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go / go / 51a218385150c44c60d3d61c7a6493a9ca342d29 / . / src / pkg / runtime / chan.c
blob: 94ea513e7af2f066d245dc97e82f87af110e433b [file] [log] [blame]
// 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.
#include "runtime.h"
#include "type.h"
static int32 debug = 0;
enum
{
Wclosed = 0x0001, // writer has closed
Rclosed = 0x0002, // reader has seen close
Eincr = 0x0004, // increment errors
Emax = 0x0800, // error limit before throw
};
typedef struct Link Link;
typedef struct WaitQ WaitQ;
typedef struct SudoG SudoG;
typedef struct Select Select;
typedef struct Scase Scase;
struct SudoG
{
G* g; // g and selgen constitute
uint32 selgen; // a weak pointer to g
int16 offset; // offset of case number
int8 isfree; // offset of case number
SudoG* link;
byte elem[8]; // synch data element (+ more)
};
struct WaitQ
{
SudoG* first;
SudoG* last;
};
struct Hchan
{
uint32 qcount; // total data in the q
uint32 dataqsiz; // size of the circular q
uint16 elemsize;
uint16 closed; // Wclosed Rclosed errorcount
uint8 elemalign;
Alg* elemalg; // interface for element type
Link* senddataq; // pointer for sender
Link* recvdataq; // pointer for receiver
WaitQ recvq; // list of recv waiters
WaitQ sendq; // list of send waiters
SudoG* free; // freelist
Lock;
};
struct Link
{
Link* link; // asynch queue circular linked list
byte elem[8]; // asynch queue data element (+ more)
};
struct Scase
{
Hchan* chan; // chan
byte* pc; // return pc
uint16 send; // 0-recv 1-send 2-default
uint16 so; // vararg of selected bool
union {
byte elem[8]; // element (send)
byte* elemp; // pointer to element (recv)
} u;
};
struct Select
{
uint16 tcase; // total count of scase[]
uint16 ncase; // currently filled scase[]
Select* link; // for freelist
Scase* scase[1]; // one per case
};
static void dequeueg(WaitQ*, Hchan*);
static SudoG* dequeue(WaitQ*, Hchan*);
static void enqueue(WaitQ*, SudoG*);
static SudoG* allocsg(Hchan*);
static void freesg(Hchan*, SudoG*);
static uint32 gcd(uint32, uint32);
static uint32 fastrand1(void);
static uint32 fastrand2(void);
static void destroychan(Hchan*);
Hchan*
runtime·makechan_c(Type *elem, int64 hint)
{
Hchan *c;
int32 i;
if(hint < 0 || (int32)hint != hint || hint > ((uintptr)-1) / elem->size)
runtime·panicstring("makechan: size out of range");
if(elem->alg >= nelem(runtime·algarray)) {
runtime·printf("chan(alg=%d)\n", elem->alg);
runtime·throw("runtime.makechan: unsupported elem type");
}
c = runtime·mal(sizeof(*c));
runtime·addfinalizer(c, destroychan, 0);
c->elemsize = elem->size;
c->elemalg = &runtime·algarray[elem->alg];
c->elemalign = elem->align;
if(hint > 0) {
Link *d, *b, *e;
// make a circular q
b = nil;
e = nil;
for(i=0; i<hint; i++) {
d = runtime·mal(sizeof(*d) + c->elemsize - sizeof(d->elem));
if(e == nil)
e = d;
d->link = b;
b = d;
}
e->link = b;
c->recvdataq = b;
c->senddataq = b;
c->qcount = 0;
c->dataqsiz = hint;
}
if(debug)
runtime·printf("makechan: chan=%p; elemsize=%D; elemalg=%d; elemalign=%d; dataqsiz=%d\n",
c, (int64)elem->size, elem->alg, elem->align, c->dataqsiz);
return c;
}
static void
destroychan(Hchan *c)
{
runtime·destroylock(&c->Lock);
}
// makechan(elem *Type, hint int64) (hchan *chan any);
void
runtime·makechan(Type *elem, int64 hint, Hchan *ret)
{
ret = runtime·makechan_c(elem, hint);
FLUSH(&ret);
}
static void
incerr(Hchan* c)
{
c->closed += Eincr;
if(c->closed & Emax) {
// Note that channel locks may still be held at this point.
runtime·throw("too many operations on a closed channel");
}
}
/*
* generic single channel send/recv
* if the bool pointer is nil,
* then the full exchange will
* occur. if pres 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.
