// Copyright 2010 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package runtime import ( "internal/abi" "internal/runtime/atomic" "internal/stringslite" "unsafe" ) type mOS struct { waitsemacount uint32 notesig *int8 errstr *byte ignoreHangup bool } func closefd(fd int32) int32 //go:noescape func open(name *byte, mode, perm int32) int32 //go:noescape func pread(fd int32, buf unsafe.Pointer, nbytes int32, offset int64) int32 //go:noescape func pwrite(fd int32, buf unsafe.Pointer, nbytes int32, offset int64) int32 func seek(fd int32, offset int64, whence int32) int64 //go:noescape func exits(msg *byte) //go:noescape func brk_(addr unsafe.Pointer) int32 func sleep(ms int32) int32 func rfork(flags int32) int32 //go:noescape func plan9_semacquire(addr *uint32, block int32) int32 //go:noescape func plan9_tsemacquire(addr *uint32, ms int32) int32 //go:noescape func plan9_semrelease(addr *uint32, count int32) int32 //go:noescape func notify(fn unsafe.Pointer) int32 func noted(mode int32) int32 //go:noescape func nsec(*int64) int64 //go:noescape func sigtramp(ureg, note unsafe.Pointer) func setfpmasks() //go:noescape func tstart_plan9(newm *m) func errstr() string type _Plink uintptr func sigpanic() { gp := getg() if !canpanic() { throw("unexpected signal during runtime execution") } note := gostringnocopy((*byte)(unsafe.Pointer(gp.m.notesig))) switch gp.sig { case _SIGRFAULT, _SIGWFAULT: i := indexNoFloat(note, "addr=") if i >= 0 { i += 5 } else if i = indexNoFloat(note, "va="); i >= 0 { i += 3 } else { panicmem() } addr := note[i:] gp.sigcode1 = uintptr(atolwhex(addr)) if gp.sigcode1 < 0x1000 { panicmem() } if gp.paniconfault { panicmemAddr(gp.sigcode1) } if inUserArenaChunk(gp.sigcode1) { // We could check that the arena chunk is explicitly set to fault, // but the fact that we faulted on accessing it is enough to prove // that it is. print("accessed data from freed user arena ", hex(gp.sigcode1), "\n") } else { print("unexpected fault address ", hex(gp.sigcode1), "\n") } throw("fault") case _SIGTRAP: if gp.paniconfault { panicmem() } throw(note) case _SIGINTDIV: panicdivide() case _SIGFLOAT: panicfloat() default: panic(errorString(note)) } } // indexNoFloat is bytealg.IndexString but safe to use in a note // handler. func indexNoFloat(s, t string) int { if len(t) == 0 { return 0 } for i := 0; i < len(s); i++ { if s[i] == t[0] && stringslite.HasPrefix(s[i:], t) { return i } } return -1 } func atolwhex(p string) int64 { for stringslite.HasPrefix(p, " ") || stringslite.HasPrefix(p, "\t") { p = p[1:] } neg := false if stringslite.HasPrefix(p, "-") || stringslite.HasPrefix(p, "+") { neg = p[0] == '-' p = p[1:] for stringslite.HasPrefix(p, " ") || stringslite.HasPrefix(p, "\t") { p = p[1:] } } var n int64 switch { case stringslite.HasPrefix(p, "0x"), stringslite.HasPrefix(p, "0X"): p = p[2:] for ; len(p) > 0; p = p[1:] { if '0' <= p[0] && p[0] <= '9' { n = n*16 + int64(p[0]-'0') } else if 'a' <= p[0] && p[0] <= 'f' { n = n*16 + int64(p[0]-'a'+10) } else if 'A' <= p[0] && p[0] <= 'F' { n = n*16 + int64(p[0]-'A'+10) } else { break } } case stringslite.HasPrefix(p, "0"): for ; len(p) > 0 && '0' <= p[0] && p[0] <= '7'; p = p[1:] { n = n*8 + int64(p[0]-'0') } default: for ; len(p) > 0 && '0' <= p[0] && p[0] <= '9'; p = p[1:] { n = n*10 + int64(p[0]-'0') } } if