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// Copyright 2014 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
// This file contains the implementation of Go channels.
import "unsafe"
const (
maxAlign = 8
hchanSize = unsafe.Sizeof(hchan{}) + uintptr(-int(unsafe.Sizeof(hchan{}))&(maxAlign-1))
debugChan = false
)
type hchan struct {
qcount uint // total data in the queue
dataqsiz uint // size of the circular queue
buf unsafe.Pointer // points to an array of dataqsiz elements
elemsize uint16
closed uint32
elemtype *_type // element type
sendx uint // send index
recvx uint // receive index
recvq waitq // list of recv waiters
sendq waitq // list of send waiters
lock mutex
}
type waitq struct {
first *sudog
last *sudog
}
//go:linkname reflect_makechan reflect.makechan
func reflect_makechan(t *chantype, size int64) *hchan {
return makechan(t, size)
}
func makechan(t *chantype, size int64) *hchan {
elem := t.elem
// compiler checks this but be safe.
if elem.size >= 1<<16 {
throw("makechan: invalid channel element type")
}
if hchanSize%maxAlign != 0 || elem.align > maxAlign {
throw("makechan: bad alignment")
}
if size < 0 || int64(uintptr(size)) != size || (elem.size > 0 && uintptr(size) > (_MaxMem-hchanSize)/uintptr(elem.size)) {
panic("makechan: size out of range")
}
var c *hchan
if elem.kind&kindNoPointers != 0 || size == 0 {
// Allocate memory in one call.
// Hchan does not contain pointers interesting for GC in this case:
// buf points into the same allocation, elemtype is persistent.
// SudoG's are referenced from their owning thread so they can't be collected.
// TODO(dvyukov,rlh): Rethink when collector can move allocated objects.
c = (*hchan)(mallocgc(hchanSize+uintptr(size)*uintptr(elem.size), nil, flagNoScan))
if size > 0 && elem.size != 0 {
c.buf = add(unsafe.Pointer(c), hchanSize)
} else {
// race detector uses this location for synchronization
// Also prevents us from pointing beyond the allocation (see issue 9401).
c.buf = unsafe.Pointer(c)
}
} else {
c = new(hchan)
c.buf = newarray(elem, uintptr(size))
}
c.elemsize = uint16(elem.size)
c.elemtype = elem
c.dataqsiz = uint(size)
if debugChan {
print("makechan: chan=", c, "; elemsize=", elem.size, "; elemalg=", elem.alg, "; dataqsiz=", size, "\n")
}
return c
}
// chanbuf(c, i) is pointer to the i'th slot in the buffer.
func chanbuf(c *hchan, i uint) unsafe.Pointer {
return add(c.buf, uintptr(i)*uintptr(c.elemsize))
}
// entry point for c <- x from compiled code
//go:nosplit
func chansend1(t *chantype, c *hchan, elem unsafe.Pointer) {
chansend(t, c, elem, true, getcallerpc(unsafe.Pointer(&t)))
}
/*
* generic single channel send/recv
* If block is not nil,
* then the protocol will not
* sleep but return if it could
* not complete.
*
* sleep can wake up with g.param == nil
* when a channel involved in the sleep has
* been closed. it is easiest to loop and re-run
* the operation; we'll see that it's now closed.
*/
func chansend(t *chantype, c *hchan, ep unsafe.Pointer, block bool, callerpc uintptr) bool {
if raceenabled {
raceReadObjectPC(t.elem, ep, callerpc, funcPC(chansend))
}
if c == nil {
if !block {
return false
}
gopark(nil, nil, "chan send (nil chan)", traceEvGoStop, 2)
throw("unreachable")
}
if debugChan {
print("chansend: chan=", c, "\n")
}
if raceenabled {
racereadpc(unsafe.Pointer(c), callerpc, funcPC(chansend))
}
// Fast path: check for failed non-blocking operation without acquiring the lock.
//
// After observing that the channel is not closed, we observe that the channel is
// not ready for sending. Each of these observations is a single word-sized read
// (first c.closed and second c.recvq.first or c.qcount depending on kind of channel).
// Because a closed channel cannot transition from 'ready for sending' to
// 'not ready for sending', even if the channel is closed between the two observations,
// they imply a moment between the two when the channel was both not yet closed
// and not ready for sending. We behave as if we observed the channel at that moment,
// and report that the send cannot proceed.