*/
void
runtime·chansend(Hchan *c, byte *ep, bool *pres)
{
SudoG *sg;
G* gp;
if(c == nil)
runtime·panicstring("send to nil channel");
if(runtime·gcwaiting)
runtime·gosched();
if(debug) {
runtime·printf("chansend: chan=%p; elem=", c);
c->elemalg->print(c->elemsize, ep);
runtime·prints("\n");
}
runtime·lock(c);
loop:
if(c->closed & Wclosed)
goto closed;
if(c->dataqsiz > 0)
goto asynch;
sg = dequeue(&c->recvq, c);
if(sg != nil) {
if(ep != nil)
c->elemalg->copy(c->elemsize, sg->elem, ep);
gp = sg->g;
gp->param = sg;
runtime·unlock(c);
runtime·ready(gp);
if(pres != nil)
*pres = true;
return;
}
if(pres != nil) {
runtime·unlock(c);
*pres = false;
return;
}
sg = allocsg(c);
if(ep != nil)
c->elemalg->copy(c->elemsize, sg->elem, ep);
g->param = nil;
g->status = Gwaiting;
enqueue(&c->sendq, sg);
runtime·unlock(c);
runtime·gosched();
runtime·lock(c);
sg = g->param;
if(sg == nil)
goto loop;
freesg(c, sg);
runtime·unlock(c);
return;
asynch:
if(c->closed & Wclosed)
goto closed;
if(c->qcount >= c->dataqsiz) {
if(pres != nil) {
runtime·unlock(c);
*pres = false;
return;
}
sg = allocsg(c);
g->status = Gwaiting;
enqueue(&c->sendq, sg);
runtime·unlock(c);
runtime·gosched();
runtime·lock(c);
goto asynch;
}
if(ep != nil)
c->elemalg->copy(c->elemsize, c->senddataq->elem, ep);
c->senddataq = c->senddataq->link;
c->qcount++;
sg = dequeue(&c->recvq, c);
if(sg != nil) {
gp = sg->g;
freesg(c, sg);
runtime·unlock(c);
runtime·ready(gp);
} else
runtime·unlock(c);
if(pres != nil)
*pres = true;
return;
closed:
incerr(c);
if(pres != nil)
*pres = true;
runtime·unlock(c);
}
void
runtime·chanrecv(Hchan* c, byte *ep, bool* pres)
{
SudoG *sg;
G *gp;
if(c == nil)
runtime·panicstring("receive from nil channel");
if(runtime·gcwaiting)
runtime·gosched();
if(debug)
runtime·printf("chanrecv: chan=%p\n", c);
runtime·lock(c);
loop:
if(c->dataqsiz > 0)
goto asynch;
if(c->closed & Wclosed)
goto closed;
sg = dequeue(&c->sendq, c);
if(sg != nil) {
c->elemalg->copy(c->elemsize, ep, sg->elem);
c->elemalg->copy(c->elemsize, sg->elem, nil);
gp = sg->g;
gp->param = sg;
runtime·unlock(c);
runtime·ready(gp);
if(pres != nil)
*pres = true;
return;
}
if(pres != nil) {
runtime·unlock(c);
c->elemalg->copy(c->elemsize, ep, nil);
*pres = false;
return;
}
sg = allocsg(c);
g->param = nil;
g->status = Gwaiting;
enqueue(&c->recvq, sg);
runtime·unlock(c);
runtime·gosched();
runtime·lock(c);
sg = g->param;
if(sg == nil)
goto loop;
c->elemalg->copy(c->elemsize, ep, sg->elem);
c->elemalg->copy(c->elemsize, sg->elem, nil);
freesg(c, sg);
runtime·unlock(c);
return;
asynch:
if(c->qcount <= 0) {
if(c->closed & Wclosed)
goto closed;
if(pres != nil) {
runtime·unlock(c);
c->elemalg->copy(c->elemsize, ep, nil);
*pres = false;
return;
}
sg = allocsg(c);
g->status = Gwaiting;
enqueue(&c->recvq, sg);
runtime·unlock(c);
runtime·gosched();
runtime·lock(c);
goto asynch;
}
c->elemalg->copy(c->elemsize, ep, c->recvdataq->elem);
c->elemalg->copy(c->elemsize, c->recvdataq->elem, nil);
c->recvdataq = c->recvdataq->link;
c->qcount--;
sg = dequeue(&c->sendq, c);
if(sg != nil) {
gp = sg->g;
freesg(c, sg);
runtime·unlock(c);
runtime·ready(gp);
if(pres != nil)
*pres = true;
return;
}
runtime·unlock(c);
if(pres != nil)
*pres = true;
return;
closed:
c->elemalg->copy(c->elemsize, ep, nil);
c->closed |= Rclosed;
incerr(c);
if(pres != nil)
*pres = true;
runtime·unlock(c);
}
// chansend1(hchan *chan any, elem any);
#pragma textflag 7
void
runtime·chansend1(Hchan* c, ...)
