| // 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. |
| |
| // Garbage collector: finalizers and block profiling. |
| |
| package runtime |
| |
| import ( |
| "internal/abi" |
| "internal/goarch" |
| "runtime/internal/atomic" |
| "unsafe" |
| ) |
| |
| // finblock is an array of finalizers to be executed. finblocks are |
| // arranged in a linked list for the finalizer queue. |
| // |
| // finblock is allocated from non-GC'd memory, so any heap pointers |
| // must be specially handled. GC currently assumes that the finalizer |
| // queue does not grow during marking (but it can shrink). |
| // |
| //go:notinheap |
| type finblock struct { |
| alllink *finblock |
| next *finblock |
| cnt uint32 |
| _ int32 |
| fin [(_FinBlockSize - 2*goarch.PtrSize - 2*4) / unsafe.Sizeof(finalizer{})]finalizer |
| } |
| |
| var finlock mutex // protects the following variables |
| var fing *g // goroutine that runs finalizers |
| var finq *finblock // list of finalizers that are to be executed |
| var finc *finblock // cache of free blocks |
| var finptrmask [_FinBlockSize / goarch.PtrSize / 8]byte |
| var fingwait bool |
| var fingwake bool |
| var allfin *finblock // list of all blocks |
| |
| // NOTE: Layout known to queuefinalizer. |
| type finalizer struct { |
| fn *funcval // function to call (may be a heap pointer) |
| arg unsafe.Pointer // ptr to object (may be a heap pointer) |
| nret uintptr // bytes of return values from fn |
| fint *_type // type of first argument of fn |
| ot *ptrtype // type of ptr to object (may be a heap pointer) |
| } |
| |
| var finalizer1 = [...]byte{ |
| // Each Finalizer is 5 words, ptr ptr INT ptr ptr (INT = uintptr here) |
| // Each byte describes 8 words. |
| // Need 8 Finalizers described by 5 bytes before pattern repeats: |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // ptr ptr INT ptr ptr |
| // aka |
| // |
| // ptr ptr INT ptr ptr ptr ptr INT |
| // ptr ptr ptr ptr INT ptr ptr ptr |
| // ptr INT ptr ptr ptr ptr INT ptr |
| // ptr ptr ptr INT ptr ptr ptr ptr |
| // INT ptr ptr ptr ptr INT ptr ptr |
| // |
| // Assumptions about Finalizer layout checked below. |
| 1<<0 | 1<<1 | 0<<2 | 1<<3 | 1<<4 | 1<<5 | 1<<6 | 0<<7, |
| 1<<0 | 1<<1 | 1<<2 | 1<<3 | 0<<4 | 1<<5 | 1<<6 | 1<<7, |
| 1<<0 | 0<<1 | 1<<2 | 1<<3 | 1<<4 | 1<<5 | 0<<6 | 1<<7, |
| 1<<0 | 1<<1 | 1<<2 | 0<<3 | 1<<4 | 1<<5 | 1<<6 | 1<<7, |
| 0<<0 | 1<<1 | 1<<2 | 1<<3 | 1<<4 | 0<<5 | 1<<6 | 1<<7, |
| } |
| |
| func queuefinalizer(p unsafe.Pointer, fn *funcval, nret uintptr, fint *_type, ot *ptrtype) { |
| if gcphase != _GCoff { |
| // Currently we assume that the finalizer queue won't |
| // grow during marking so we don't have to rescan it |
| // during mark termination. If we ever need to lift |
| // this assumption, we can do it by adding the |
| // necessary barriers to queuefinalizer (which it may |
| // have automatically). |
| throw("queuefinalizer during GC") |
| } |
| |
| lock(&finlock) |
| if finq == nil || finq.cnt == uint32(len(finq.fin)) { |
| if finc == nil { |
| finc = (*finblock)(persistentalloc(_FinBlockSize, 0, &memstats.gcMiscSys)) |
| finc.alllink = allfin |
| allfin = finc |
| if finptrmask[0] == 0 { |
| // Build pointer mask for Finalizer array in block. |
| // Check assumptions made in finalizer1 array above. |
| if (unsafe.Sizeof(finalizer{}) != 5*goarch.PtrSize || |
| unsafe.Offsetof(finalizer{}.fn) != 0 || |
| unsafe.Offsetof(finalizer{}.arg) != goarch.PtrSize || |
| unsafe.Offsetof(finalizer{}.nret) != 2*goarch.PtrSize || |
