src/cmd/8g/ggen.c - go - Git at Google

 // 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.

 #undef	EXTERN
 #define	EXTERN
 #include <u.h>
 #include <libc.h>
 #include "gg.h"
 #include "opt.h"

 void
 defframe(Prog *ptxt)
 {
 	// fill in argument size
 	ptxt->to.offset2 = rnd(curfn->type->argwid, widthptr);

 	// fill in final stack size
 	if(stksize > maxstksize)
 		maxstksize = stksize;
 	ptxt->to.offset = rnd(maxstksize+maxarg, widthptr);
 	maxstksize = 0;
 }

 // Sweep the prog list to mark any used nodes.
 void
 markautoused(Prog* p)
 {
 	for (; p; p = p->link) {
 		if (p->from.type == D_AUTO && p->from.node)
 			p->from.node->used = 1;

 		if (p->to.type == D_AUTO && p->to.node)
 			p->to.node->used = 1;
 	}
 }

 // Fixup instructions after compactframe has moved all autos around.
 void
 fixautoused(Prog* p)
 {
 	for (; p; p = p->link) {
 		if (p->from.type == D_AUTO && p->from.node)
 			p->from.offset += p->from.node->stkdelta;

 		if (p->to.type == D_AUTO && p->to.node)
 			p->to.offset += p->to.node->stkdelta;
 	}
 }

 void
 clearfat(Node *nl)
 {
 	uint32 w, c, q;
 	Node n1;

 	/* clear a fat object */
 	if(debug['g'])
 		dump("\nclearfat", nl);

 	w = nl->type->width;
 	if(w == 8 || w == 12)
 		if(componentgen(N, nl))
 			return;

 	c = w % 4;	// bytes
 	q = w / 4;	// quads

 	gconreg(AMOVL, 0, D_AX);
 	nodreg(&n1, types[tptr], D_DI);
 	agen(nl, &n1);

 	if(q >= 4) {
 		gconreg(AMOVL, q, D_CX);
 		gins(AREP, N, N);	// repeat
 		gins(ASTOSL, N, N);	// STOL AL,*(DI)+
 	} else
 	while(q > 0) {
 		gins(ASTOSL, N, N);	// STOL AL,*(DI)+
 		q--;
 	}

 	if(c >= 4) {
 		gconreg(AMOVL, c, D_CX);
 		gins(AREP, N, N);	// repeat
 		gins(ASTOSB, N, N);	// STOB AL,*(DI)+
 	} else
 	while(c > 0) {
 		gins(ASTOSB, N, N);	// STOB AL,*(DI)+
 		c--;
 	}
 }

 /*
  * generate:
  *	call f
  *	proc=0	normal call
  *	proc=1	goroutine run in new proc
  *	proc=2	defer call save away stack
  */
 void
 ginscall(Node *f, int proc)
 {
 	Prog *p;
 	Node reg, con;

 	switch(proc) {
 	default:
 		fatal("ginscall: bad proc %d", proc);
 		break;

 	case 0:	// normal call
 	case -1:	// normal call but no return
 		p = gins(ACALL, N, f);
 		afunclit(&p->to);
 		if(proc == -1 || noreturn(p))
 			gins(AUNDEF, N, N);
 		break;

 	case 1:	// call in new proc (go)
 	case 2:	// deferred call (defer)
 		nodreg(&reg, types[TINT32], D_CX);
 		gins(APUSHL, f, N);
 		nodconst(&con, types[TINT32], argsize(f->type));
 		gins(APUSHL, &con, N);
 		if(proc == 1)
 			ginscall(newproc, 0);
 		else
 			ginscall(deferproc, 0);
 		gins(APOPL, N, &reg);
 		gins(APOPL, N, &reg);
 		if(proc == 2) {
 			nodreg(&reg, types[TINT64], D_AX);
 			gins(ATESTL, &reg, &reg);
 			patch(gbranch(AJNE, T, -1), retpc);
 		}
 		break;
 	}
 }

