) 212 213 // Possible values for si_code. 214 const ( 215 // SI_USER is sent by kill, sigsend, raise. 216 SI_USER = 0 217 218 // SI_KERNEL is sent by the kernel from somewhere. 219 SI_KERNEL = 0x80 220 221 // SI_QUEUE is sent by sigqueue. 222 SI_QUEUE = -1 223 224 // SI_TIMER is sent by timer expiration. 225 SI_TIMER = -2 226 227 // SI_MESGQ is sent by real time mesq state change. 228 SI_MESGQ = -3 229 230 // SI_ASYNCIO is sent by AIO completion. 231 SI_ASYNCIO = -4 232 233 // SI_SIGIO is sent by queued SIGIO. 234 SI_SIGIO = -5 235 236 // SI_TKILL is sent by tkill system call. 237 SI_TKILL = -6 238 239 // SI_DETHREAD is sent by execve() killing subsidiary threads. 240 SI_DETHREAD = -7 241 242 // SI_ASYNCNL is sent by glibc async name lookup completion. 243 SI_ASYNCNL = -60 244 ) 245 246 // CLD_* codes are only meaningful for SIGCHLD. 247 const ( 248 // CLD_EXITED indicates that a task exited. 249 CLD_EXITED = 1 250 251 // CLD_KILLED indicates that a task was killed by a signal. 252 CLD_KILLED = 2 253 254 // CLD_DUMPED indicates that a task was killed by a signal and then dumped 255 // core. 256 CLD_DUMPED = 3 257 258 // CLD_TRAPPED indicates that a task was stopped by ptrace. 259 CLD_TRAPPED = 4 260 261 // CLD_STOPPED indicates that a thread group completed a group stop. 262 CLD_STOPPED = 5 263 264 // CLD_CONTINUED indicates that a group-stopped thread group was continued. 265 CLD_CONTINUED = 6 266 ) 267 268 // SYS_* codes are only meaningful for SIGSYS. 269 const ( 270 // SYS_SECCOMP indicates that a signal originates from seccomp. 271 SYS_SECCOMP = 1 272 ) 273 274 // Possible values for Sigevent.Notify, aka struct sigevent::sigev_notify. 275 const ( 276 SIGEV_SIGNAL = 0 277 SIGEV_NONE = 1 278 SIGEV_THREAD = 2 279 SIGEV_THREAD_ID = 4 280 ) 281 282 // Sigevent represents struct sigevent. 283 // 284 // +marshal 285 type Sigevent struct { 286 Value uint64 // union sigval {int, void*} 287 Signo int32 288 Notify int32 289 290 // struct sigevent here contains 48-byte union _sigev_un. However, only 291 // member _tid is significant to the kernel. 292 Tid int32 293 UnRemainder [44]byte 294 } 295 296 // SigAction represents struct sigaction. 297 // 298 // +marshal 299 // +stateify savable 300 type SigAction struct { 301 Handler uint64 302 Flags uint64 303 Restorer uint64 304 Mask SignalSet 305 } 306 307 // SignalStack represents information about a user stack, and is equivalent to 308 // stack_t. 309 // 310 // +marshal 311 // +stateify savable 312 type SignalStack struct { 313 Addr uint64 314 Flags uint32 315 _ uint32 316 Size uint64 317 } 318 319 // Contains checks if the stack pointer is within this stack. 320 func (s *SignalStack) Contains(sp hostarch.Addr) bool { 321 return hostarch.Addr(s.Addr) < sp && sp <= hostarch.Addr(s.Addr+s.Size) 322 } 323 324 // Top returns the stack's top address. 325 func (s *SignalStack) Top() hostarch.Addr { 326 return hostarch.Addr(s.Addr + s.Size) 327 } 328 329 // IsEnabled returns true iff this signal stack is marked as enabled. 330 func (s *SignalStack) IsEnabled() bool { 331 return s.Flags&SS_DISABLE == 0 332 } 333 334 // SignalInfo represents information about a signal being delivered, and is 335 // equivalent to struct siginfo in linux kernel(linux/include/uapi/asm-generic/siginfo.h). 