neg { n = -n } return n } type sigset struct{} // Called to initialize a new m (including the bootstrap m). // Called on the parent thread (main thread in case of bootstrap), can allocate memory. func mpreinit(mp *m) { // Initialize stack and goroutine for note handling. mp.gsignal = malg(32 * 1024) mp.gsignal.m = mp mp.notesig = (*int8)(mallocgc(_ERRMAX, nil, true)) // Initialize stack for handling strings from the // errstr system call, as used in package syscall. mp.errstr = (*byte)(mallocgc(_ERRMAX, nil, true)) } func sigsave(p *sigset) { } func msigrestore(sigmask sigset) { } //go:nosplit //go:nowritebarrierrec func clearSignalHandlers() { } func sigblock(exiting bool) { } // Called to initialize a new m (including the bootstrap m). // Called on the new thread, cannot allocate memory. func minit() { if atomic.Load(&exiting) != 0 { exits(&emptystatus[0]) } // Mask all SSE floating-point exceptions // when running on the 64-bit kernel. setfpmasks() } // Called from dropm to undo the effect of an minit. func unminit() { } // Called from exitm, but not from drop, to undo the effect of thread-owned // resources in minit, semacreate, or elsewhere. Do not take locks after calling this. func mdestroy(mp *m) { } var sysstat = []byte("/dev/sysstat\x00") func getproccount() int32 { var buf [2048]byte fd := open(&sysstat[0], _OREAD, 0) if fd < 0 { return 1 } ncpu := int32(0) for { n := read(fd, unsafe.Pointer(&buf), int32(len(buf))) if n <= 0 { break } for i := int32(0); i < n; i++ { if buf[i] == '\n' { ncpu++ } } } closefd(fd) if ncpu == 0 { ncpu = 1 } return ncpu } var devswap = []byte("/dev/swap\x00") var pagesize = []byte(" pagesize\n") func getPageSize() uintptr { var buf [2048]byte var pos int fd := open(&devswap[0], _OREAD, 0) if fd < 0 { // There's not much we can do if /dev/swap doesn't // exist. However, nothing in the memory manager uses // this on Plan 9, so it also doesn't really matter. return minPhysPageSize } for pos < len(buf) { n := read(fd, unsafe.Pointer(&buf[pos]), int32(len(buf)-pos)) if n <= 0 { break } pos += int(n) } closefd(fd) text := buf[:pos] // Find " pagesize" line. bol := 0 for i, c := range text { if c == '\n' { bol = i + 1 } if bytesHasPrefix(text[i:], pagesize) { // Parse number at the beginning of this line. return uintptr(_atoi(text[bol:])) } } // Again, the page size doesn't really matter, so use a fallback. return minPhysPageSize } func bytesHasPrefix(s, prefix []byte) bool { if len(s) < len(prefix) { return false } for i, p := range prefix { if s[i] != p { return false } } return true } var pid = []byte("#c/pid\x00") func getpid() uint64 { var b [20]byte fd := open(&pid[0], 0, 0) if fd >= 0 { read(fd, unsafe.Pointer(&b), int32(len(b))) closefd(fd) } c := b[:] for c[0] == ' ' || c[0] == '\t' { c = c[1:] } return uint64(_atoi(c)) } func osinit() { physPageSize = getPageSize() initBloc() ncpu = getproccount() getg().m.procid = getpid() } //go:nosplit func crash() { notify(nil) *(*int)(nil) = 0 } //go:nosplit func readRandom(r []byte) int { return 0 } func initsig(preinit bool) { if !preinit { notify(unsafe.Pointer(abi.FuncPCABI0(sigtramp))) } } //go:nosplit func osyield() { sleep(0) } //go:nosplit func osyield_no_g() { osyield() } //go:nosplit func usleep(µs uint32) { ms := int32(µs / 1000) if ms == 0 { ms = 1 } sleep(ms) } //go:nosplit func usleep_no_g(usec uint32) { usleep(usec) } //go:nosplit func nanotime1() int64 { var scratch int64 ns := nsec(&scratch) // TODO(aram): remove hack after I fix _nsec in the pc64 kernel. if ns == 0 { return scratch } return ns } var goexits = []byte("go: exit ") var emptystatus = []byte("\x00") var exiting uint32 func goexitsall(status *byte) { var buf [_ERRMAX]byte if !atomic.Cas(&exiting, 0, 1) { return } getg().m.locks++ n := copy(buf[:], goexits) n = copy(buf[n:], gostringnocopy(status)) pid := getpid() for mp := (*m)(atomic.Loadp(unsafe.Pointer(&allm))); mp != nil; mp = mp.alllink { if mp.procid != 0 && mp.procid != pid { postnote(mp.procid, buf[:]) } } getg().m.locks-- } var procdir = []byte("/proc/") var notefile = []byte("/note\x00") func postnote(pid uint64, msg []byte) int { var buf [128]byte var tmp [32]byte n := copy(buf[:], procdir) n += copy(buf[n:], itoa(tmp[:], pid)) copy(buf[n:], notefile) fd := open(&buf[0], _OWRITE, 0) if fd < 0 { return -1 } len := findnull(&msg[0]) if write1(uintptr(fd), unsafe.Pointer(&msg[0]), int32(len)) != int32(len) { closefd(fd) return -1 } closefd(fd) return 0 } //go:nosplit func exit(e int32) { var status []byte if e == 0 { status = emptystatus } else { // build error string var tmp [32]byte sl := itoa(tmp[:len(tmp)-1], uint64(e)) // Don't append, rely on the existing data being zero. status = sl[:len(sl)+1] } goexitsall(&status[0]) exits(&status[0]) } // May run with m.p==nil, so write barriers are not allowed. // //go:nowritebarrier func newosproc(mp *m) { if false { print("newosproc mp=", mp, " ostk=", &mp, "\n") } pid := rfork(_RFPROC | _RFMEM | _RFNOWAIT) if pid < 0 { throw("newosproc: rfork failed") } if pid == 0 { tstart_plan9(mp) } } func exitThread(wait *atomic.Uint32) { // We should never reach exitThread on Plan 9 because we let // the OS clean up threads. throw("exitThread") } //go:nosplit func semacreate(mp *m) { } //go:nosplit func semasleep(ns int64) int { gp := getg() if ns >= 0 { ms := timediv(ns, 1000000, nil) if ms == 0 { ms = 1 } ret := plan9_tsemacquire(&gp.m.waitsemacount, ms) if ret == 1 { return 0 // success } return -1 // timeout or interrupted } for plan9_semacquire(&gp.m.waitsemacount, 1) < 0 { // interrupted; try again (c.f. lock_sema.go) } return 0 // success } //go:nosplit func semawakeup(mp *m) { plan9_semrelease(&mp.waitsemacount, 1) } //go:nosplit func read(fd int32, buf unsafe.Pointer, n int32) int32 { return pread(fd, buf, n, -1) } //go:nosplit func write1(fd uintptr, buf unsafe.Pointer, n int32) int32 { return pwrite(int32(fd), buf, n, -1) } var _badsignal = []byte("runtime: signal received on thread not created by Go.\n") // This runs on a foreign stack, without an m or a g. No stack split. // //go:nosplit func badsignal2() { pwrite(2, unsafe.Pointer(&_badsignal[0]), int32(len(_badsignal)), -1) exits(&_badsignal[0]) } func raisebadsignal(sig uint32) { badsignal2() } func _atoi(b []byte) int { n := 0 for len(b) > 0 && '0' <= b[0] && b[0] <= '9' { n = n*10 + int(b[0]) - '0' b = b[1:] } return n } func signame(sig uint32) string { if sig >= uint32(len(sigtable)) { return "" } return sigtable[sig].name } const preemptMSupported = false func preemptM(mp *m) { // Not currently supported. // // TODO: Use a note like we use signals on POSIX OSes }