| unsafe.Offsetof(finalizer{}.fint) != 3*goarch.PtrSize || |
| unsafe.Offsetof(finalizer{}.ot) != 4*goarch.PtrSize) { |
| throw("finalizer out of sync") |
| } |
| for i := range finptrmask { |
| finptrmask[i] = finalizer1[i%len(finalizer1)] |
| } |
| } |
| } |
| block := finc |
| finc = block.next |
| block.next = finq |
| finq = block |
| } |
| f := &finq.fin[finq.cnt] |
| atomic.Xadd(&finq.cnt, +1) // Sync with markroots |
| f.fn = fn |
| f.nret = nret |
| f.fint = fint |
| f.ot = ot |
| f.arg = p |
| fingwake = true |
| unlock(&finlock) |
| } |
| |
| //go:nowritebarrier |
| func iterate_finq(callback func(*funcval, unsafe.Pointer, uintptr, *_type, *ptrtype)) { |
| for fb := allfin; fb != nil; fb = fb.alllink { |
| for i := uint32(0); i < fb.cnt; i++ { |
| f := &fb.fin[i] |
| callback(f.fn, f.arg, f.nret, f.fint, f.ot) |
| } |
| } |
| } |
| |
| func wakefing() *g { |
| var res *g |
| lock(&finlock) |
| if fingwait && fingwake { |
| fingwait = false |
| fingwake = false |
| res = fing |
| } |
| unlock(&finlock) |
| return res |
| } |
| |
| var ( |
| fingCreate uint32 |
| fingRunning bool |
| ) |
| |
| func createfing() { |
| // start the finalizer goroutine exactly once |
| if fingCreate == 0 && atomic.Cas(&fingCreate, 0, 1) { |
| go runfinq() |
| } |
| } |
| |
| // This is the goroutine that runs all of the finalizers |
| func runfinq() { |
| var ( |
| frame unsafe.Pointer |
| framecap uintptr |
| argRegs int |
| ) |
| |
| gp := getg() |
| lock(&finlock) |
| fing = gp |
| unlock(&finlock) |
| |
| for { |
| lock(&finlock) |
| fb := finq |
| finq = nil |
| if fb == nil { |
| fingwait = true |
| goparkunlock(&finlock, waitReasonFinalizerWait, traceEvGoBlock, 1) |
| continue |
| } |
| argRegs = intArgRegs |
| unlock(&finlock) |
| if raceenabled { |
| racefingo() |
| } |
| for fb != nil { |
| for i := fb.cnt; i > 0; i-- { |
| f := &fb.fin[i-1] |
| |
| var regs abi.RegArgs |
| // The args may be passed in registers or on stack. Even for |
| // the register case, we still need the spill slots. |
| // TODO: revisit if we remove spill slots. |
| // |
| // Unfortunately because we can have an arbitrary |
| // amount of returns and it would be complex to try and |
| // figure out how many of those can get passed in registers, |
| // just conservatively assume none of them do. |
| framesz := unsafe.Sizeof((any)(nil)) + f.nret |
| if framecap < framesz { |
| // The frame does not contain pointers interesting for GC, |
| // all not yet finalized objects are stored in finq. |
| // If we do not mark it as FlagNoScan, |
| // the last finalized object is not collected. |
| frame = mallocgc(framesz, nil, true) |
| framecap = framesz |
| } |
| |
| if f.fint == nil { |
| throw("missing type in runfinq") |
| } |
| r := frame |
| if argRegs > 0 { |
| r = unsafe.Pointer(®s.Ints) |
| } else { |
| // frame is effectively uninitialized |
| // memory. That means we have to clear |
| // it before writing to it to avoid |
| // confusing the write barrier. |
| *(*[2]uintptr)(frame) = [2]uintptr{} |
| } |
| switch f.fint.kind & kindMask { |
| case kindPtr: |
| // direct use of pointer |
| *(*unsafe.Pointer)(r) = f.arg |
| case kindInterface: |
| ityp := (*interfacetype)(unsafe.Pointer(f.fint)) |
| // set up with empty interface |
| (*eface)(r)._type = &f.ot.typ |
| (*eface)(r).data = f.arg |
| if len(ityp.mhdr) != 0 { |
| // convert to interface with methods |
| // this conversion is guaranteed to succeed - we checked in SetFinalizer |
| (*iface)(r).tab = assertE2I(ityp, (*eface)(r)._type) |
| } |
| default: |
