package buffer import ( "context" "fmt" "gvisor.dev/gvisor/pkg/atomicbitops" "gvisor.dev/gvisor/pkg/refs" ) // enableLogging indicates whether reference-related events should be logged (with // stack traces). This is false by default and should only be set to true for // debugging purposes, as it can generate an extremely large amount of output // and drastically degrade performance. const chunkenableLogging = false // obj is used to customize logging. Note that we use a pointer to T so that // we do not copy the entire object when passed as a format parameter. var chunkobj *chunk // Refs implements refs.RefCounter. It keeps a reference count using atomic // operations and calls the destructor when the count reaches zero. // // NOTE: Do not introduce additional fields to the Refs struct. It is used by // many filesystem objects, and we want to keep it as small as possible (i.e., // the same size as using an int64 directly) to avoid taking up extra cache // space. In general, this template should not be extended at the cost of // performance. If it does not offer enough flexibility for a particular object // (example: b/187877947), we should implement the RefCounter/CheckedObject // interfaces manually. // // +stateify savable type chunkRefs struct { // refCount is composed of two fields: // // [32-bit speculative references]:[32-bit real references] // // Speculative references are used for TryIncRef, to avoid a CompareAndSwap // loop. See IncRef, DecRef and TryIncRef for details of how these fields are // used. refCount atomicbitops.Int64 } // InitRefs initializes r with one reference and, if enabled, activates leak // checking. func (r *chunkRefs) InitRefs() { r.refCount.RacyStore(1) refs.Register(r) } // RefType implements refs.CheckedObject.RefType. func (r *chunkRefs) RefType() string { return fmt.Sprintf("%T", chunkobj)[1:] } // LeakMessage implements refs.CheckedObject.LeakMessage. func (r *chunkRefs) LeakMessage() string { return fmt.Sprintf("[%s %p] reference count of %d instead of 0", r.RefType(), r, r.ReadRefs()) } // LogRefs implements refs.CheckedObject.LogRefs. func (r *chunkRefs) LogRefs() bool { return chunkenableLogging } // ReadRefs returns the current number of references. The returned count is // inherently racy and is unsafe to use without external synchronization. func (r *chunkRefs) ReadRefs() int64 { return r.refCount.Load() } // IncRef implements refs.RefCounter.IncRef. // //go:nosplit func (r *chunkRefs) IncRef() { v := r.refCount.Add(1) if chunkenableLogging { refs.LogIncRef(r, v) } if v <= 1 { panic(fmt.Sprintf("Incrementing non-positive count %p on %s", r, r.RefType())) } } // TryIncRef implements refs.TryRefCounter.TryIncRef. // // To do this safely without a loop, a speculative reference is first acquired // on the object. This allows multiple concurrent TryIncRef calls to distinguish // other TryIncRef calls from genuine references held. // //go:nosplit func (r *chunkRefs) TryIncRef() bool { const speculativeRef = 1 << 32 if v := r.refCount.Add(speculativeRef); int32(v) == 0 { r.refCount.Add(-speculativeRef) return false } v := r.refCount.Add(-speculativeRef + 1) if chunkenableLogging { refs.LogTryIncRef(r, v) } return true } // DecRef implements refs.RefCounter.DecRef. // // Note that speculative references are counted here. Since they were added // prior to real references reaching zero, they will successfully convert to // real references. In other words, we see speculative references only in the // following case: // // A: TryIncRef [speculative increase => sees non-negative references] // B: DecRef [real decrease] // A: TryIncRef [transform speculative to real] // //go:nosplit func (r *chunkRefs) DecRef(destroy func()) { v := r.refCount.Add(-1) if chunkenableLogging { refs.LogDecRef(r, v) } switch { case v < 0: panic(fmt.Sprintf("Decrementing non-positive ref count %p, owned by %s", r, r.RefType())) case v == 0: refs.Unregister(r) if destroy != nil { destroy() } } } func (r *chunkRefs) afterLoad(context.Context) { if r.ReadRefs() > 0 { refs.Register(r) } }