Adding upstream version 1.21.8.upstream/1.21.8

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 489 insertions, 0 deletions

diff --git a/src/runtime/mgcwork.go b/src/runtime/mgcwork.go
new file mode 100644
index 0000000..7ab8975
--- /dev/null
+++ b/src/runtime/mgcwork.go
@@ -0,0 +1,489 @@
+// 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 (
+	"internal/goarch"
+	"runtime/internal/atomic"
+	"runtime/internal/sys"
+	"unsafe"
+)
+
+const (
+	_WorkbufSize = 2048 // in bytes; larger values result in less contention
+
+	// workbufAlloc is the number of bytes to allocate at a time
+	// for new workbufs. This must be a multiple of pageSize and
+	// should be a multiple of _WorkbufSize.
+	//
+	// Larger values reduce workbuf allocation overhead. Smaller
+	// values reduce heap fragmentation.
+	workbufAlloc = 32 << 10
+)
+
+func init() {
+	if workbufAlloc%pageSize != 0 || workbufAlloc%_WorkbufSize != 0 {
+		throw("bad workbufAlloc")
+	}
+}
+
+// Garbage collector work pool abstraction.
+//
+// This implements a producer/consumer model for pointers to grey
+// objects. A grey object is one that is marked and on a work
+// queue. A black object is marked and not on a work queue.
+//
+// Write barriers, root discovery, stack scanning, and object scanning
+// produce pointers to grey objects. Scanning consumes pointers to
+// grey objects, thus blackening them, and then scans them,
+// potentially producing new pointers to grey objects.
+
+// A gcWork provides the interface to produce and consume work for the
+// garbage collector.
+//
+// A gcWork can be used on the stack as follows:
+//
+//	(preemption must be disabled)
+//	gcw := &getg().m.p.ptr().gcw
+//	.. call gcw.put() to produce and gcw.tryGet() to consume ..
+//
+// It's important that any use of gcWork during the mark phase prevent
+// the garbage collector from transitioning to mark termination since
+// gcWork may locally hold GC work buffers. This can be done by
+// disabling preemption (systemstack or acquirem).
+type gcWork struct {
+	// wbuf1 and wbuf2 are the primary and secondary work buffers.
+	//
+	// This can be thought of as a stack of both work buffers'
+	// pointers concatenated. When we pop the last pointer, we
+	// shift the stack up by one work buffer by bringing in a new
+	// full buffer and discarding an empty one. When we fill both
+	// buffers, we shift the stack down by one work buffer by
+	// bringing in a new empty buffer and discarding a full one.
+	// This way we have one buffer's worth of hysteresis, which
+	// amortizes the cost of getting or putting a work buffer over
+	// at least one buffer of work and reduces contention on the
+	// global work lists.
+	//
+	// wbuf1 is always the buffer we're currently pushing to and
+	// popping from and wbuf2 is the buffer that will be discarded
+	// next.
+	//
+	// Invariant: Both wbuf1 and wbuf2 are nil or neither are.
+	wbuf1, wbuf2 *workbuf
+
+	// Bytes marked (blackened) on this gcWork. This is aggregated
+	// into work.bytesMarked by dispose.
+	bytesMarked uint64
+
+	// Heap scan work performed on this gcWork. This is aggregated into
+	// gcController by dispose and may also be flushed by callers.
+	// Other types of scan work are flushed immediately.
+	heapScanWork int64
+
+	// flushedWork indicates that a non-empty work buffer was
+	// flushed to the global work list since the last gcMarkDone
+	// termination check. Specifically, this indicates that this
+	// gcWork may have communicated work to another gcWork.
+	flushedWork bool
+}
+
+// Most of the methods of gcWork are go:nowritebarrierrec because the
+// write barrier itself can invoke gcWork methods but the methods are
+// not generally re-entrant. Hence, if a gcWork method invoked the
+// write barrier while the gcWork was in an inconsistent state, and
+// the write barrier in turn invoked a gcWork method, it could
+// permanently corrupt the gcWork.
+
+func (w *gcWork) init() {
+	w.wbuf1 = getempty()
+	wbuf2 := trygetfull()
+	if wbuf2 == nil {
+		wbuf2 = getempty()
+	}
+	w.wbuf2 = wbuf2
+}
+
+// put enqueues a pointer for the garbage collector to trace.