//
// It is okay if the reads are reordered here: if we observe that the channel is not
// ready for sending and then observe that it is not closed, that implies that the
// channel wasn't closed during the first observation.
if !block && c.closed == 0 && ((c.dataqsiz == 0 && c.recvq.first == nil) ||
(c.dataqsiz > 0 && c.qcount == c.dataqsiz)) {
return false
}
var t0 int64
if blockprofilerate > 0 {
t0 = cputicks()
}
lock(&c.lock)
if c.closed != 0 {
unlock(&c.lock)
panic("send on closed channel")
}
if c.dataqsiz == 0 { // synchronous channel
sg := c.recvq.dequeue()
if sg != nil { // found a waiting receiver
if raceenabled {
racesync(c, sg)
}
unlock(&c.lock)
recvg := sg.g
if sg.elem != nil {
syncsend(c, sg, ep)
}
recvg.param = unsafe.Pointer(sg)
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(recvg, 3)
return true
}
if !block {
unlock(&c.lock)
return false
}
// no receiver available: block on this channel.
gp := getg()
mysg := acquireSudog()
mysg.releasetime = 0
if t0 != 0 {
mysg.releasetime = -1
}
mysg.elem = ep
mysg.waitlink = nil
gp.waiting = mysg
mysg.g = gp
mysg.selectdone = nil
gp.param = nil
c.sendq.enqueue(mysg)
goparkunlock(&c.lock, "chan send", traceEvGoBlockSend, 3)
// someone woke us up.
if mysg != gp.waiting {
throw("G waiting list is corrupted!")
}
gp.waiting = nil
if gp.param == nil {
if c.closed == 0 {
throw("chansend: spurious wakeup")
}
panic("send on closed channel")
}
gp.param = nil
if mysg.releasetime > 0 {
blockevent(int64(mysg.releasetime)-t0, 2)
}
releaseSudog(mysg)
return true
}
// asynchronous channel
// wait for some space to write our data
var t1 int64
for futile := byte(0); c.qcount >= c.dataqsiz; futile = traceFutileWakeup {
if !block {
unlock(&c.lock)
return false
}
gp := getg()
mysg := acquireSudog()
mysg.releasetime = 0
if t0 != 0 {
mysg.releasetime = -1
}
mysg.g = gp
mysg.elem = nil
mysg.selectdone = nil
c.sendq.enqueue(mysg)
goparkunlock(&c.lock, "chan send", traceEvGoBlockSend|futile, 3)
// someone woke us up - try again
if mysg.releasetime > 0 {
t1 = mysg.releasetime
}
releaseSudog(mysg)
lock(&c.lock)
if c.closed != 0 {
unlock(&c.lock)
panic("send on closed channel")
}
}
// write our data into the channel buffer
if raceenabled {
raceacquire(chanbuf(c, c.sendx))
racerelease(chanbuf(c, c.sendx))
}
typedmemmove(c.elemtype, chanbuf(c, c.sendx), ep)
c.sendx++
if c.sendx == c.dataqsiz {
c.sendx = 0
}
c.qcount++
// wake up a waiting receiver
sg := c.recvq.dequeue()
if sg != nil {
recvg := sg.g
unlock(&c.lock)
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(recvg, 3)
} else {
unlock(&c.lock)
}
if t1 > 0 {
blockevent(t1-t0, 2)
}
return true
}
func syncsend(c *hchan, sg *sudog, elem unsafe.Pointer) {
// Send on unbuffered channel is the only operation
// in the entire runtime where one goroutine
// writes to the stack of another goroutine. The GC assumes that
// stack writes only happen when the goroutine is running and are
// only done by that goroutine. Using a write barrier is sufficient to
// make up for violating that assumption, but the write barrier has to work.
// typedmemmove will call heapBitsBulkBarrier, but the target bytes
// are not in the heap, so that will not help. We arrange to call
// memmove and typeBitsBulkBarrier instead.
memmove(sg.elem, elem, c.elemtype.size)
typeBitsBulkBarrier(c.elemtype, uintptr(sg.elem), c.elemtype.size)
sg.elem = nil
}
func closechan(c *hchan) {
if c == nil {
panic("close of nil channel")
}
lock(&c.lock)
if c.closed != 0 {
unlock(&c.lock)
panic("close of closed channel")
}
if raceenabled {
callerpc := getcallerpc(unsafe.Pointer(&c))
racewritepc(unsafe.Pointer(c), callerpc, funcPC(closechan))
racerelease(unsafe.Pointer(c))
}
c.closed = 1
// release all readers
for {
sg := c.recvq.dequeue()
if sg == nil {
break
}
gp := sg.g
sg.elem = nil
gp.param = nil
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(gp, 3)
}
// release all writers
for {
sg := c.sendq.dequeue()
if sg == nil {
break
}
gp := sg.g
sg.elem = nil
gp.param = nil
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(gp, 3)
}
unlock(&c.lock)
}
// entry points for <- c from compiled code
//go:nosplit
func chanrecv1(t *chantype, c *hchan, elem unsafe.Pointer) {
chanrecv(t, c, elem, true)
}
//go:nosplit
func chanrecv2(t *chantype, c *hchan, elem unsafe.Pointer) (received bool) {
_, received = chanrecv(t, c, elem, true)
return
}
// chanrecv receives on channel c and writes the received data to ep.