| throw("bad kind in runfinq") |
| } |
| fingRunning = true |
| reflectcall(nil, unsafe.Pointer(f.fn), frame, uint32(framesz), uint32(framesz), uint32(framesz), ®s) |
| fingRunning = false |
| |
| // Drop finalizer queue heap references |
| // before hiding them from markroot. |
| // This also ensures these will be |
| // clear if we reuse the finalizer. |
| f.fn = nil |
| f.arg = nil |
| f.ot = nil |
| atomic.Store(&fb.cnt, i-1) |
| } |
| next := fb.next |
| lock(&finlock) |
| fb.next = finc |
| finc = fb |
| unlock(&finlock) |
| fb = next |
| } |
| } |
| } |
| |
| // SetFinalizer sets the finalizer associated with obj to the provided |
| // finalizer function. When the garbage collector finds an unreachable block |
| // with an associated finalizer, it clears the association and runs |
| // finalizer(obj) in a separate goroutine. This makes obj reachable again, |
| // but now without an associated finalizer. Assuming that SetFinalizer |
| // is not called again, the next time the garbage collector sees |
| // that obj is unreachable, it will free obj. |
| // |
| // SetFinalizer(obj, nil) clears any finalizer associated with obj. |
| // |
| // The argument obj must be a pointer to an object allocated by calling |
| // new, by taking the address of a composite literal, or by taking the |
| // address of a local variable. |
| // The argument finalizer must be a function that takes a single argument |
| // to which obj's type can be assigned, and can have arbitrary ignored return |
| // values. If either of these is not true, SetFinalizer may abort the |
| // program. |
| // |
| // Finalizers are run in dependency order: if A points at B, both have |
| // finalizers, and they are otherwise unreachable, only the finalizer |
| // for A runs; once A is freed, the finalizer for B can run. |
| // If a cyclic structure includes a block with a finalizer, that |
| // cycle is not guaranteed to be garbage collected and the finalizer |
| // is not guaranteed to run, because there is no ordering that |
| // respects the dependencies. |
| // |
| // The finalizer is scheduled to run at some arbitrary time after the |
| // program can no longer reach the object to which obj points. |
| // There is no guarantee that finalizers will run before a program exits, |
| // so typically they are useful only for releasing non-memory resources |
| // associated with an object during a long-running program. |
| // For example, an os.File object could use a finalizer to close the |
| // associated operating system file descriptor when a program discards |
| // an os.File without calling Close, but it would be a mistake |
| // to depend on a finalizer to flush an in-memory I/O buffer such as a |
| // bufio.Writer, because the buffer would not be flushed at program exit. |
| // |
| // It is not guaranteed that a finalizer will run if the size of *obj is |
| // zero bytes. |
| // |
| // It is not guaranteed that a finalizer will run for objects allocated |
| // in initializers for package-level variables. Such objects may be |
| // linker-allocated, not heap-allocated. |
| // |
| // A finalizer may run as soon as an object becomes unreachable. |
| // In order to use finalizers correctly, the program must ensure that |
| // the object is reachable until it is no longer required. |
| // Objects stored in global variables, or that can be found by tracing |
| // pointers from a global variable, are reachable. For other objects, |
| // pass the object to a call of the KeepAlive function to mark the |