+// obj must point to the beginning of a heap object or an oblet.
+//
+//go:nowritebarrierrec
+func (w *gcWork) put(obj uintptr) {
+	flushed := false
+	wbuf := w.wbuf1
+	// Record that this may acquire the wbufSpans or heap lock to
+	// allocate a workbuf.
+	lockWithRankMayAcquire(&work.wbufSpans.lock, lockRankWbufSpans)
+	lockWithRankMayAcquire(&mheap_.lock, lockRankMheap)
+	if wbuf == nil {
+		w.init()
+		wbuf = w.wbuf1
+		// wbuf is empty at this point.
+	} else if wbuf.nobj == len(wbuf.obj) {
+		w.wbuf1, w.wbuf2 = w.wbuf2, w.wbuf1
+		wbuf = w.wbuf1
+		if wbuf.nobj == len(wbuf.obj) {
+			putfull(wbuf)
+			w.flushedWork = true
+			wbuf = getempty()
+			w.wbuf1 = wbuf
+			flushed = true
+		}
+	}
+
+	wbuf.obj[wbuf.nobj] = obj
+	wbuf.nobj++
+
+	// If we put a buffer on full, let the GC controller know so
+	// it can encourage more workers to run. We delay this until
+	// the end of put so that w is in a consistent state, since
+	// enlistWorker may itself manipulate w.
+	if flushed && gcphase == _GCmark {
+		gcController.enlistWorker()
+	}
+}
+
+// putFast does a put and reports whether it can be done quickly
+// otherwise it returns false and the caller needs to call put.
+//
+//go:nowritebarrierrec
+func (w *gcWork) putFast(obj uintptr) bool {
+	wbuf := w.wbuf1
+	if wbuf == nil || wbuf.nobj == len(wbuf.obj) {
+		return false
+	}
+
+	wbuf.obj[wbuf.nobj] = obj
+	wbuf.nobj++
+	return true
+}
+
+// putBatch performs a put on every pointer in obj. See put for
+// constraints on these pointers.
+//
+//go:nowritebarrierrec
+func (w *gcWork) putBatch(obj []uintptr) {
+	if len(obj) == 0 {
+		return
+	}
+
+	flushed := false
+	wbuf := w.wbuf1
+	if wbuf == nil {
+		w.init()
+		wbuf = w.wbuf1
+	}
+
+	for len(obj) > 0 {
+		for wbuf.nobj == len(wbuf.obj) {
+			putfull(wbuf)
+			w.flushedWork = true
+			w.wbuf1, w.wbuf2 = w.wbuf2, getempty()
+			wbuf = w.wbuf1
+			flushed = true
+		}
+		n := copy(wbuf.obj[wbuf.nobj:], obj)
+		wbuf.nobj += n
+		obj = obj[n:]
+	}
+
+	if flushed && gcphase == _GCmark {
+		gcController.enlistWorker()
+	}
+}
+
+// tryGet dequeues a pointer for the garbage collector to trace.
+//
+// If there are no pointers remaining in this gcWork or in the global
+// queue, tryGet returns 0.  Note that there may still be pointers in
+// other gcWork instances or other caches.
+//
+//go:nowritebarrierrec
+func (w *gcWork) tryGet() uintptr {
+	wbuf := w.wbuf1
+	if wbuf == nil {
+		w.init()
+		wbuf = w.wbuf1
+		// wbuf is empty at this point.
+	}
+	if wbuf.nobj == 0 {
+		w.wbuf1, w.wbuf2 = w.wbuf2, w.wbuf1
+		wbuf = w.wbuf1
+		if wbuf.nobj == 0 {
+			owbuf := wbuf
+			wbuf = trygetfull()
+			if wbuf == nil {
+				return 0
+			}
+			putempty(owbuf)
+			w.wbuf1 = wbuf
+		}
+	}
+
+	wbuf.nobj--
+	return wbuf.obj[wbuf.nobj]
+}
+
+// tryGetFast dequeues a pointer for the garbage collector to trace
+// if one is readily available. Otherwise it returns 0 and
+// the caller is expected to call tryGet().
