// Copyright 2009 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 ( "runtime/internal/atomic" "runtime/internal/sys" "unsafe" ) // For gccgo, while we still have C runtime code, use go:linkname to // rename some functions to themselves, so that the compiler will // export them. // //go:linkname gotraceback runtime.gotraceback //go:linkname args runtime.args //go:linkname goargs runtime.goargs //go:linkname check runtime.check //go:linkname goenvs_unix runtime.goenvs_unix //go:linkname parsedebugvars runtime.parsedebugvars //go:linkname timediv runtime.timediv // Keep a cached value to make gotraceback fast, // since we call it on every call to gentraceback. // The cached value is a uint32 in which the low bits // are the "crash" and "all" settings and the remaining // bits are the traceback value (0 off, 1 on, 2 include system). const ( tracebackCrash = 1 << iota tracebackAll tracebackShift = iota ) var traceback_cache uint32 = 2 << tracebackShift var traceback_env uint32 // gotraceback returns the current traceback settings. // // If level is 0, suppress all tracebacks. // If level is 1, show tracebacks, but exclude runtime frames. // If level is 2, show tracebacks including runtime frames. // If all is set, print all goroutine stacks. Otherwise, print just the current goroutine. // If crash is set, crash (core dump, etc) after tracebacking. // //go:nosplit func gotraceback() (level int32, all, crash bool) { _g_ := getg() all = _g_.m.throwing > 0 if _g_.m.traceback != 0 { level = int32(_g_.m.traceback) return } t := atomic.Load(&traceback_cache) crash = t&tracebackCrash != 0 all = all || t&tracebackAll != 0 level = int32(t >> tracebackShift) return } var ( argc int32 argv **byte ) // nosplit for use in linux startup sysargs //go:nosplit func argv_index(argv **byte, i int32) *byte { return *(**byte)(add(unsafe.Pointer(argv), uintptr(i)*sys.PtrSize)) } func args(c int32, v **byte) { argc = c argv = v sysargs(c, v) } func goargs() { if GOOS == "windows" { return } argslice = make([]string, argc) for i := int32(0); i < argc; i++ { argslice[i] = gostringnocopy(argv_index(argv, i)) } } func goenvs_unix() { // TODO(austin): ppc64 in dynamic linking mode doesn't // guarantee env[] will immediately follow argv. Might cause // problems. n := int32(0) for argv_index(argv, argc+1+n) != nil { n++ } envs = make([]string, n) for i := int32(0); i < n; i++ { envs[i] = gostring(argv_index(argv, argc+1+i)) } } func environ() []string { return envs } // TODO: These should be locals in testAtomic64, but we don't 8-byte // align stack variables on 386. var test_z64, test_x64 uint64 func testAtomic64() { test_z64 = 42 test_x64 = 0 // prefetcht0(uintptr(unsafe.Pointer(&test_z64))) // prefetcht1(uintptr(unsafe.Pointer(&test_z64))) // prefetcht2(uintptr(unsafe.Pointer(&test_z64))) // prefetchnta(uintptr(unsafe.Pointer(&test_z64))) if atomic.Cas64(&test_z64, test_x64, 1) { throw("cas64 failed") } if test_x64 != 0 { throw("cas64 failed") } test_x64 = 42 if !atomic.Cas64(&test_z64, test_x64, 1) { throw("cas64 failed") } if test_x64 != 42 || test_z64 != 1 { throw("cas64 failed") } if atomic.Load64(&test_z64) != 1 { throw("load64 failed") } atomic.Store64(&test_z64, (1<<40)+1) if