{
int32 o;
byte *ae;
if(c == nil)
runtime·panicstring("send to nil channel");
o = runtime·rnd(sizeof(c), c->elemalign);
ae = (byte*)&c + o;
runtime·chansend(c, ae, nil);
}
// chansend2(hchan *chan any, elem any) (pres bool);
#pragma textflag 7
void
runtime·chansend2(Hchan* c, ...)
{
int32 o;
byte *ae, *ap;
if(c == nil)
runtime·panicstring("send to nil channel");
o = runtime·rnd(sizeof(c), c->elemalign);
ae = (byte*)&c + o;
o = runtime·rnd(o+c->elemsize, Structrnd);
ap = (byte*)&c + o;
runtime·chansend(c, ae, ap);
}
// chanrecv1(hchan *chan any) (elem any);
#pragma textflag 7
void
runtime·chanrecv1(Hchan* c, ...)
{
int32 o;
byte *ae;
o = runtime·rnd(sizeof(c), Structrnd);
ae = (byte*)&c + o;
runtime·chanrecv(c, ae, nil);
}
// chanrecv2(hchan *chan any) (elem any, pres bool);
#pragma textflag 7
void
runtime·chanrecv2(Hchan* c, ...)
{
int32 o;
byte *ae, *ap;
o = runtime·rnd(sizeof(c), Structrnd);
ae = (byte*)&c + o;
o = runtime·rnd(o+c->elemsize, 1);
ap = (byte*)&c + o;
runtime·chanrecv(c, ae, ap);
}
// newselect(size uint32) (sel *byte);
#pragma textflag 7
void
runtime·newselect(int32 size, ...)
{
int32 n, o;
Select **selp;
Select *sel;
o = runtime·rnd(sizeof(size), Structrnd);
selp = (Select**)((byte*)&size + o);
n = 0;
if(size > 1)
n = size-1;
sel = runtime·mal(sizeof(*sel) + n*sizeof(sel->scase[0]));
sel->tcase = size;
sel->ncase = 0;
*selp = sel;
if(debug)
runtime·printf("newselect s=%p size=%d\n", sel, size);
}
// selectsend(sel *byte, hchan *chan any, elem any) (selected bool);
#pragma textflag 7
void
runtime·selectsend(Select *sel, Hchan *c, ...)
{
int32 i, eo;
Scase *cas;
byte *ae;
// nil cases do not compete
if(c == nil)
return;
i = sel->ncase;
if(i >= sel->tcase)
runtime·throw("selectsend: too many cases");
sel->ncase = i+1;
cas = runtime·mal(sizeof *cas + c->elemsize - sizeof(cas->u.elem));
sel->scase[i] = cas;
cas->pc = runtime·getcallerpc(&sel);
cas->chan = c;
eo = runtime·rnd(sizeof(sel), sizeof(c));
eo = runtime·rnd(eo+sizeof(c), c->elemsize);
cas->so = runtime·rnd(eo+c->elemsize, Structrnd);
cas->send = 1;
ae = (byte*)&sel + eo;
c->elemalg->copy(c->elemsize, cas->u.elem, ae);
if(debug)
runtime·printf("selectsend s=%p pc=%p chan=%p so=%d send=%d\n",
sel, cas->pc, cas->chan, cas->so, cas->send);
}
// selectrecv(sel *byte, hchan *chan any, elem *any) (selected bool);
#pragma textflag 7
void
runtime·selectrecv(Select *sel, Hchan *c, ...)