// ep may be nil, in which case received data is ignored.
// If block == false and no elements are available, returns (false, false).
// Otherwise, if c is closed, zeros *ep and returns (true, false).
// Otherwise, fills in *ep with an element and returns (true, true).
func chanrecv(t *chantype, c *hchan, ep unsafe.Pointer, block bool) (selected, received bool) {
// raceenabled: don't need to check ep, as it is always on the stack.
if debugChan {
print("chanrecv: chan=", c, "\n")
}
if c == nil {
if !block {
return
}
gopark(nil, nil, "chan receive (nil chan)", traceEvGoStop, 2)
throw("unreachable")
}
// Fast path: check for failed non-blocking operation without acquiring the lock.
//
// After observing that the channel is not ready for receiving, we observe that the
// channel is not closed. Each of these observations is a single word-sized read
// (first c.sendq.first or c.qcount, and second c.closed).
// Because a channel cannot be reopened, the later observation of the channel
// being not closed implies that it was also not closed at the moment of the
// first observation. We behave as if we observed the channel at that moment
// and report that the receive cannot proceed.
//
// The order of operations is important here: reversing the operations can lead to
// incorrect behavior when racing with a close.
if !block && (c.dataqsiz == 0 && c.sendq.first == nil ||
c.dataqsiz > 0 && atomicloaduint(&c.qcount) == 0) &&
atomicload(&c.closed) == 0 {
return
}
var t0 int64
if blockprofilerate > 0 {
t0 = cputicks()
}
lock(&c.lock)
if c.dataqsiz == 0 { // synchronous channel
if c.closed != 0 {
return recvclosed(c, ep)
}
sg := c.sendq.dequeue()
if sg != nil {
if raceenabled {
racesync(c, sg)
}
unlock(&c.lock)
if ep != nil {
typedmemmove(c.elemtype, ep, sg.elem)
}
sg.elem = nil
gp := sg.g
gp.param = unsafe.Pointer(sg)
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(gp, 3)
selected = true
received = true
return
}
if !block {
unlock(&c.lock)
return
}
// no sender available: block on this channel.
gp := getg()
mysg := acquireSudog()
mysg.releasetime = 0
if t0 != 0 {
mysg.releasetime = -1
}
mysg.elem = ep
mysg.waitlink = nil
gp.waiting = mysg
mysg.g = gp
mysg.selectdone = nil
gp.param = nil
c.recvq.enqueue(mysg)
goparkunlock(&c.lock, "chan receive", traceEvGoBlockRecv, 3)
// someone woke us up
if mysg != gp.waiting {
throw("G waiting list is corrupted!")
}
gp.waiting = nil
if mysg.releasetime > 0 {
blockevent(mysg.releasetime-t0, 2)
}
haveData := gp.param != nil
gp.param = nil
releaseSudog(mysg)
if haveData {
// a sender sent us some data. It already wrote to ep.
selected = true
received = true
return
}
lock(&c.lock)
if c.closed == 0 {
throw("chanrecv: spurious wakeup")
}
return recvclosed(c, ep)
}
// asynchronous channel
// wait for some data to appear
var t1 int64
for futile := byte(0); c.qcount <= 0; futile = traceFutileWakeup {
if c.closed != 0 {
selected, received = recvclosed(c, ep)
if t1 > 0 {
blockevent(t1-t0, 2)
}
return
}
if !block {
unlock(&c.lock)
return
}
// wait for someone to send an element
gp := getg()
mysg := acquireSudog()
mysg.releasetime = 0
if t0 != 0 {
mysg.releasetime = -1
}
mysg.elem = nil
mysg.g = gp
mysg.selectdone = nil
c.recvq.enqueue(mysg)
goparkunlock(&c.lock, "chan receive", traceEvGoBlockRecv|futile, 3)
// someone woke us up - try again
if mysg.releasetime > 0 {
t1 = mysg.releasetime
}
releaseSudog(mysg)
lock(&c.lock)
}
if raceenabled {
raceacquire(chanbuf(c, c.recvx))
racerelease(chanbuf(c, c.recvx))
}
if ep != nil {
typedmemmove(c.elemtype, ep, chanbuf(c, c.recvx))
}
memclr(chanbuf(c, c.recvx), uintptr(c.elemsize))
c.recvx++
if c.recvx == c.dataqsiz {
c.recvx = 0
}
c.qcount--
// ping a sender now that there is space
sg := c.sendq.dequeue()
if sg != nil {
gp := sg.g
unlock(&c.lock)
if sg.releasetime != 0 {
sg.releasetime = cputicks()
}
goready(gp, 3)
} else {
unlock(&c.lock)
}
if t1 > 0 {
blockevent(t1-t0, 2)
}
selected = true
received = true
return
}
// recvclosed is a helper function for chanrecv. Handles cleanup
// when the receiver encounters a closed channel.