| // last point in the function where the object must be reachable. |
| // |
| // For example, if p points to a struct, such as os.File, that contains |
| // a file descriptor d, and p has a finalizer that closes that file |
| // descriptor, and if the last use of p in a function is a call to |
| // syscall.Write(p.d, buf, size), then p may be unreachable as soon as |
| // the program enters syscall.Write. The finalizer may run at that moment, |
| // closing p.d, causing syscall.Write to fail because it is writing to |
| // a closed file descriptor (or, worse, to an entirely different |
| // file descriptor opened by a different goroutine). To avoid this problem, |
| // call KeepAlive(p) after the call to syscall.Write. |
| // |
| // A single goroutine runs all finalizers for a program, sequentially. |
| // If a finalizer must run for a long time, it should do so by starting |
| // a new goroutine. |
| // |
| // In the terminology of the Go memory model, a call |
| // SetFinalizer(x, f) “synchronizes before” the finalization call f(x). |
| // However, there is no guarantee that KeepAlive(x) or any other use of x |
| // “synchronizes before” f(x), so in general a finalizer should use a mutex |
| // or other synchronization mechanism if it needs to access mutable state in x. |
| // For example, consider a finalizer that inspects a mutable field in x |
| // that is modified from time to time in the main program before x |
| // becomes unreachable and the finalizer is invoked. |
| // The modifications in the main program and the inspection in the finalizer |
| // need to use appropriate synchronization, such as mutexes or atomic updates, |
| // to avoid read-write races. |
| func SetFinalizer(obj any, finalizer any) { |
| if debug.sbrk != 0 { |
| // debug.sbrk never frees memory, so no finalizers run |
| // (and we don't have the data structures to record them). |
| return |
| } |
| e := efaceOf(&obj) |
| etyp := e._type |
| if etyp == nil { |
| throw("runtime.SetFinalizer: first argument is nil") |
| } |
| if etyp.kind&kindMask != kindPtr { |
| throw("runtime.SetFinalizer: first argument is " + etyp.string() + ", not pointer") |
| } |
| ot := (*ptrtype)(unsafe.Pointer(etyp)) |
| if ot.elem == nil { |
| throw("nil elem type!") |
| } |
| |
| // find the containing object |
| base, _, _ := findObject(uintptr(e.data), 0, 0) |
| |
| if base == 0 { |
| // 0-length objects are okay. |
| if e.data == unsafe.Pointer(&zerobase) { |
| return |
| } |
| |
| // Global initializers might be linker-allocated. |
| // var Foo = &Object{} |
| // func main() { |
| // runtime.SetFinalizer(Foo, nil) |
| // } |
| // The relevant segments are: noptrdata, data, bss, noptrbss. |
| // We cannot assume they are in any order or even contiguous, |
| // due to external linking. |
| for datap := &firstmoduledata; datap != nil; datap = datap.next { |
| if datap.noptrdata <= uintptr(e.data) && uintptr(e.data) < datap.enoptrdata || |
| datap.data <= uintptr(e.data) && uintptr(e.data) < datap.edata || |
| datap.bss <= uintptr(e.data) && uintptr(e.data) < datap.ebss || |
| datap.noptrbss <= uintptr(e.data) && uintptr(e.data) < datap.enoptrbss { |
| return |
| } |
| } |
| throw("runtime.SetFinalizer: pointer not in allocated block") |
| } |
| |
| if uintptr(e.data) != base { |
| // As an implementation detail we allow to set finalizers for an inner byte |
| // of an object if it could come from tiny alloc (see mallocgc for details). |
| if ot.elem == nil || ot.elem.ptrdata != 0 || ot.elem.size >= maxTinySize { |