{
int32 i, eo;
Scase *cas;
// nil cases do not compete
if(c == nil)
return;
i = sel->ncase;
if(i >= sel->tcase)
runtime·throw("selectrecv: too many cases");
sel->ncase = i+1;
cas = runtime·mal(sizeof *cas);
sel->scase[i] = cas;
cas->pc = runtime·getcallerpc(&sel);
cas->chan = c;
eo = runtime·rnd(sizeof(sel), sizeof(c));
eo = runtime·rnd(eo+sizeof(c), sizeof(byte*));
cas->so = runtime·rnd(eo+sizeof(byte*), Structrnd);
cas->send = 0;
cas->u.elemp = *(byte**)((byte*)&sel + eo);
if(debug)
runtime·printf("selectrecv s=%p pc=%p chan=%p so=%d send=%d\n",
sel, cas->pc, cas->chan, cas->so, cas->send);
}
// selectdefaul(sel *byte) (selected bool);
#pragma textflag 7
void
runtime·selectdefault(Select *sel, ...)
{
int32 i;
Scase *cas;
i = sel->ncase;
if(i >= sel->tcase)
runtime·throw("selectdefault: too many cases");
sel->ncase = i+1;
cas = runtime·mal(sizeof *cas);
sel->scase[i] = cas;
cas->pc = runtime·getcallerpc(&sel);
cas->chan = nil;
cas->so = runtime·rnd(sizeof(sel), Structrnd);
cas->send = 2;
cas->u.elemp = nil;
if(debug)
runtime·printf("selectdefault s=%p pc=%p so=%d send=%d\n",
sel, cas->pc, cas->so, cas->send);
}
static void
freesel(Select *sel)
{
uint32 i;
for(i=0; i<sel->ncase; i++)
runtime·free(sel->scase[i]);
runtime·free(sel);
}
static void
sellock(Select *sel)
{
uint32 i;
Hchan *c;
c = nil;
for(i=0; i<sel->ncase; i++) {
if(sel->scase[i]->chan != c) {
c = sel->scase[i]->chan;
runtime·lock(c);
}
}
}
static void
selunlock(Select *sel)
{
uint32 i;
Hchan *c;
c = nil;
for(i=sel->ncase; i>0; i--) {
if(sel->scase[i-1]->chan && sel->scase[i-1]->chan != c) {
c = sel->scase[i-1]->chan;
runtime·unlock(c);
}
}
}
// selectgo(sel *byte);
//
// overwrites return pc on stack to signal which case of the select
// to run, so cannot appear at the top of a split stack.
// frame has 6 pointers and 4 int32 so 64 bytes max.
// that's less than StackGuard-StackSmall, so okay.
#pragma textflag 7
void
runtime·selectgo(Select *sel)
{
uint32 p, o, i, j;
Scase *cas, *dfl;
Hchan *c;
SudoG *sg;
G *gp;
byte *as;
if(runtime·gcwaiting)
runtime·gosched();
if(debug)
runtime·printf("select: sel=%p\n", sel);
if(sel->ncase < 2) {
if(sel->ncase < 1) {
g->status = Gwaiting; // forever
runtime·gosched();
}
// TODO: make special case of one.
}
// select a (relative) prime
for(i=0;; i++) {
p = fastrand1();
if(gcd(p, sel->ncase) == 1)
break;
if(i > 1000)
runtime·throw("select: failed to select prime");
}
// select an initial offset
o = fastrand2();
p %= sel->ncase;
o %= sel->ncase;
// sort the cases by Hchan address to get the locking order.