// Caller must hold c.lock, recvclosed will release the lock.
func recvclosed(c *hchan, ep unsafe.Pointer) (selected, recevied bool) {
if raceenabled {
raceacquire(unsafe.Pointer(c))
}
unlock(&c.lock)
if ep != nil {
memclr(ep, uintptr(c.elemsize))
}
return true, false
}
// compiler implements
//
// select {
// case c <- v:
// ... foo
// default:
// ... bar
// }
//
// as
//
// if selectnbsend(c, v) {
// ... foo
// } else {
// ... bar
// }
//
func selectnbsend(t *chantype, c *hchan, elem unsafe.Pointer) (selected bool) {
return chansend(t, c, elem, false, getcallerpc(unsafe.Pointer(&t)))
}
// compiler implements
//
// select {
// case v = <-c:
// ... foo
// default:
// ... bar
// }
//
// as
//
// if selectnbrecv(&v, c) {
// ... foo
// } else {
// ... bar
// }
//
func selectnbrecv(t *chantype, elem unsafe.Pointer, c *hchan) (selected bool) {
selected, _ = chanrecv(t, c, elem, false)
return
}
// compiler implements
//
// select {
// case v, ok = <-c:
// ... foo
// default:
// ... bar
// }
//
// as
//
// if c != nil && selectnbrecv2(&v, &ok, c) {
// ... foo
// } else {
// ... bar
// }
//
func selectnbrecv2(t *chantype, elem unsafe.Pointer, received *bool, c *hchan) (selected bool) {
// TODO(khr): just return 2 values from this function, now that it is in Go.
selected, *received = chanrecv(t, c, elem, false)
return
}
//go:linkname reflect_chansend reflect.chansend
func reflect_chansend(t *chantype, c *hchan, elem unsafe.Pointer, nb bool) (selected bool) {
return chansend(t, c, elem, !nb, getcallerpc(unsafe.Pointer(&t)))
}
//go:linkname reflect_chanrecv reflect.chanrecv
func reflect_chanrecv(t *chantype, c *hchan, nb bool, elem unsafe.Pointer) (selected bool, received bool) {
return chanrecv(t, c, elem, !nb)
}
//go:linkname reflect_chanlen reflect.chanlen
func reflect_chanlen(c *hchan) int {
if c == nil {
return 0
}
return int(c.qcount)
}
//go:linkname reflect_chancap reflect.chancap
func reflect_chancap(c *hchan) int {
if c == nil {
return 0
}
return int(c.dataqsiz)
}
//go:linkname reflect_chanclose reflect.chanclose
func reflect_chanclose(c *hchan) {
closechan(c)
}
func (q *waitq) enqueue(sgp *sudog) {
sgp.next = nil
x := q.last
if x == nil {
sgp.prev = nil
q.first = sgp
q.last = sgp
return
}
sgp.prev = x
x.next = sgp
q.last = sgp
}
func (q *waitq) dequeue() *sudog {
for {
sgp := q.first
if sgp == nil {
return nil
}
y := sgp.next
if y == nil {
q.first = nil
q.last = nil
} else {
y.prev = nil
q.first = y
sgp.next = nil // mark as removed (see dequeueSudog)
}
// if sgp participates in a select and is already signaled, ignore it
if sgp.selectdone != nil {
// claim the right to signal
if *sgp.selectdone != 0 || !cas(sgp.selectdone, 0, 1) {
continue
}
}
return sgp
}
}
func racesync(c *hchan, sg *sudog) {
racerelease(chanbuf(c, 0))
raceacquireg(sg.g, chanbuf(c, 0))
racereleaseg(sg.g, chanbuf(c, 0))
raceacquire(chanbuf(c, 0))
}