336 // 337 // +marshal 338 // +stateify savable 339 type SignalInfo struct { 340 Signo int32 // Signal number 341 Errno int32 // Errno value 342 Code int32 // Signal code 343 _ uint32 344 345 // struct siginfo::_sifields is a union. In SignalInfo, fields in the union 346 // are accessed through methods. 347 // 348 // For reference, here is the definition of _sifields: (_sigfault._trapno, 349 // which does not exist on x86, omitted for clarity) 350 // 351 // union { 352 // int _pad[SI_PAD_SIZE]; 353 // 354 // /* kill() */ 355 // struct { 356 // __kernel_pid_t _pid; /* sender's pid */ 357 // __ARCH_SI_UID_T _uid; /* sender's uid */ 358 // } _kill; 359 // 360 // /* POSIX.1b timers */ 361 // struct { 362 // __kernel_timer_t _tid; /* timer id */ 363 // int _overrun; /* overrun count */ 364 // char _pad[sizeof( __ARCH_SI_UID_T) - sizeof(int)]; 365 // sigval_t _sigval; /* same as below */ 366 // int _sys_private; /* not to be passed to user */ 367 // } _timer; 368 // 369 // /* POSIX.1b signals */ 370 // struct { 371 // __kernel_pid_t _pid; /* sender's pid */ 372 // __ARCH_SI_UID_T _uid; /* sender's uid */ 373 // sigval_t _sigval; 374 // } _rt; 375 // 376 // /* SIGCHLD */ 377 // struct { 378 // __kernel_pid_t _pid; /* which child */ 379 // __ARCH_SI_UID_T _uid; /* sender's uid */ 380 // int _status; /* exit code */ 381 // __ARCH_SI_CLOCK_T _utime; 382 // __ARCH_SI_CLOCK_T _stime; 383 // } _sigchld; 384 // 385 // /* SIGILL, SIGFPE, SIGSEGV, SIGBUS */ 386 // struct { 387 // void *_addr; /* faulting insn/memory ref. */ 388 // short _addr_lsb; /* LSB of the reported address */ 389 // } _sigfault; 390 // 391 // /* SIGPOLL */ 392 // struct { 393 // __ARCH_SI_BAND_T _band; /* POLL_IN, POLL_OUT, POLL_MSG */ 394 // int _fd; 395 // } _sigpoll; 396 // 397 // /* SIGSYS */ 398 // struct { 399 // void *_call_addr; /* calling user insn */ 400 // int _syscall; /* triggering system call number */ 401 // unsigned int _arch; /* AUDIT_ARCH_* of syscall */ 402 // } _sigsys; 403 // } _sifields; 404 // 405 // _sifields is padded so that the size of siginfo is SI_MAX_SIZE = 128 406 // bytes. 407 Fields [128 - 16]byte 408 } 409 410 // FixSignalCodeForUser fixes up si_code. 411 // 412 // The si_code we get from Linux may contain the kernel-specific code in the 413 // top 16 bits if it's positive (e.g., from ptrace). Linux's 414 // copy_siginfo_to_user does: 415 // err |= __put_user((short)from->si_code, &to->si_code); 416 // to mask out those bits and we need to do the same. 417 func (s *SignalInfo) FixSignalCodeForUser() { 418 if s.Code > 0 { 419 s.Code &= 0x0000ffff 420 } 421 } 422 423 // PID returns the si_pid field. 424 func (s *SignalInfo) PID() int32 { 425 return int32(hostarch.ByteOrder.Uint32(s.Fields[0:4])) 426 } 427 428 // SetPID mutates the si_pid field. 429 func (s *SignalInfo) SetPID(val int32) { 430 hostarch.ByteOrder.PutUint32(s.Fields[0:4], uint32(val)) 431 } 432 433 // UID returns the si_uid field. 434 func (s *SignalInfo) UID() int32 { 435 return int32(hostarch.ByteOrder.Uint32(s.Fields[4:8])) 436 } 437 438 // SetUID mutates the si_uid field. 