+//
+//go:nowritebarrierrec
+func (w *gcWork) tryGetFast() uintptr {
+	wbuf := w.wbuf1
+	if wbuf == nil || wbuf.nobj == 0 {
+		return 0
+	}
+
+	wbuf.nobj--
+	return wbuf.obj[wbuf.nobj]
+}
+
+// dispose returns any cached pointers to the global queue.
+// The buffers are being put on the full queue so that the
+// write barriers will not simply reacquire them before the
+// GC can inspect them. This helps reduce the mutator's
+// ability to hide pointers during the concurrent mark phase.
+//
+//go:nowritebarrierrec
+func (w *gcWork) dispose() {
+	if wbuf := w.wbuf1; wbuf != nil {
+		if wbuf.nobj == 0 {
+			putempty(wbuf)
+		} else {
+			putfull(wbuf)
+			w.flushedWork = true
+		}
+		w.wbuf1 = nil
+
+		wbuf = w.wbuf2
+		if wbuf.nobj == 0 {
+			putempty(wbuf)
+		} else {
+			putfull(wbuf)
+			w.flushedWork = true
+		}
+		w.wbuf2 = nil
+	}
+	if w.bytesMarked != 0 {
+		// dispose happens relatively infrequently. If this
+		// atomic becomes a problem, we should first try to
+		// dispose less and if necessary aggregate in a per-P
+		// counter.
+		atomic.Xadd64(&work.bytesMarked, int64(w.bytesMarked))
+		w.bytesMarked = 0
+	}
+	if w.heapScanWork != 0 {
+		gcController.heapScanWork.Add(w.heapScanWork)
+		w.heapScanWork = 0
+	}
+}
+
+// balance moves some work that's cached in this gcWork back on the
+// global queue.
+//
+//go:nowritebarrierrec
+func (w *gcWork) balance() {
+	if w.wbuf1 == nil {
+		return
+	}
+	if wbuf := w.wbuf2; wbuf.nobj != 0 {
+		putfull(wbuf)
+		w.flushedWork = true
+		w.wbuf2 = getempty()
+	} else if wbuf := w.wbuf1; wbuf.nobj > 4 {
+		w.wbuf1 = handoff(wbuf)
+		w.flushedWork = true // handoff did putfull
+	} else {
+		return
+	}
+	// We flushed a buffer to the full list, so wake a worker.
+	if gcphase == _GCmark {
+		gcController.enlistWorker()
+	}
+}
+
+// empty reports whether w has no mark work available.
+//
+//go:nowritebarrierrec
+func (w *gcWork) empty() bool {
+	return w.wbuf1 == nil || (w.wbuf1.nobj == 0 && w.wbuf2.nobj == 0)
+}
+
+// Internally, the GC work pool is kept in arrays in work buffers.
+// The gcWork interface caches a work buffer until full (or empty) to
+// avoid contending on the global work buffer lists.
+
+type workbufhdr struct {
+	node lfnode // must be first
+	nobj int
+}
+
+type workbuf struct {
+	_ sys.NotInHeap
+	workbufhdr
+	// account for the above fields
+	obj [(_WorkbufSize - unsafe.Sizeof(workbufhdr{})) / goarch.PtrSize]uintptr
+}
+
+// workbuf factory routines. These funcs are used to manage the
+// workbufs.
+// If the GC asks for some work these are the only routines that
+// make wbufs available to the GC.
+
+func (b *workbuf) checknonempty() {
+	if b.nobj == 0 {
+		throw("workbuf is empty")
+	}
+}
+
+func (b *workbuf) checkempty() {
+	if b.nobj != 0 {
+		throw("workbuf is not empty")
+	}
+}
+
+// getempty pops an empty work buffer off the work.empty list,
+// allocating new buffers if none are available.
+//
+//go:nowritebarrier
+func getempty() *workbuf {
+	var b *workbuf
+	if work.empty != 0 {
+		b = (*workbuf)(work.empty.pop())
+		if b != nil {
+			b.checkempty()
+		}
+	}
+	// Record that this may acquire the wbufSpans or heap lock to
+	// allocate a workbuf.
+	lockWithRankMayAcquire(&work.wbufSpans.lock, lockRankWbufSpans)
+	lockWithRankMayAcquire(&mheap_.lock, lockRankMheap)
+	if b == nil {
+		// Allocate more workbufs.
