前序
上文讲到 rt0_go 的 runtime·schedinit(SB)
TEXT runtime·rt0_go<ABIInternal>(SB),NOSPLIT,$0
// 略,查看 golang 调度学习 - 调度流程 (一)
// create a new goroutine to start program
MOVQ $runtime·mainPC(SB), AX // entry, 就是 $runtime·main
PUSHQ AX // newproc 的第二个参数
PUSHQ $0 // arg size 的第一个参数
CALL runtime·newproc(SB) // 调用 runtime·newproc($0, $runtime·mainPC(SB))
POPQ AX
POPQ AX
// start this M
CALL runtime·mstart(SB)
CALL runtime·abort(SB) // mstart should never return
RET
// Prevent dead-code elimination of debugCallV1, which is
// intended to be called by debuggers.
MOVQ $runtime·debugCallV1<ABIInternal>(SB), AX
RET
newproc
创立一个新的 g 运行带 siz 字节参数的 fn,并且把它放到 g.m.p 的待运行队列
在编写程序中,应用 go func() {}来创立一个 goroutine(g),这条语句会被编译器翻译成函数 newproc()。
// Create a new g running fn with siz bytes of arguments.
// Put it on the queue of g's waiting to run.
// The compiler turns a go statement into a call to this.
//
// The stack layout of this call is unusual: it assumes that the
// arguments to pass to fn are on the stack sequentially immediately
// after &fn. Hence, they are logically part of newproc's argument
// frame, even though they don't appear in its signature (and can't
// because their types differ between call sites).
//
// This must be nosplit because this stack layout means there are
// untyped arguments in newproc's argument frame. Stack copies won't
// be able to adjust them and stack splits won't be able to copy them.
//
//go:nosplit
func newproc(siz int32, fn *funcval) {argp := add(unsafe.Pointer(&fn), sys.PtrSize) // 上面例子 a = 1 的地位
gp := getg()
pc := getcallerpc() // 上面例子 funCaller 的 PC
systemstack(func() { // 在 g0 的堆栈上执行
newg := newproc1(fn, argp, siz, gp, pc) // 新建 g, 上面剖析源码
_p_ := getg().m.p.ptr()
// 把 newg 放到_p_的 runnext
// runqput 第三个参数如果是 True 就把 g 放到 runnext,runnext 原有的放到 runq。否则 g 放到 runq
// 如果 runq 满了就放到 sched.runq(要加锁)// 参考 https://blog.csdn.net/diaosssss/article/details/93066804
runqput(_p_, newg, true)
if mainStarted {wakep() // 上面剖析源码
}
})
}
假如是调用
go funCaller() {go funcA(a=1, b=2)
}
newproc 的调用栈, caller SP 示意 funCaller 的 SP
地位 | 值 |
---|---|
(24)caller SP | b=2 |
(16)caller SP | a=1 |
(8)caller SP | *funcA |
(0)caller SP | siz=24, sizeof(1)+sizeof(2)+sizeof(*funcA) |
(-8)caller SP | caller PC |
newproc1
// Create a new g in state _Grunnable, starting at fn, with narg bytes
// of arguments starting at argp. callerpc is the address of the go
// statement that created this. The caller is responsible for adding
// the new g to the scheduler.
//
// This must run on the system stack because it's the continuation of
// newproc, which cannot split the stack.
//
//go:systemstack
func newproc1(fn *funcval, argp unsafe.Pointer, narg int32, callergp *g, callerpc uintptr) *g {_g_ := getg()
if fn == nil {
_g_.m.throwing = -1 // do not dump full stacks
throw("go of nil func value")
}
acquirem() // disable preemption because it can be holding p in a local var,loc++
siz := narg
siz = (siz + 7) &^ 7
// We could allocate a larger initial stack if necessary.
// Not worth it: this is almost always an error.
// 4*sizeof(uintreg): extra space added below
// sizeof(uintreg): caller's LR (arm) or return address (x86, in gostartcall).
// 参数大小不能大概初始栈大小
if siz >= _StackMin-4*sys.RegSize-sys.RegSize {throw("newproc: function arguments too large for new goroutine")
}
_p_ := _g_.m.p.ptr()
newg := gfget(_p_) // 从缓存中读取 g, 详见下文
if newg == nil {newg = malg(_StackMin) // 缓存中没有 g, 新建 g。调配栈为 2k 大小的 G 对象
casgstatus(newg, _Gidle, _Gdead) // 将 g 的状态改为_Gdead
// 增加到 allg 数组,避免 gc 扫描革除掉
allgadd(newg) // publishes with a g->status of Gdead so GC scanner doesn't look at uninitialized stack.
}
if newg.stack.hi == 0 {throw("newproc1: newg missing stack")
}
if readgstatus(newg) != _Gdead {throw("newproc1: new g is not Gdead")
}
totalSize := 4*sys.RegSize + uintptr(siz) + sys.MinFrameSize // extra space in case of reads slightly beyond frame
totalSize += -totalSize & (sys.SpAlign - 1) // align to spAlign
// 新协程的栈顶计算,将栈顶减去参数占用的空间
sp := newg.stack.hi - totalSize
spArg := sp
if usesLR {
// caller's LR
*(*uintptr)(unsafe.Pointer(sp)) = 0
prepGoExitFrame(sp)
spArg += sys.MinFrameSize
}
if narg > 0 { // 如果有参数
// copy 参数到栈上
memmove(unsafe.Pointer(spArg), argp, uintptr(narg))
// This is a stack-to-stack copy. If write barriers
// are enabled and the source stack is grey (the
// destination is always black), then perform a
// barrier copy. We do this *after* the memmove
// because the destination stack may have garbage on
// it.