439 func (s *SignalInfo) SetUID(val int32) { 440 hostarch.ByteOrder.PutUint32(s.Fields[4:8], uint32(val)) 441 } 442 443 // Sigval returns the sigval field, which is aliased to both si_int and si_ptr. 444 func (s *SignalInfo) Sigval() uint64 { 445 return hostarch.ByteOrder.Uint64(s.Fields[8:16]) 446 } 447 448 // SetSigval mutates the sigval field. 449 func (s *SignalInfo) SetSigval(val uint64) { 450 hostarch.ByteOrder.PutUint64(s.Fields[8:16], val) 451 } 452 453 // TimerID returns the si_timerid field. 454 func (s *SignalInfo) TimerID() TimerID { 455 return TimerID(hostarch.ByteOrder.Uint32(s.Fields[0:4])) 456 } 457 458 // SetTimerID sets the si_timerid field. 459 func (s *SignalInfo) SetTimerID(val TimerID) { 460 hostarch.ByteOrder.PutUint32(s.Fields[0:4], uint32(val)) 461 } 462 463 // Overrun returns the si_overrun field. 464 func (s *SignalInfo) Overrun() int32 { 465 return int32(hostarch.ByteOrder.Uint32(s.Fields[4:8])) 466 } 467 468 // SetOverrun sets the si_overrun field. 469 func (s *SignalInfo) SetOverrun(val int32) { 470 hostarch.ByteOrder.PutUint32(s.Fields[4:8], uint32(val)) 471 } 472 473 // Addr returns the si_addr field. 474 func (s *SignalInfo) Addr() uint64 { 475 return hostarch.ByteOrder.Uint64(s.Fields[0:8]) 476 } 477 478 // SetAddr sets the si_addr field. 479 func (s *SignalInfo) SetAddr(val uint64) { 480 hostarch.ByteOrder.PutUint64(s.Fields[0:8], val) 481 } 482 483 // Status returns the si_status field. 484 func (s *SignalInfo) Status() int32 { 485 return int32(hostarch.ByteOrder.Uint32(s.Fields[8:12])) 486 } 487 488 // SetStatus mutates the si_status field. 489 func (s *SignalInfo) SetStatus(val int32) { 490 hostarch.ByteOrder.PutUint32(s.Fields[8:12], uint32(val)) 491 } 492 493 // CallAddr returns the si_call_addr field. 494 func (s *SignalInfo) CallAddr() uint64 { 495 return hostarch.ByteOrder.Uint64(s.Fields[0:8]) 496 } 497 498 // SetCallAddr mutates the si_call_addr field. 499 func (s *SignalInfo) SetCallAddr(val uint64) { 500 hostarch.ByteOrder.PutUint64(s.Fields[0:8], val) 501 } 502 503 // Syscall returns the si_syscall field. 504 func (s *SignalInfo) Syscall() int32 { 505 return int32(hostarch.ByteOrder.Uint32(s.Fields[8:12])) 506 } 507 508 // SetSyscall mutates the si_syscall field. 509 func (s *SignalInfo) SetSyscall(val int32) { 510 hostarch.ByteOrder.PutUint32(s.Fields[8:12], uint32(val)) 511 } 512 513 // Arch returns the si_arch field. 514 func (s *SignalInfo) Arch() uint32 { 515 return hostarch.ByteOrder.Uint32(s.Fields[12:16]) 516 } 517 518 // SetArch mutates the si_arch field. 519 func (s *SignalInfo) SetArch(val uint32) { 520 hostarch.ByteOrder.PutUint32(s.Fields[12:16], val) 521 } 522 523 // Band returns the si_band field. 524 func (s *SignalInfo) Band() int64 { 525 return int64(hostarch.ByteOrder.Uint64(s.Fields[0:8])) 526 } 527 528 // SetBand mutates the si_band field. 529 func (s *SignalInfo) SetBand(val int64) { 530 // Note: this assumes the platform uses `long` as `__ARCH_SI_BAND_T`. 531 // On some platforms, which gVisor doesn't support, `__ARCH_SI_BAND_T` is 532 // `int`. See siginfo.h. 533 hostarch.ByteOrder.PutUint64(s.Fields[0:8], uint64(val)) 534 } 535 536 // FD returns the si_fd field. 537 func (s *SignalInfo) FD() uint32 { 538 return hostarch.ByteOrder.Uint32(s.Fields[8:12]) 539 } 540 541 // SetFD mutates the si_fd field. 542 func (s *SignalInfo) SetFD(val uint32) { 543 hostarch.ByteOrder.PutUint32(s.Fields[8:12], val) 544 }