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package unix
import (
"runtime"
"sync/atomic"
"fmt"
"gvisor.dev/gvisor/pkg/log"
refs_vfs1 "gvisor.dev/gvisor/pkg/refs"
)
// ownerType 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 socketOpsCommonownerType *socketOpsCommon
// Refs implements refs.RefCounter. It keeps a reference count using atomic
// operations and calls the destructor when the count reaches zero.
//
// Note that the number of references is actually refCount + 1 so that a default
// zero-value Refs object contains one reference.
//
// TODO(gvisor.dev/issue/1486): Store stack traces when leak check is enabled in
// a map with 16-bit hashes, and store the hash in the top 16 bits of refCount.
// This will allow us to add stack trace information to the leak messages
// without growing the size of Refs.
//
// +stateify savable
type socketOpsCommonRefs 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 int64
}
func (r *socketOpsCommonRefs) finalize() {
var note string
switch refs_vfs1.GetLeakMode() {
case refs_vfs1.NoLeakChecking:
return
case refs_vfs1.UninitializedLeakChecking:
note = "(Leak checker uninitialized): "
}
if n := r.ReadRefs(); n != 0 {
log.Warningf("%sRefs %p owned by %T garbage collected with ref count of %d (want 0)", note, r, socketOpsCommonownerType, n)
}
}
// EnableLeakCheck checks for reference leaks when Refs gets garbage collected.
func (r *socketOpsCommonRefs) EnableLeakCheck() {
if refs_vfs1.GetLeakMode() != refs_vfs1.NoLeakChecking {
runtime.SetFinalizer(r, (*socketOpsCommonRefs).finalize)
}
}
// ReadRefs returns the current number of references. The returned count is
// inherently racy and is unsafe to use without external synchronization.
func (r *socketOpsCommonRefs) ReadRefs() int64 {
return atomic.LoadInt64(&r.refCount) + 1
}
// IncRef implements refs.RefCounter.IncRef.
//
//go:nosplit
func (r *socketOpsCommonRefs) IncRef() {
if v := atomic.AddInt64(&r.refCount, 1); v <= 0 {
panic(fmt.Sprintf("Incrementing non-positive ref count %p owned by %T", r, socketOpsCommonownerType))
}
}
// TryIncRef implements refs.RefCounter.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 *socketOpsCommonRefs) TryIncRef() bool {
const speculativeRef = 1 << 32
v := atomic.AddInt64(&r.refCount, speculativeRef)
if int32(v) < 0 {
atomic.AddInt64(&r.refCount, -speculativeRef)
return false
}
atomic.AddInt64(&r.refCount, -speculativeRef+1)
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 *socketOpsCommonRefs) DecRef(destroy func()) {
switch v := atomic.AddInt64(&r.refCount, -1); {
case v < -1:
panic(fmt.Sprintf("Decrementing non-positive ref count %p, owned by %T", r, socketOpsCommonownerType))
case v == -1:
if destroy != nil {
destroy()
}
}
}
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