for(i=1; i<sel->ncase; i++) {
cas = sel->scase[i];
for(j=i; j>0 && sel->scase[j-1]->chan >= cas->chan; j--)
sel->scase[j] = sel->scase[j-1];
sel->scase[j] = cas;
}
sellock(sel);
loop:
// pass 1 - look for something already waiting
dfl = nil;
for(i=0; i<sel->ncase; i++) {
cas = sel->scase[o];
c = cas->chan;
switch(cas->send) {
case 0: // recv
if(c->dataqsiz > 0) {
if(c->qcount > 0)
goto asyncrecv;
} else {
sg = dequeue(&c->sendq, c);
if(sg != nil)
goto syncrecv;
}
if(c->closed & Wclosed)
goto rclose;
break;
case 1: // send
if(c->closed & Wclosed)
goto sclose;
if(c->dataqsiz > 0) {
if(c->qcount < c->dataqsiz)
goto asyncsend;
} else {
sg = dequeue(&c->recvq, c);
if(sg != nil)
goto syncsend;
}
break;
case 2: // default
dfl = cas;
break;
}
o += p;
if(o >= sel->ncase)
o -= sel->ncase;
}
if(dfl != nil) {
cas = dfl;
goto retc;
}
// pass 2 - enqueue on all chans
for(i=0; i<sel->ncase; i++) {
cas = sel->scase[o];
c = cas->chan;
sg = allocsg(c);
sg->offset = o;
switch(cas->send) {
case 0: // recv
if(c->dataqsiz > 0) {
if(c->qcount > 0)
runtime·throw("select: pass 2 async recv");
} else {
if(dequeue(&c->sendq, c))
runtime·throw("select: pass 2 sync recv");
}
enqueue(&c->recvq, sg);
break;
case 1: // send
if(c->dataqsiz > 0) {
if(c->qcount < c->dataqsiz)
runtime·throw("select: pass 2 async send");
} else {
if(dequeue(&c->recvq, c))
runtime·throw("select: pass 2 sync send");
c->elemalg->copy(c->elemsize, sg->elem, cas->u.elem);
}
enqueue(&c->sendq, sg);
break;
}
o += p;
if(o >= sel->ncase)
o -= sel->ncase;
}
g->param = nil;
g->status = Gwaiting;
selunlock(sel);
runtime·gosched();
sellock(sel);
sg = g->param;
// pass 3 - dequeue from unsuccessful chans
// otherwise they stack up on quiet channels
for(i=0; i<sel->ncase; i++) {
if(sg == nil || o != sg->offset) {
cas = sel->scase[o];
c = cas->chan;
if(cas->send)
dequeueg(&c->sendq, c);
else
dequeueg(&c->recvq, c);
}
o += p;
if(o >= sel->ncase)
o -= sel->ncase;
}
if(sg == nil)
goto loop;
o = sg->offset;
cas = sel->scase[o];
c = cas->chan;
if(c->dataqsiz > 0) {
// prints("shouldnt happen\n");
goto loop;
}
if(debug)
runtime·printf("wait-return: sel=%p c=%p cas=%p send=%d o=%d\n",
sel, c, cas, cas->send, o);
if(!cas->send) {
if(cas->u.elemp != nil)
c->elemalg->copy(c->elemsize, cas->u.elemp, sg->elem);
c->elemalg->copy(c->elemsize, sg->elem, nil);
}
freesg(c, sg);
goto retc;
asyncrecv:
// can receive from buffer
if(cas->u.elemp != nil)
c->elemalg->copy(c->elemsize, cas->u.elemp, c->recvdataq->elem);
c->elemalg->copy(c->elemsize, c->recvdataq->elem, nil);
c->recvdataq = c->recvdataq->link;
c->qcount--;
sg = dequeue(&c->sendq, c);
if(sg != nil) {
gp = sg->g;
freesg(c, sg);
runtime·ready(gp);
}
goto retc;
asyncsend:
// can send to buffer
if(cas->u.elem != nil)
c->elemalg->copy(c->elemsize, c->senddataq->elem, cas->u.elem);
c->senddataq = c->senddataq->link;
c->qcount++;
sg = dequeue(&c->recvq, c);
if(sg != nil) {
gp = sg->g;
freesg(c, sg);
runtime·ready(gp);
}
goto retc;
syncrecv:
// can receive from sleeping sender (sg)
if(debug)
runtime·printf("syncrecv: sel=%p c=%p o=%d\n", sel, c, o);
if(cas->u.elemp != nil)