atomic.Load64(&test_z64) != (1<<40)+1 { throw("store64 failed") } if atomic.Xadd64(&test_z64, (1<<40)+1) != (2<<40)+2 { throw("xadd64 failed") } if atomic.Load64(&test_z64) != (2<<40)+2 { throw("xadd64 failed") } if atomic.Xchg64(&test_z64, (3<<40)+3) != (2<<40)+2 { throw("xchg64 failed") } if atomic.Load64(&test_z64) != (3<<40)+3 { throw("xchg64 failed") } } func check() { // This doesn't currently work for gccgo. Because escape // analysis is not turned on by default, the code below that // takes the address of local variables causes memory // allocation, but this function is called before the memory // allocator has been initialized. return var ( a int8 b uint8 c int16 d uint16 e int32 f uint32 g int64 h uint64 i, i1 float32 j, j1 float64 k, k1 unsafe.Pointer l *uint16 m [4]byte ) type x1t struct { x uint8 } type y1t struct { x1 x1t y uint8 } var x1 x1t var y1 y1t if unsafe.Sizeof(a) != 1 { throw("bad a") } if unsafe.Sizeof(b) != 1 { throw("bad b") } if unsafe.Sizeof(c) != 2 { throw("bad c") } if unsafe.Sizeof(d) != 2 { throw("bad d") } if unsafe.Sizeof(e) != 4 { throw("bad e") } if unsafe.Sizeof(f) != 4 { throw("bad f") } if unsafe.Sizeof(g) != 8 { throw("bad g") } if unsafe.Sizeof(h) != 8 { throw("bad h") } if unsafe.Sizeof(i) != 4 { throw("bad i") } if unsafe.Sizeof(j) != 8 { throw("bad j") } if unsafe.Sizeof(k) != sys.PtrSize { throw("bad k") } if unsafe.Sizeof(l) != sys.PtrSize { throw("bad l") } if unsafe.Sizeof(x1) != 1 { throw("bad unsafe.Sizeof x1") } if unsafe.Offsetof(y1.y) != 1 { throw("bad offsetof y1.y") } if unsafe.Sizeof(y1) != 2 { throw("bad unsafe.Sizeof y1") } if timediv(12345*1000000000+54321, 1000000000, &e) != 12345 || e != 54321 { throw("bad timediv") } var z uint32 z = 1 if !atomic.Cas(&z, 1, 2) { throw("cas1") } if z != 2 { throw("cas2") } z = 4 if atomic.Cas(&z, 5, 6) { throw("cas3") } if z != 4 { throw("cas4") } z = 0xffffffff if !atomic.Cas(&z, 0xffffffff, 0xfffffffe) { throw("cas5") } if z != 0xfffffffe { throw("cas6") } k = unsafe.Pointer(uintptr(0xfedcb123)) if sys.PtrSize == 8 { k = unsafe.Pointer(uintptr(k) << 10) } if casp(&k, nil, nil) { throw("casp1") } k1 = add(k, 1) if !casp(&k, k, k1) { throw("casp2") } if k != k1 { throw("casp3") } m = [4]byte{1, 1, 1, 1} atomic.Or8(&m[1], 0xf0) if m[0] != 1 || m[1] != 0xf1 || m[2] != 1 || m[3] != 1 { throw("atomicor8") } m = [4]byte{0xff, 0xff, 0xff, 0xff} atomic.And8(&m[1], 0x1) if m[0] != 0xff || m[1] != 0x1 || m[2] != 0xff || m[3] != 0xff { throw("atomicand8") } *(*uint64)(unsafe.Pointer(&j)) = ^uint64(0) if j == j { throw("float64nan") } if !(j != j) { throw("float64nan1") } *(*uint64)(unsafe.Pointer(&j1)) = ^uint64(1) if j == j1 { throw("float64nan2") } if !(j != j1) { throw("float64nan3") } *(*uint32)(unsafe.Pointer(&i)) = ^uint32(0) if i == i { throw("float32nan") } if i == i { throw("float32nan1") } *(*uint32)(unsafe.Pointer(&i1)) = ^uint32(1) if i == i1 { throw("float32nan2") } if i == i1 { throw("float32nan3") } testAtomic64() // if _FixedStack != round2(_FixedStack) { // throw("FixedStack is not power-of-2") // } if !checkASM() { throw("assembly checks failed") } } type dbgVar struct { name string value *int32 } // Holds variables parsed from GODEBUG env var, // except