// Copyright 2012 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. // +build race // Public race detection API, present iff build with -race. package runtime import ( "unsafe" ) func RaceRead(addr unsafe.Pointer) func RaceWrite(addr unsafe.Pointer) func RaceReadRange(addr unsafe.Pointer, len int) func RaceWriteRange(addr unsafe.Pointer, len int) func RaceSemacquire(s *uint32) func RaceSemrelease(s *uint32) // private interface for the runtime const raceenabled = true // For all functions accepting callerpc and pc, // callerpc is a return PC of the function that calls this function, // pc is start PC of the function that calls this function. func raceReadObjectPC(t *_type, addr unsafe.Pointer, callerpc, pc uintptr) { kind := t.kind & kindMask if kind == kindArray || kind == kindStruct { // for composite objects we have to read every address // because a write might happen to any subobject. racereadrangepc(addr, t.size, callerpc, pc) } else { // for non-composite objects we can read just the start // address, as any write must write the first byte. racereadpc(addr, callerpc, pc) } } func raceWriteObjectPC(t *_type, addr unsafe.Pointer, callerpc, pc uintptr) { kind := t.kind & kindMask if kind == kindArray || kind == kindStruct { // for composite objects we have to write every address // because a write might happen to any subobject. racewriterangepc(addr, t.size, callerpc, pc) } else { // for non-composite objects we can write just the start // address, as any write must write the first byte. racewritepc(addr, callerpc, pc) } } //go:noescape func racereadpc(addr unsafe.Pointer, callpc, pc uintptr) //go:noescape func racewritepc(addr unsafe.Pointer, callpc, pc uintptr) type symbolizeContext struct { pc uintptr fn *byte file *byte line uintptr off uintptr res uintptr } var qq = [...]byte{'?', '?', 0} var dash = [...]byte{'-', 0} // Callback from C into Go, runs on g0. func racesymbolize(ctx *symbolizeContext) { f := findfunc(ctx.pc) if f == nil { ctx.fn = &qq[0] ctx.file = &dash[0] ctx.line = 0 ctx.off = ctx.pc ctx.res = 1 return } ctx.fn = cfuncname(f) file, line := funcline(f, ctx.pc) ctx.line = uintptr(line) ctx.file = &bytes(file)[0] // assume NUL-terminated ctx.off = ctx.pc - f.entry ctx.res = 1 return } // Race runtime functions called via runtime·racecall. //go:linkname __tsan_init __tsan_init var __tsan_init byte //go:linkname __tsan_fini __tsan_fini var __tsan_fini byte //go:linkname __tsan_map_shadow __tsan_map_shadow var __tsan_map_shadow byte //go:linkname __tsan_finalizer_goroutine __tsan_finalizer_goroutine var __tsan_finalizer_goroutine byte //go:linkname __tsan_go_start __tsan_go_start var __tsan_go_start byte //go:linkname __tsan_go_end __tsan_go_end var __tsan_go_end byte //go:linkname __tsan_malloc __tsan_malloc var __tsan_malloc byte //go:linkname __tsan_acquire __tsan_acquire var __tsan_acquire byte //go:linkname __tsan_release __tsan_release var __tsan_release byte //go:linkname __tsan_release_merge __tsan_release_merge var __tsan_release_merge byte //go:linkname __tsan_go_ignore_sync_begin __tsan_go_ignore_sync_begin var __tsan_go_ignore_sync_begin byte //go:linkname __tsan_go_ignore_sync_end __tsan_go_ignore_sync_end var __tsan_go_ignore_sync_end byte // Mimic what cmd/cgo would do. //go:cgo_import_static __tsan_init //go:cgo_import_static __tsan_fini //go:cgo_import_static __tsan_map_shadow //go:cgo_import_static __tsan_finalizer_goroutine //go:cgo_import_static __tsan_go_start //go:cgo_import_static __tsan_go_end //go:cgo_import_static __tsan_malloc //go:cgo_import_static __tsan_acquire //go:cgo_import_static __tsan_release //go:cgo_import_static __tsan_release_merge //go:cgo_import_static __tsan_go_ignore_sync_begin //go:cgo_import_static __tsan_go_ignore_sync_end // These are called from race_amd64.s. //go:cgo_import_static __tsan_read //go:cgo_import_static __tsan_read_pc //go:cgo_import_static __tsan_read_range //go:cgo_import_static __tsan_write //go:cgo_import_static __tsan_write_pc //go:cgo_import_static __tsan_write_range //go:cgo_import_static __tsan_func_enter //go:cgo_import_static __tsan_func_exit //go:cgo_import_static __tsan_go_atomic32_load //go:cgo_import_static __tsan_go_atomic64_load //go:cgo_import_static __tsan_go_atomic32_store //go:cgo_import_static __tsan_go_atomic64_store //go:cgo_import_static __tsan_go_atomic32_exchange //go:cgo_import_static __tsan_go_atomic64_exchange //go:cgo_import_static __tsan_go_atomic32_fetch_add //go:cgo_import_static __tsan_go_atomic64_fetch_add //go:cgo_import_static __tsan_go_atomic32_compare_exchange //go:cgo_import_static __tsan_go_atomic64_compare_exchange // start/end of global data (data+bss). var racedatastart uintptr var racedataend uintptr // start/end of heap for race_amd64.s var racearenastart uintptr var racearenaend uintptr func