 /*
  * n is call to interface method.
  * generate res = n.
  */
 void
 cgen_callinter(Node *n, Node *res, int proc)
 {
 	Node *i, *f;
 	Node tmpi, nodo, nodr, nodsp;

 	i = n->left;
 	if(i->op != ODOTINTER)
 		fatal("cgen_callinter: not ODOTINTER %O", i->op);

 	f = i->right;		// field
 	if(f->op != ONAME)
 		fatal("cgen_callinter: not ONAME %O", f->op);

 	i = i->left;		// interface

 	if(!i->addable) {
 		tempname(&tmpi, i->type);
 		cgen(i, &tmpi);
 		i = &tmpi;
 	}

 	genlist(n->list);		// assign the args

 	// Can regalloc now; i is known to be addable,
 	// so the agen will be easy.
 	regalloc(&nodr, types[tptr], res);
 	regalloc(&nodo, types[tptr], &nodr);
 	nodo.op = OINDREG;

 	agen(i, &nodr);		// REG = &inter

 	nodindreg(&nodsp, types[tptr], D_SP);
 	nodo.xoffset += widthptr;
 	cgen(&nodo, &nodsp);	// 0(SP) = 4(REG) -- i.data

 	nodo.xoffset -= widthptr;
 	cgen(&nodo, &nodr);	// REG = 0(REG) -- i.tab

 	if(n->left->xoffset == BADWIDTH)
 		fatal("cgen_callinter: badwidth");
 	nodo.xoffset = n->left->xoffset + 3*widthptr + 8;
 	cgen(&nodo, &nodr);	// REG = 20+offset(REG) -- i.tab->fun[f]

 	// BOTCH nodr.type = fntype;
 	nodr.type = n->left->type;
 	ginscall(&nodr, proc);

 	regfree(&nodr);
 	regfree(&nodo);

 	setmaxarg(n->left->type);
 }

 /*
  * generate function call;
  *	proc=0	normal call
  *	proc=1	goroutine run in new proc
  *	proc=2	defer call save away stack
  */
 void
 cgen_call(Node *n, int proc)
 {
 	Type *t;
 	Node nod, afun;

 	if(n == N)
 		return;

 	if(n->left->ullman >= UINF) {
 		// if name involves a fn call
 		// precompute the address of the fn
 		tempname(&afun, types[tptr]);
 		cgen(n->left, &afun);
 	}

 	genlist(n->list);		// assign the args
 	t = n->left->type;

 	setmaxarg(t);

 	// call tempname pointer
 	if(n->left->ullman >= UINF) {
 		regalloc(&nod, types[tptr], N);
 		cgen_as(&nod, &afun);
 		nod.type = t;
 		ginscall(&nod, proc);
 		regfree(&nod);
 		return;
 	}

 	// call pointer
 	if(n->left->op != ONAME || n->left->class != PFUNC) {
 		regalloc(&nod, types[tptr], N);
 		cgen_as(&nod, n->left);
 		nod.type = t;
 		ginscall(&nod, proc);
 		regfree(&nod);
 		return;
 	}

 	// call direct
 	n->left->method = 1;
 	ginscall(n->left, proc);
 }

 /*
  * call to n has already been generated.
  * generate:
  *	res = return value from call.
  */
 void
 cgen_callret(Node *n, Node *res)
 {
 	Node nod;
 	Type *fp, *t;
 	Iter flist;

 	t = n->left->type;
 	if(t->etype == TPTR32 || t->etype == TPTR64)
 		t = t->type;

 	fp = structfirst(&flist, getoutarg(t));
 	if(fp == T)
 		fatal("cgen_callret: nil");

 	memset(&nod, 0, sizeof(nod));
 	nod.op = OINDREG;
 	nod.val.u.reg = D_SP;
 	nod.addable = 1;

 	nod.xoffset = fp->width;
 	nod.type = fp->type;
 	cgen_as(res, &nod);
 }

 /*
  * call to n has already been generated.
  * generate:
  *	res = &return value from call.
  */
 void
 cgen_aret(Node *n, Node *res)
 {
 	Node nod1, nod2;
 	Type *fp, *t;
 	Iter flist;

 	t = n->left->type;
 	if(isptr[t->etype])
 		t = t->type;

 	fp = structfirst(&flist, getoutarg(t));
 	if(fp == T)
 		fatal("cgen_aret: nil");

 	memset(&nod1, 0, sizeof(nod1));
 	nod1.op = OINDREG;
 	nod1.val.u.reg = D_SP;
 	nod1.addable = 1;

 	nod1.xoffset = fp->width;
 	nod1.type = fp->type;

 	if(res->op != OREGISTER) {
 		regalloc(&nod2, types[tptr], res);
 		gins(ALEAL, &nod1, &nod2);
 		gins(AMOVL, &nod2, res);
 		regfree(&nod2);
 	} else
 		gins(ALEAL, &nod1, res);
 }

 /*
  * generate return.
  * n->left is assignments to return values.
  */
 void
 cgen_ret(Node *n)
 {
 	genlist(n->list);		// copy out args
 	if(retpc)
 		gjmp(retpc);
 	else
 		gins(ARET, N, N);
 }