if writeBarrier.needed && !_g_.m.curg.gcscandone {f := findfunc(fn.fn)
stkmap := (*stackmap)(funcdata(f, _FUNCDATA_ArgsPointerMaps))
// 一些 gc 相干的工作省略
if stkmap.nbit > 0 {
// We're in the prologue, so it's always stack map index 0.
bv := stackmapdata(stkmap, 0)
bulkBarrierBitmap(spArg, spArg, uintptr(bv.n)*sys.PtrSize, 0, bv.bytedata)
}
}
}
// 初始化 G 的 gobuf,保留 sp,pc,工作函数等
memclrNoHeapPointers(unsafe.Pointer(&newg.sched), unsafe.Sizeof(newg.sched))
newg.sched.sp = sp
newg.stktopsp = sp
newg.sched.pc = funcPC(goexit) + sys.PCQuantum // +PCQuantum so that previous instruction is in same function
newg.sched.g = guintptr(unsafe.Pointer(newg))
gostartcallfn(&newg.sched, fn)
newg.gopc = callerpc
newg.ancestors = saveAncestors(callergp)
newg.startpc = fn.fn
if _g_.m.curg != nil {newg.labels = _g_.m.curg.labels}
if isSystemGoroutine(newg, false) {atomic.Xadd(&sched.ngsys, +1)
}
casgstatus(newg, _Gdead, _Grunnable)
if _p_.goidcache == _p_.goidcacheend {
// Sched.goidgen is the last allocated id,
// this batch must be [sched.goidgen+1, sched.goidgen+GoidCacheBatch].
// At startup sched.goidgen=0, so main goroutine receives goid=1.
_p_.goidcache = atomic.Xadd64(&sched.goidgen, _GoidCacheBatch)
_p_.goidcache -= _GoidCacheBatch - 1
_p_.goidcacheend = _p_.goidcache + _GoidCacheBatch
}
newg.goid = int64(_p_.goidcache)
_p_.goidcache++
if raceenabled {newg.racectx = racegostart(callerpc)
}
if trace.enabled {traceGoCreate(newg, newg.startpc)
}
releasem(_g_.m)
return newg
}
gfget
从缓存中获取 g
// Get from gfree list.
// If local list is empty, grab a batch from global list.
func gfget(_p_ *p) *g {
retry:
// 如果_p_.gFree 为空,sched.gFree.stack 或者 sched.gFree.noStack 不为空,偷最多 32 个过去
if _p_.gFree.empty() && (!sched.gFree.stack.empty() || !sched.gFree.noStack.empty()) {lock(&sched.gFree.lock)
// Move a batch of free Gs to the P.
for _p_.gFree.n < 32 {
// Prefer Gs with stacks.
gp := sched.gFree.stack.pop()
if gp == nil {gp = sched.gFree.noStack.pop()
if gp == nil {break}
}
sched.gFree.n--
_p_.gFree.push(gp)
_p_.gFree.n++
}
unlock(&sched.gFree.lock)
goto retry
}
gp := _p_.gFree.pop()
if gp == nil {return nil}
_p_.gFree.n--
if gp.stack.lo == 0 {
// Stack was deallocated in gfput. Allocate a new one.
systemstack(func() {gp.stack = stackalloc(_FixedStack)
})
gp.stackguard0 = gp.stack.lo + _StackGuard
} else {
if raceenabled {racemalloc(unsafe.Pointer(gp.stack.lo), gp.stack.hi-gp.stack.lo)
}
if msanenabled {msanmalloc(unsafe.Pointer(gp.stack.lo), gp.stack.hi-gp.stack.lo)
}
}
return gp
}
malg()
malg()函数创立一个新的 g,包含为该 g 申请栈空间(反对程序调配栈的零碎)。零碎中的每个 g 都是由该函数创立而来的
// Allocate a new g, with a stack big enough for stacksize bytes.
func malg(stacksize int32) *g {newg := new(g)
if stacksize >= 0 {stacksize = round2(_StackSystem + stacksize)
systemstack(func() {newg.stack = stackalloc(uint32(stacksize))
})
newg.stackguard0 = newg.stack.lo + _StackGuard
newg.stackguard1 = ^uintptr(0)
// Clear the bottom word of the stack. We record g
// there on gsignal stack during VDSO on ARM and ARM64.
*(*uintptr)(unsafe.Pointer(newg.stack.lo)) = 0
}
return newg
}
gfput
// Put on gfree list.
// If local list is too long, transfer a batch to the global list.
func gfput(_p_ *p, gp *g) {if readgstatus(gp) != _Gdead {throw("gfput: bad status (not Gdead)")
}
stksize := gp.stack.hi - gp.stack.lo
if stksize != _FixedStack {
// non-standard stack size - free it.
stackfree(gp.stack)
gp.stack.lo = 0
gp.stack.hi = 0
gp.stackguard0 = 0
}
_p_.gFree.push(gp)
_p_.gFree.n++
if _p_.gFree.n >= 64 {lock(&sched.gFree.lock)
for _p_.gFree.n >= 32 {
_p_.gFree.n--
gp = _p_.gFree.pop()
if gp.stack.lo == 0 {sched.gFree.noStack.push(gp)
} else {sched.gFree.stack.push(gp)
}
sched.gFree.n++
}
unlock(&sched.gFree.lock)
}
}
wakep
援用文章
[1] Go 语言底细(6):启动和内存调配初始化
https://studygolang.com/artic…