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runtime: consolidate h_spans and mheap_.spans

Like h_allspans and mheap_.allspans, these were two ways of referring
to the spans array from when the runtime was split between C and Go.
Clean this up by making mheap_.spans a slice and eliminating h_spans.

Change-Id: I3aa7038d53c3a4252050aa33e468c48dfed0b70e
Reviewed-on: https://go-review.googlesource.com/30532
Run-TryBot: Austin Clements <austin@google.com>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Rick Hudson <rlh@golang.org>
This commit is contained in:
Austin Clements 2016-10-04 16:03:00 -04:00
parent 66e849b168
commit 6b0f668044
6 changed files with 37 additions and 40 deletions

View File

@ -123,7 +123,7 @@ func cgoCheckTypedBlock(typ *_type, src unsafe.Pointer, off, size uintptr) {
aoff := uintptr(src) - mheap_.arena_start
idx := aoff >> _PageShift
s := h_spans[idx]
s := mheap_.spans[idx]
if s.state == _MSpanStack {
// There are no heap bits for value stored on the stack.
// For a channel receive src might be on the stack of some

View File

@ -360,7 +360,7 @@ func mallocinit() {
// To overcome this we ask for PageSize more and round up the pointer.
p1 := round(p, _PageSize)
mheap_.spans = (**mspan)(unsafe.Pointer(p1))
spansStart := p1
mheap_.bitmap = p1 + spansSize + bitmapSize
if sys.PtrSize == 4 {
// Set arena_start such that we can accept memory
@ -379,7 +379,7 @@ func mallocinit() {
}
// Initialize the rest of the allocator.
mheap_.init(spansSize)
mheap_.init(spansStart, spansSize)
_g_ := getg()
_g_.m.mcache = allocmcache()
}

View File

@ -398,7 +398,7 @@ func heapBitsForObject(p, refBase, refOff uintptr) (base uintptr, hbits heapBits
idx := off >> _PageShift
// p points into the heap, but possibly to the middle of an object.
// Consult the span table to find the block beginning.
s = h_spans[idx]
s = mheap_.spans[idx]
if s == nil || p < s.base() || p >= s.limit || s.state != mSpanInUse {
if s == nil || s.state == _MSpanStack {
// If s is nil, the virtual address has never been part of the heap.

View File

@ -420,7 +420,7 @@ func findObject(v unsafe.Pointer) (s *mspan, x unsafe.Pointer, n uintptr) {
}
p := uintptr(v) >> pageShift
q := p - arena_start>>pageShift
s = *(**mspan)(add(unsafe.Pointer(mheap_.spans), q*sys.PtrSize))
s = mheap_.spans[q]
if s == nil {
return
}

View File

@ -1327,7 +1327,7 @@ func gcDumpObject(label string, obj, off uintptr) {
k := obj >> _PageShift
x := k
x -= mheap_.arena_start >> _PageShift
s := h_spans[x]
s := mheap_.spans[x]
print(label, "=", hex(obj), " k=", hex(k))
if s == nil {
print(" s=nil\n")