 /*
  * generate += *= etc.
  */
 void
 cgen_asop(Node *n)
 {
 	Node n1, n2, n3, n4;
 	Node *nl, *nr;
 	Prog *p1;
 	Addr addr;
 	int a;

 	nl = n->left;
 	nr = n->right;

 	if(nr->ullman >= UINF && nl->ullman >= UINF) {
 		tempname(&n1, nr->type);
 		cgen(nr, &n1);
 		n2 = *n;
 		n2.right = &n1;
 		cgen_asop(&n2);
 		goto ret;
 	}

 	if(!isint[nl->type->etype])
 		goto hard;
 	if(!isint[nr->type->etype])
 		goto hard;
 	if(is64(nl->type) || is64(nr->type))
 		goto hard;

 	switch(n->etype) {
 	case OADD:
 		if(smallintconst(nr))
 		if(mpgetfix(nr->val.u.xval) == 1) {
 			a = optoas(OINC, nl->type);
 			if(nl->addable) {
 				gins(a, N, nl);
 				goto ret;
 			}
 			if(sudoaddable(a, nl, &addr)) {
 				p1 = gins(a, N, N);
 				p1->to = addr;
 				sudoclean();
 				goto ret;
 			}
 		}
 		break;

 	case OSUB:
 		if(smallintconst(nr))
 		if(mpgetfix(nr->val.u.xval) == 1) {
 			a = optoas(ODEC, nl->type);
 			if(nl->addable) {
 				gins(a, N, nl);
 				goto ret;
 			}
 			if(sudoaddable(a, nl, &addr)) {
 				p1 = gins(a, N, N);
 				p1->to = addr;
 				sudoclean();
 				goto ret;
 			}
 		}
 		break;
 	}

 	switch(n->etype) {
 	case OADD:
 	case OSUB:
 	case OXOR:
 	case OAND:
 	case OOR:
 		a = optoas(n->etype, nl->type);
 		if(nl->addable) {
 			if(smallintconst(nr)) {
 				gins(a, nr, nl);
 				goto ret;
 			}
 			regalloc(&n2, nr->type, N);
 			cgen(nr, &n2);
 			gins(a, &n2, nl);
 			regfree(&n2);
 			goto ret;
 		}
 		if(nr->ullman < UINF)
 		if(sudoaddable(a, nl, &addr)) {
 			if(smallintconst(nr)) {
 				p1 = gins(a, nr, N);
 				p1->to = addr;
 				sudoclean();
 				goto ret;
 			}
 			regalloc(&n2, nr->type, N);
 			cgen(nr, &n2);
 			p1 = gins(a, &n2, N);
 			p1->to = addr;
 			regfree(&n2);
 			sudoclean();
 			goto ret;
 		}
 	}

 hard:
 	n2.op = 0;
 	n1.op = 0;
 	if(nr->ullman >= nl->ullman || nl->addable) {
 		mgen(nr, &n2, N);
 		nr = &n2;
 	} else {
 		tempname(&n2, nr->type);
 		cgen(nr, &n2);
 		nr = &n2;
 	}
 	if(!nl->addable) {
 		igen(nl, &n1, N);
 		nl = &n1;
 	}

 	n3 = *n;
 	n3.left = nl;
 	n3.right = nr;
 	n3.op = n->etype;

 	mgen(&n3, &n4, N);
 	gmove(&n4, nl);

 	if(n1.op)
 		regfree(&n1);
 	mfree(&n2);
 	mfree(&n4);

 ret:
 	;
 }

 int
 samereg(Node *a, Node *b)
 {
 	if(a->op != OREGISTER)
 		return 0;
 	if(b->op != OREGISTER)
 		return 0;
 	if(a->val.u.reg != b->val.u.reg)
 		return 0;
 	return 1;
 }

 /*
  * generate division.
  * caller must set:
  *	ax = allocated AX register
  *	dx = allocated DX register
  * generates one of:
  *	res = nl / nr
  *	res = nl % nr
  * according to op.
  */
 void
 dodiv(int op, Node *nl, Node *nr, Node *res, Node *ax, Node *dx)
 {
 	int check;
 	Node n1, t1, t2, t3, t4, n4, nz;
 	Type *t, *t0;
 	Prog *p1, *p2, *p3;