for "memprofilerate" since there is an // existing int var for that value, which may // already have an initial value. // For gccgo we use a named type so that the C code can see the // definition. type debugVars struct { allocfreetrace int32 cgocheck int32 efence int32 gccheckmark int32 gcpacertrace int32 gcshrinkstackoff int32 gcstackbarrieroff int32 gcstackbarrierall int32 gcrescanstacks int32 gcstoptheworld int32 gctrace int32 invalidptr int32 sbrk int32 scavenge int32 scheddetail int32 schedtrace int32 wbshadow int32 } var debug debugVars // For gccgo's C code. //extern runtime_setdebug func runtime_setdebug(*debugVars) var dbgvars = []dbgVar{ {"allocfreetrace", &debug.allocfreetrace}, {"cgocheck", &debug.cgocheck}, {"efence", &debug.efence}, {"gccheckmark", &debug.gccheckmark}, {"gcpacertrace", &debug.gcpacertrace}, {"gcshrinkstackoff", &debug.gcshrinkstackoff}, {"gcstackbarrieroff", &debug.gcstackbarrieroff}, {"gcstackbarrierall", &debug.gcstackbarrierall}, {"gcrescanstacks", &debug.gcrescanstacks}, {"gcstoptheworld", &debug.gcstoptheworld}, {"gctrace", &debug.gctrace}, {"invalidptr", &debug.invalidptr}, {"sbrk", &debug.sbrk}, {"scavenge", &debug.scavenge}, {"scheddetail", &debug.scheddetail}, {"schedtrace", &debug.schedtrace}, {"wbshadow", &debug.wbshadow}, } func parsedebugvars() { // defaults debug.cgocheck = 1 debug.invalidptr = 1 for p := gogetenv("GODEBUG"); p != ""; { field := "" i := index(p, ",") if i < 0 { field, p = p, "" } else { field, p = p[:i], p[i+1:] } i = index(field, "=") if i < 0 { continue } key, value := field[:i], field[i+1:] // Update MemProfileRate directly here since it // is int, not int32, and should only be updated // if specified in GODEBUG. if key == "memprofilerate" { if n, ok := atoi(value); ok { MemProfileRate = n } } else { for _, v := range dbgvars { if v.name == key { if n, ok := atoi32(value); ok { *v.value = n } } } } } setTraceback(gogetenv("GOTRACEBACK")) traceback_env = traceback_cache if debug.gcrescanstacks == 0 { // Without rescanning, there's no need for stack // barriers. debug.gcstackbarrieroff = 1 debug.gcstackbarrierall = 0 } // if debug.gcstackbarrierall > 0 { // firstStackBarrierOffset = 0 // } // For cgocheck > 1, we turn on the write barrier at all times // and check all pointer writes. if debug.cgocheck > 1 { writeBarrier.cgo = true writeBarrier.enabled = true } // Tell the C code what the value is. runtime_setdebug(&debug) } //go:linkname setTraceback runtime_debug.SetTraceback func setTraceback(level string) { var t uint32 switch level { case "none": t = 0 case "single", "": t = 1 << tracebackShift case "all": t = 1<= 0; bit-- { if v >= int64(div)<= int64(div) { if rem != nil { *rem = 0 } return 0x7fffffff } if rem != nil { *rem = int32(v) } return res } // Helpers for Go. Must be NOSPLIT, must only call NOSPLIT functions, and must not block. //go:nosplit func acquirem() *m { _g_ := getg() _g_.m.locks++ return _g_.m } //go:nosplit func releasem(mp *m) { // _g_ := getg() mp.locks-- // if mp.locks == 0 && _g_.preempt { // // restore the preemption request in case we've cleared it in newstack // _g_.stackguard0 = stackPreempt // } } //go:nosplit func gomcache() *mcache { return getg().m.mcache }