| throw("runtime.SetFinalizer: pointer not at beginning of allocated block") |
| } |
| } |
| |
| f := efaceOf(&finalizer) |
| ftyp := f._type |
| if ftyp == nil { |
| // switch to system stack and remove finalizer |
| systemstack(func() { |
| removefinalizer(e.data) |
| }) |
| return |
| } |
| |
| if ftyp.kind&kindMask != kindFunc { |
| throw("runtime.SetFinalizer: second argument is " + ftyp.string() + ", not a function") |
| } |
| ft := (*functype)(unsafe.Pointer(ftyp)) |
| if ft.dotdotdot() { |
| throw("runtime.SetFinalizer: cannot pass " + etyp.string() + " to finalizer " + ftyp.string() + " because dotdotdot") |
| } |
| if ft.inCount != 1 { |
| throw("runtime.SetFinalizer: cannot pass " + etyp.string() + " to finalizer " + ftyp.string()) |
| } |
| fint := ft.in()[0] |
| switch { |
| case fint == etyp: |
| // ok - same type |
| goto okarg |
| case fint.kind&kindMask == kindPtr: |
| if (fint.uncommon() == nil || etyp.uncommon() == nil) && (*ptrtype)(unsafe.Pointer(fint)).elem == ot.elem { |
| // ok - not same type, but both pointers, |
| // one or the other is unnamed, and same element type, so assignable. |
| goto okarg |
| } |
| case fint.kind&kindMask == kindInterface: |
| ityp := (*interfacetype)(unsafe.Pointer(fint)) |
| if len(ityp.mhdr) == 0 { |
| // ok - satisfies empty interface |
| goto okarg |
| } |
| if iface := assertE2I2(ityp, *efaceOf(&obj)); iface.tab != nil { |
| goto okarg |
| } |
| } |
| throw("runtime.SetFinalizer: cannot pass " + etyp.string() + " to finalizer " + ftyp.string()) |
| okarg: |
| // compute size needed for return parameters |
| nret := uintptr(0) |
| for _, t := range ft.out() { |
| nret = alignUp(nret, uintptr(t.align)) + uintptr(t.size) |
| } |
| nret = alignUp(nret, goarch.PtrSize) |
| |
| // make sure we have a finalizer goroutine |
| createfing() |
| |
| systemstack(func() { |
| if !addfinalizer(e.data, (*funcval)(f.data), nret, fint, ot) { |
| throw("runtime.SetFinalizer: finalizer already set") |
| } |
| }) |
| } |
| |
| // Mark KeepAlive as noinline so that it is easily detectable as an intrinsic. |
| // |
| //go:noinline |
| |
| // KeepAlive marks its argument as currently reachable. |
| // This ensures that the object is not freed, and its finalizer is not run, |
| // before the point in the program where KeepAlive is called. |
| // |
| // A very simplified example showing where KeepAlive is required: |
| // |
| // type File struct { d int } |
| // d, err := syscall.Open("/file/path", syscall.O_RDONLY, 0) |
| // // ... do something if err != nil ... |
| // p := &File{d} |
| // runtime.SetFinalizer(p, func(p *File) { syscall.Close(p.d) }) |
| // var buf [10]byte |
| // n, err := syscall.Read(p.d, buf[:]) |
| // // Ensure p is not finalized until Read returns. |
| // runtime.KeepAlive(p) |
| // // No more uses of p after this point. |
| // |
| // Without the KeepAlive call, the finalizer could run at the start of |
| // syscall.Read, closing the file descriptor before syscall.Read makes |
| // the actual system call. |
| // |
| // Note: KeepAlive should only be used to prevent finalizers from |
| // running prematurely. In particular, when used with unsafe.Pointer, |
| // the rules for valid uses of unsafe.Pointer still apply. |
| func KeepAlive(x any) { |
| // Introduce a use of x that the compiler can't eliminate. |
| // This makes sure x is alive on entry. We need x to be alive |
| // on entry for "defer runtime.KeepAlive(x)"; see issue 21402. |
| if cgoAlwaysFalse { |
| println(x) |
| } |
| } |