 	// Have to be careful about handling
 	// most negative int divided by -1 correctly.
 	// The hardware will trap.
 	// Also the byte divide instruction needs AH,
 	// which we otherwise don't have to deal with.
 	// Easiest way to avoid for int8, int16: use int32.
 	// For int32 and int64, use explicit test.
 	// Could use int64 hw for int32.
 	t = nl->type;
 	t0 = t;
 	check = 0;
 	if(issigned[t->etype]) {
 		check = 1;
 		if(isconst(nl, CTINT) && mpgetfix(nl->val.u.xval) != -1LL<<(t->width*8-1))
 			check = 0;
 		else if(isconst(nr, CTINT) && mpgetfix(nr->val.u.xval) != -1)
 			check = 0;
 	}
 	if(t->width < 4) {
 		if(issigned[t->etype])
 			t = types[TINT32];
 		else
 			t = types[TUINT32];
 		check = 0;
 	}

 	tempname(&t1, t);
 	tempname(&t2, t);
 	if(t0 != t) {
 		tempname(&t3, t0);
 		tempname(&t4, t0);
 		cgen(nl, &t3);
 		cgen(nr, &t4);
 		// Convert.
 		gmove(&t3, &t1);
 		gmove(&t4, &t2);
 	} else {
 		cgen(nl, &t1);
 		cgen(nr, &t2);
 	}

 	if(!samereg(ax, res) && !samereg(dx, res))
 		regalloc(&n1, t, res);
 	else
 		regalloc(&n1, t, N);
 	gmove(&t2, &n1);
 	gmove(&t1, ax);
 	p3 = P;
 	if(check) {
 		nodconst(&n4, t, -1);
 		gins(optoas(OCMP, t), &n1, &n4);
 		p1 = gbranch(optoas(ONE, t), T, +1);
 		nodconst(&n4, t, -1LL<<(t->width*8-1));
 		gins(optoas(OCMP, t), ax, &n4);
 		p2 = gbranch(optoas(ONE, t), T, +1);
 		if(op == ODIV)
 			gmove(&n4, res);
 		if(op == OMOD) {
 			nodconst(&n4, t, 0);
 			gmove(&n4, res);
 		}
 		p3 = gbranch(AJMP, T, 0);
 		patch(p1, pc);
 		patch(p2, pc);
 	}
 	if(!issigned[t->etype]) {
 		nodconst(&nz, t, 0);
 		gmove(&nz, dx);
 	} else
 		gins(optoas(OEXTEND, t), N, N);
 	gins(optoas(op, t), &n1, N);
 	regfree(&n1);

 	if(op == ODIV)
 		gmove(ax, res);
 	else
 		gmove(dx, res);
 	if(check)
 		patch(p3, pc);
 }

 static void
 savex(int dr, Node *x, Node *oldx, Node *res, Type *t)
 {
 	int r;

 	r = reg[dr];
 	nodreg(x, types[TINT32], dr);

 	// save current ax and dx if they are live
 	// and not the destination
 	memset(oldx, 0, sizeof *oldx);
 	if(r > 0 && !samereg(x, res)) {
 		tempname(oldx, types[TINT32]);
 		gmove(x, oldx);
 	}

 	regalloc(x, t, x);
 }

 static void
 restx(Node *x, Node *oldx)
 {
 	regfree(x);

 	if(oldx->op != 0) {
 		x->type = types[TINT32];
 		gmove(oldx, x);
 	}
 }

 /*
  * generate division according to op, one of:
  *	res = nl / nr
  *	res = nl % nr
  */
 void
 cgen_div(int op, Node *nl, Node *nr, Node *res)
 {
 	Node ax, dx, oldax, olddx;
 	Type *t;

 	if(is64(nl->type))
 		fatal("cgen_div %T", nl->type);

 	if(issigned[nl->type->etype])
 		t = types[TINT32];
 	else
 		t = types[TUINT32];
 	savex(D_AX, &ax, &oldax, res, t);
 	savex(D_DX, &dx, &olddx, res, t);
 	dodiv(op, nl, nr, res, &ax, &dx);
 	restx(&dx, &olddx);
 	restx(&ax, &oldax);
 }

 /*
  * generate shift according to op, one of:
  *	res = nl << nr
  *	res = nl >> nr
  */
 void
 cgen_shift(int op, int bounded, Node *nl, Node *nr, Node *res)
 {
 	Node n1, n2, nt, cx, oldcx, hi, lo;
 	int a, w;
 	Prog *p1, *p2;
 	uvlong sc;

 	if(nl->type->width > 4)
 		fatal("cgen_shift %T", nl->type);

 	w = nl->type->width * 8;

 	a = optoas(op, nl->type);