+		var s *mspan
+		if work.wbufSpans.free.first != nil {
+			lock(&work.wbufSpans.lock)
+			s = work.wbufSpans.free.first
+			if s != nil {
+				work.wbufSpans.free.remove(s)
+				work.wbufSpans.busy.insert(s)
+			}
+			unlock(&work.wbufSpans.lock)
+		}
+		if s == nil {
+			systemstack(func() {
+				s = mheap_.allocManual(workbufAlloc/pageSize, spanAllocWorkBuf)
+			})
+			if s == nil {
+				throw("out of memory")
+			}
+			// Record the new span in the busy list.
+			lock(&work.wbufSpans.lock)
+			work.wbufSpans.busy.insert(s)
+			unlock(&work.wbufSpans.lock)
+		}
+		// Slice up the span into new workbufs. Return one and
+		// put the rest on the empty list.
+		for i := uintptr(0); i+_WorkbufSize <= workbufAlloc; i += _WorkbufSize {
+			newb := (*workbuf)(unsafe.Pointer(s.base() + i))
+			newb.nobj = 0
+			lfnodeValidate(&newb.node)
+			if i == 0 {
+				b = newb
+			} else {
+				putempty(newb)
+			}
+		}
+	}
+	return b
+}
+
+// putempty puts a workbuf onto the work.empty list.
+// Upon entry this goroutine owns b. The lfstack.push relinquishes ownership.
+//
+//go:nowritebarrier
+func putempty(b *workbuf) {
+	b.checkempty()
+	work.empty.push(&b.node)
+}
+
+// putfull puts the workbuf on the work.full list for the GC.
+// putfull accepts partially full buffers so the GC can avoid competing
+// with the mutators for ownership of partially full buffers.
+//
+//go:nowritebarrier
+func putfull(b *workbuf) {
+	b.checknonempty()
+	work.full.push(&b.node)
+}
+
+// trygetfull tries to get a full or partially empty workbuffer.
+// If one is not immediately available return nil.
+//
+//go:nowritebarrier
+func trygetfull() *workbuf {
+	b := (*workbuf)(work.full.pop())
+	if b != nil {
+		b.checknonempty()
+		return b
+	}
+	return b
+}
+
+//go:nowritebarrier
+func handoff(b *workbuf) *workbuf {
+	// Make new buffer with half of b's pointers.
+	b1 := getempty()
+	n := b.nobj / 2
+	b.nobj -= n
+	b1.nobj = n
+	memmove(unsafe.Pointer(&b1.obj[0]), unsafe.Pointer(&b.obj[b.nobj]), uintptr(n)*unsafe.Sizeof(b1.obj[0]))
+
+	// Put b on full list - let first half of b get stolen.
+	putfull(b)
+	return b1
+}
+
+// prepareFreeWorkbufs moves busy workbuf spans to free list so they
+// can be freed to the heap. This must only be called when all
+// workbufs are on the empty list.
+func prepareFreeWorkbufs() {
+	lock(&work.wbufSpans.lock)
+	if work.full != 0 {
+		throw("cannot free workbufs when work.full != 0")
+	}
+	// Since all workbufs are on the empty list, we don't care
+	// which ones are in which spans. We can wipe the entire empty
+	// list and move all workbuf spans to the free list.
+	work.empty = 0
+	work.wbufSpans.free.takeAll(&work.wbufSpans.busy)
+	unlock(&work.wbufSpans.lock)
+}
+
+// freeSomeWbufs frees some workbufs back to the heap and returns
+// true if it should be called again to free more.
+func freeSomeWbufs(preemptible bool) bool {
+	const batchSize = 64 // ~1–2 µs per span.
+	lock(&work.wbufSpans.lock)
+	if gcphase != _GCoff || work.wbufSpans.free.isEmpty() {
+		unlock(&work.wbufSpans.lock)
+		return false
+	}
+	systemstack(func() {
+		gp := getg().m.curg
+		for i := 0; i < batchSize && !(preemptible && gp.preempt); i++ {
+			span := work.wbufSpans.free.first
+			if span == nil {
+				break
+			}
+			work.wbufSpans.free.remove(span)
+			mheap_.freeManual(span, spanAllocWorkBuf)
+		}
+	})
+	more := !work.wbufSpans.free.isEmpty()
+	unlock(&work.wbufSpans.lock)
+	return more
+}