c->elemalg->copy(c->elemsize, cas->u.elemp, sg->elem);
c->elemalg->copy(c->elemsize, sg->elem, nil);
gp = sg->g;
gp->param = sg;
runtime·ready(gp);
goto retc;
rclose:
// read at end of closed channel
if(cas->u.elemp != nil)
c->elemalg->copy(c->elemsize, cas->u.elemp, nil);
c->closed |= Rclosed;
incerr(c);
goto retc;
syncsend:
// can send to sleeping receiver (sg)
if(debug)
runtime·printf("syncsend: sel=%p c=%p o=%d\n", sel, c, o);
if(c->closed & Wclosed)
goto sclose;
c->elemalg->copy(c->elemsize, sg->elem, cas->u.elem);
gp = sg->g;
gp->param = sg;
runtime·ready(gp);
goto retc;
sclose:
// send on closed channel
incerr(c);
goto retc;
retc:
selunlock(sel);
// return to pc corresponding to chosen case
runtime·setcallerpc(&sel, cas->pc);
as = (byte*)&sel + cas->so;
freesel(sel);
*as = true;
}
// closechan(sel *byte);
void
runtime·closechan(Hchan *c)
{
SudoG *sg;
G* gp;
if(runtime·gcwaiting)
runtime·gosched();
runtime·lock(c);
incerr(c);
c->closed |= Wclosed;
// release all readers
for(;;) {
sg = dequeue(&c->recvq, c);
if(sg == nil)
break;
gp = sg->g;
gp->param = nil;
freesg(c, sg);
runtime·ready(gp);
}
// release all writers
for(;;) {
sg = dequeue(&c->sendq, c);
if(sg == nil)
break;
gp = sg->g;
gp->param = nil;
freesg(c, sg);
runtime·ready(gp);
}
runtime·unlock(c);
}
void
runtime·chanclose(Hchan *c)
{
runtime·closechan(c);
}
bool
runtime·chanclosed(Hchan *c)
{
return (c->closed & Rclosed) != 0;
}
int32
runtime·chanlen(Hchan *c)
{
return c->qcount;
}
int32
runtime·chancap(Hchan *c)
{
return c->dataqsiz;
}
// closedchan(sel *byte) bool;
void
runtime·closedchan(Hchan *c, bool closed)
{
closed = runtime·chanclosed(c);
FLUSH(&closed);
}
static SudoG*
dequeue(WaitQ *q, Hchan *c)
{
SudoG *sgp;
loop:
sgp = q->first;
if(sgp == nil)
return nil;
q->first = sgp->link;
// if sgp is stale, ignore it
if(!runtime·cas(&sgp->g->selgen, sgp->selgen, sgp->selgen + 1)) {
//prints("INVALID PSEUDOG POINTER\n");
freesg(c, sgp);
goto loop;
}
return sgp;
}
static void
dequeueg(WaitQ *q, Hchan *c)
{
SudoG **l, *sgp;
for(l=&q->first; (sgp=*l) != nil; l=&sgp->link) {
if(sgp->g == g) {
*l = sgp->link;
freesg(c, sgp);
break;
}
}
}
static void
enqueue(WaitQ *q, SudoG *sgp)
{
sgp->link = nil;
if(q->first == nil) {
q->first = sgp;
q->last = sgp;
return;
}
q->last->link = sgp;
q->last = sgp;
}
static SudoG*
allocsg(Hchan *c)
{
SudoG* sg;
sg = c->free;
if(sg != nil) {
c->free = sg->link;
} else
sg = runtime·mal(sizeof(*sg) + c->elemsize - sizeof(sg->elem));
sg->selgen = g->selgen;
sg->g = g;
sg->offset = 0;
sg->isfree = 0;
return sg;
}
static void
freesg(Hchan *c, SudoG *sg)
{
if(sg != nil) {
if(sg->isfree)
runtime·throw("chan.freesg: already free");
sg->isfree = 1;
sg->link = c->free;
c->free = sg;
}
}
static uint32
gcd(uint32 u, uint32 v)
{
for(;;) {
if(u > v) {
if(v == 0)
return u;
u = u%v;
continue;
}
if(u == 0)
return v;
v = v%u;
}
}
static uint32
fastrand1(void)
{
static uint32 x = 0x49f6428aUL;
x += x;
if(x & 0x80000000L)
x ^= 0x88888eefUL;
return x;
}
static uint32
fastrand2(void)
{
static uint32 x = 0x49f6428aUL;
x += x;
if(x & 0x80000000L)
x ^= 0xfafd871bUL;
return x;
}