View File

@ -49,9 +49,13 @@ type mheap struct {
// access (since that may free the backing store).
allspans []*mspan // all spans out there
// span lookup
spans **mspan
spans_mapped uintptr
// spans is a lookup table to map virtual address page IDs to *mspan.
// For allocated spans, their pages map to the span itself.
// For free spans, only the lowest and highest pages map to the span itself.
// Internal pages map to an arbitrary span.
// For pages that have never been allocated, spans entries are nil.
spans []*mspan
spans_mapped uintptr // bytes mapped starting at &spans[0]
// Proportional sweep
pagesInUse uint64 // pages of spans in stats _MSpanInUse; R/W with mheap.lock
@ -244,13 +248,6 @@ func (s *mspan) layout() (size, n, total uintptr) {
return
}
// h_spans is a lookup table to map virtual address page IDs to *mspan.
// For allocated spans, their pages map to the span itself.
// For free spans, only the lowest and highest pages map to the span itself. Internal
// pages map to an arbitrary span.
// For pages that have never been allocated, h_spans entries are nil.
var h_spans []*mspan // TODO: make this h.spans once mheap can be defined in Go
func recordspan(vh unsafe.Pointer, p unsafe.Pointer) {
h := (*mheap)(vh)
s := (*mspan)(p)
@ -291,7 +288,7 @@ func inheap(b uintptr) bool {
return false
}
// Not a beginning of a block, consult span table to find the block beginning.
s := h_spans[(b-mheap_.arena_start)>>_PageShift]
s := mheap_.spans[(b-mheap_.arena_start)>>_PageShift]
if s == nil || b < s.base() || b >= s.limit || s.state != mSpanInUse {
return false
}
@ -306,7 +303,7 @@ func inHeapOrStack(b uintptr) bool {
return false
}
// Not a beginning of a block, consult span table to find the block beginning.
s := h_spans[(b-mheap_.arena_start)>>_PageShift]
s := mheap_.spans[(b-mheap_.arena_start)>>_PageShift]
if s == nil || b < s.base() {
return false
}
@ -336,7 +333,7 @@ func spanOf(p uintptr) *mspan {
// that p points into the heap (that is, mheap_.arena_start <= p <
// mheap_.arena_used).
func spanOfUnchecked(p uintptr) *mspan {
return h_spans[(p-mheap_.arena_start)>>_PageShift]
return mheap_.spans[(p-mheap_.arena_start)>>_PageShift]
}
func mlookup(v uintptr, base *uintptr, size *uintptr, sp **mspan) int32 {
@ -389,7 +386,7 @@ func mlookup(v uintptr, base *uintptr, size *uintptr, sp **mspan) int32 {
}
// Initialize the heap.
func (h *mheap) init(spans_size uintptr) {
func (h *mheap) init(spansStart, spansBytes uintptr) {
h.spanalloc.init(unsafe.Sizeof(mspan{}), recordspan, unsafe.Pointer(h), &memstats.mspan_sys)
h.cachealloc.init(unsafe.Sizeof(mcache{}), nil, nil, &memstats.mcache_sys)
h.specialfinalizeralloc.init(unsafe.Sizeof(specialfinalizer{}), nil, nil, &memstats.other_sys)
@ -407,10 +404,10 @@ func (h *mheap) init(spans_size uintptr) {
h.central[i].mcentral.init(int32(i))
}
sp := (*slice)(unsafe.Pointer(&h_spans))
sp.array = unsafe.Pointer(h.spans)
sp.len = int(spans_size / sys.PtrSize)
sp.cap = int(spans_size / sys.PtrSize)
sp := (*slice)(unsafe.Pointer(&h.spans))
sp.array = unsafe.Pointer(spansStart)
sp.len = int(spansBytes / sys.PtrSize)
sp.cap = int(spansBytes / sys.PtrSize)
}
// mHeap_MapSpans makes sure that the spans are mapped
@ -430,7 +427,7 @@ func (h *mheap) mapSpans(arena_used uintptr) {
if h.spans_mapped >= n {
return
}
sysMap(add(unsafe.Pointer(h.spans), h.spans_mapped), n-h.spans_mapped, h.arena_reserved, &memstats.other_sys)
sysMap(add(unsafe.Pointer(&h.spans[0]), h.spans_mapped), n-h.spans_mapped, h.arena_reserved, &memstats.other_sys)
h.spans_mapped = n
}
@ -582,15 +579,15 @@ func (h *mheap) alloc_m(npage uintptr, sizeclass int32, large bool) *mspan {
traceHeapAlloc()
}
// h_spans is accessed concurrently without synchronization
// h.spans is accessed concurrently without synchronization
// from other threads. Hence, there must be a store/store
// barrier here to ensure the writes to h_spans above happen
// barrier here to ensure the writes to h.spans above happen
// before the caller can publish a pointer p to an object
// allocated from s. As soon as this happens, the garbage
// collector running on another processor could read p and
// look up s in h_spans. The unlock acts as the barrier to
// look up s in h.spans. The unlock acts as the barrier to
// order these writes. On the read side, the data dependency
// between p and the index in h_spans orders the reads.
// between p and the index in h.spans orders the reads.
unlock(&h.lock)
return s
}
@ -686,10 +683,10 @@ HaveSpan:
s.npages = npage
p := (t.base() - h.arena_start) >> _PageShift
if p > 0 {
h_spans[p-1] = s
h.spans[p-1] = s
}
h_spans[p] = t
h_spans[p+t.npages-1] = t
h.spans[p] = t
h.spans[p+t.npages-1] = t
t.needzero = s.needzero
s.state = _MSpanStack // prevent coalescing with s
t.state = _MSpanStack
@ -700,7 +697,7 @@ HaveSpan:
p := (s.base() - h.arena_start) >> _PageShift
for n := uintptr(0); n < npage; n++ {
h_spans[p+n] = s
h.spans[p+n] = s
}
memstats.heap_inuse += uint64(npage << _PageShift)
@ -766,7 +763,7 @@ func (h *mheap) grow(npage uintptr) bool {
s.init(uintptr(v), ask>>_PageShift)
p := (s.base() - h.arena_start) >> _PageShift
for i := p; i < p+s.npages; i++ {
h_spans[i] = s
h.spans[i] = s
}
atomic.Store(&s.sweepgen, h.sweepgen)
s.state = _MSpanInUse
@ -781,7 +778,7 @@ func (h *mheap) grow(npage uintptr) bool {
func (h *mheap) lookup(v unsafe.Pointer) *mspan {
p := uintptr(v)
p -= h.arena_start
return h_spans[p>>_PageShift]
return h.spans[p>>_PageShift]
}
// Look up the span at the given address.
@ -795,7 +792,7 @@ func (h *mheap) lookupMaybe(v unsafe.Pointer) *mspan {
if uintptr(v) < h.arena_start || uintptr(v) >= h.arena_used {
return nil
}
s := h_spans[(uintptr(v)-h.arena_start)>>_PageShift]
s := h.spans[(uintptr(v)-h.arena_start)>>_PageShift]
if s == nil || uintptr(v) < s.base() || uintptr(v) >= uintptr(unsafe.Pointer(s.limit)) || s.state != _MSpanInUse {
return nil
}
@ -880,26 +877,26 @@ func (h *mheap) freeSpanLocked(s *mspan, acctinuse, acctidle bool, unusedsince i
// Coalesce with earlier, later spans.
p := (s.base() - h.arena_start) >> _PageShift
if p > 0 {
t := h_spans[p-1]
t := h.spans[p-1]
if t != nil && t.state == _MSpanFree {
s.startAddr = t.startAddr
s.npages += t.npages
s.npreleased = t.npreleased // absorb released pages
s.needzero |= t.needzero
p -= t.npages
h_spans[p] = s
h.spans[p] = s
h.freeList(t.npages).remove(t)
t.state = _MSpanDead
h.spanalloc.free(unsafe.Pointer(t))
}
}
if (p+s.npages)*sys.PtrSize < h.spans_mapped {
t := h_spans[p+s.npages]
t := h.spans[p+s.npages]
if t != nil && t.state == _MSpanFree {
s.npages += t.npages
s.npreleased += t.npreleased
s.needzero |= t.needzero
h_spans[p+s.npages-1] = s
h.spans[p+s.npages-1] = s
h.freeList(t.npages).remove(t)
t.state = _MSpanDead
h.spanalloc.free(unsafe.Pointer(t))