racefuncenter(uintptr) func racefuncexit() func racereadrangepc1(uintptr, uintptr, uintptr) func racewriterangepc1(uintptr, uintptr, uintptr) func racesymbolizethunk(uintptr) // racecall allows calling an arbitrary function f from C race runtime // with up to 4 uintptr arguments. func racecall(*byte, uintptr, uintptr, uintptr, uintptr) // checks if the address has shadow (i.e. heap or data/bss) //go:nosplit func isvalidaddr(addr unsafe.Pointer) bool { return racearenastart <= uintptr(addr) && uintptr(addr) < racearenaend || racedatastart <= uintptr(addr) && uintptr(addr) < racedataend } //go:nosplit func raceinit() uintptr { // cgo is required to initialize libc, which is used by race runtime if !iscgo { throw("raceinit: race build must use cgo") } var racectx uintptr racecall(&__tsan_init, uintptr(unsafe.Pointer(&racectx)), funcPC(racesymbolizethunk), 0, 0) // Round data segment to page boundaries, because it's used in mmap(). start := ^uintptr(0) end := uintptr(0) if start > firstmoduledata.noptrdata { start = firstmoduledata.noptrdata } if start > firstmoduledata.data { start = firstmoduledata.data } if start > firstmoduledata.noptrbss { start = firstmoduledata.noptrbss } if start > firstmoduledata.bss { start = firstmoduledata.bss } if end < firstmoduledata.enoptrdata { end = firstmoduledata.enoptrdata } if end < firstmoduledata.edata { end = firstmoduledata.edata } if end < firstmoduledata.enoptrbss { end = firstmoduledata.enoptrbss } if end < firstmoduledata.ebss { end = firstmoduledata.ebss } size := round(end-start, _PageSize) racecall(&__tsan_map_shadow, start, size, 0, 0) racedatastart = start racedataend = start + size return racectx } //go:nosplit func racefini() { racecall(&__tsan_fini, 0, 0, 0, 0) } //go:nosplit func racemapshadow(addr unsafe.Pointer, size uintptr) { if racearenastart == 0 { racearenastart = uintptr(addr) } if racearenaend < uintptr(addr)+size { racearenaend = uintptr(addr) + size } racecall(&__tsan_map_shadow, uintptr(addr), size, 0, 0) } //go:nosplit func racemalloc(p unsafe.Pointer, sz uintptr) { racecall(&__tsan_malloc, uintptr(p), sz, 0, 0) } //go:nosplit func racegostart(pc uintptr) uintptr { _g_ := getg() var spawng *g if _g_.m.curg != nil { spawng = _g_.m.curg } else { spawng = _g_ } var racectx uintptr racecall(&__tsan_go_start, spawng.racectx, uintptr(unsafe.Pointer(&racectx)), pc, 0) return racectx } //go:nosplit func racegoend() { racecall(&__tsan_go_end, getg().racectx, 0, 0, 0) } //go:nosplit func racewriterangepc(addr unsafe.Pointer, sz, callpc, pc uintptr) { _g_ := getg() if _g_ != _g_.m.curg { // The call is coming from manual instrumentation of Go code running on g0/gsignal. // Not interesting. return } if callpc != 0 { racefuncenter(callpc) } racewriterangepc1(uintptr(addr), sz, pc) if callpc != 0 { racefuncexit() } } //go:nosplit func racereadrangepc(addr unsafe.Pointer, sz, callpc, pc uintptr) { _g_ := getg() if _g_ != _g_.m.curg { // The call is coming from manual instrumentation of Go code running on g0/gsignal. // Not interesting. return } if callpc != 0 { racefuncenter(callpc) } racereadrangepc1(uintptr(addr), sz, pc) if callpc != 0 { racefuncexit() } } //go:nosplit func raceacquire(addr unsafe.Pointer) { raceacquireg(getg(), addr) } //go:nosplit func raceacquireg(gp *g, addr unsafe.Pointer) { if getg().raceignore != 0 || !isvalidaddr(addr) { return } racecall(&__tsan_acquire, gp.racectx, uintptr(addr), 0, 0) } //go:nosplit func racerelease(addr unsafe.Pointer) { _g_ := getg() if _g_.raceignore != 0 || !isvalidaddr(addr) { return } racereleaseg(_g_, addr) } //go:nosplit func racereleaseg(gp *g, addr unsafe.Pointer) { if getg().raceignore != 0 || !isvalidaddr(addr) { return } racecall(&__tsan_release, gp.racectx, uintptr(addr), 0, 0) } //go:nosplit func racereleasemerge(addr unsafe.Pointer) { racereleasemergeg(getg(), addr) } //go:nosplit func racereleasemergeg(gp *g, addr unsafe.Pointer) { if getg().raceignore != 0 || !isvalidaddr(addr) { return } racecall(&__tsan_release_merge, gp.racectx, uintptr(addr), 0, 0) } //go:nosplit func racefingo() { racecall(&__tsan_finalizer_goroutine, getg().racectx, 0, 0, 0) } //go:nosplit func RaceAcquire(addr unsafe.Pointer) { raceacquire(addr) } //go:nosplit func RaceRelease(addr unsafe.Pointer) { racerelease(addr) } //go:nosplit func RaceReleaseMerge(addr unsafe.Pointer) { racereleasemerge(addr) } //go:nosplit // RaceDisable disables handling of race events in the current goroutine. func RaceDisable() { _g_ := getg() if _g_.raceignore == 0 { racecall(&__tsan_go_ignore_sync_begin, _g_.racectx, 0, 0, 0) } _g_.raceignore++ } //go:nosplit // RaceEnable re-enables handling of race events in the current goroutine. func RaceEnable() { _g_ := getg() _g_.raceignore-- if _g_.raceignore == 0 { racecall(&__tsan_go_ignore_sync_end, _g_.racectx, 0, 0, 0) } }