 	if(nr->op == OLITERAL) {
 		tempname(&n2, nl->type);
 		cgen(nl, &n2);
 		regalloc(&n1, nl->type, res);
 		gmove(&n2, &n1);
 		sc = mpgetfix(nr->val.u.xval);
 		if(sc >= nl->type->width*8) {
 			// large shift gets 2 shifts by width-1
 			gins(a, ncon(w-1), &n1);
 			gins(a, ncon(w-1), &n1);
 		} else
 			gins(a, nr, &n1);
 		gmove(&n1, res);
 		regfree(&n1);
 		return;
 	}

 	memset(&oldcx, 0, sizeof oldcx);
 	nodreg(&cx, types[TUINT32], D_CX);
 	if(reg[D_CX] > 1 && !samereg(&cx, res)) {
 		tempname(&oldcx, types[TUINT32]);
 		gmove(&cx, &oldcx);
 	}

 	if(nr->type->width > 4) {
 		tempname(&nt, nr->type);
 		n1 = nt;
 	} else {
 		nodreg(&n1, types[TUINT32], D_CX);
 		regalloc(&n1, nr->type, &n1);		// to hold the shift type in CX
 	}

 	if(samereg(&cx, res))
 		regalloc(&n2, nl->type, N);
 	else
 		regalloc(&n2, nl->type, res);
 	if(nl->ullman >= nr->ullman) {
 		cgen(nl, &n2);
 		cgen(nr, &n1);
 	} else {
 		cgen(nr, &n1);
 		cgen(nl, &n2);
 	}

 	// test and fix up large shifts
 	if(bounded) {
 		if(nr->type->width > 4) {
 			// delayed reg alloc
 			nodreg(&n1, types[TUINT32], D_CX);
 			regalloc(&n1, types[TUINT32], &n1);		// to hold the shift type in CX
 			split64(&nt, &lo, &hi);
 			gmove(&lo, &n1);
 		}
 	} else {
 		if(nr->type->width > 4) {
 			// delayed reg alloc
 			nodreg(&n1, types[TUINT32], D_CX);
 			regalloc(&n1, types[TUINT32], &n1);		// to hold the shift type in CX
 			split64(&nt, &lo, &hi);
 			gmove(&lo, &n1);
 			gins(optoas(OCMP, types[TUINT32]), &hi, ncon(0));
 			p2 = gbranch(optoas(ONE, types[TUINT32]), T, +1);
 			gins(optoas(OCMP, types[TUINT32]), &n1, ncon(w));
 			p1 = gbranch(optoas(OLT, types[TUINT32]), T, +1);
 			patch(p2, pc);
 		} else {
 			gins(optoas(OCMP, nr->type), &n1, ncon(w));
 			p1 = gbranch(optoas(OLT, types[TUINT32]), T, +1);
 		}
 		if(op == ORSH && issigned[nl->type->etype]) {
 			gins(a, ncon(w-1), &n2);
 		} else {
 			gmove(ncon(0), &n2);
 		}
 		patch(p1, pc);
 	}
 	gins(a, &n1, &n2);

 	if(oldcx.op != 0)
 		gmove(&oldcx, &cx);

 	gmove(&n2, res);

 	regfree(&n1);
 	regfree(&n2);
 }

 /*
  * generate byte multiply:
  *	res = nl * nr
  * no byte multiply instruction so have to do
  * 16-bit multiply and take bottom half.
  */
 void
 cgen_bmul(int op, Node *nl, Node *nr, Node *res)
 {
 	Node n1b, n2b, n1w, n2w;
 	Type *t;
 	int a;

 	if(nl->ullman >= nr->ullman) {
 		regalloc(&n1b, nl->type, res);
 		cgen(nl, &n1b);
 		regalloc(&n2b, nr->type, N);
 		cgen(nr, &n2b);
 	} else {
 		regalloc(&n2b, nr->type, N);
 		cgen(nr, &n2b);
 		regalloc(&n1b, nl->type, res);
 		cgen(nl, &n1b);
 	}

 	// copy from byte to short registers
 	t = types[TUINT16];
 	if(issigned[nl->type->etype])
 		t = types[TINT16];

 	regalloc(&n2w, t, &n2b);
 	cgen(&n2b, &n2w);

 	regalloc(&n1w, t, &n1b);
 	cgen(&n1b, &n1w);

 	a = optoas(op, t);
 	gins(a, &n2w, &n1w);
 	cgen(&n1w, &n1b);
 	cgen(&n1b, res);

 	regfree(&n1w);
 	regfree(&n2w);
 	regfree(&n1b);
 	regfree(&n2b);
 }
	// 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.

	#undef EXTERN
	#define EXTERN
	#include <u.h>
	#include <libc.h>
	#include "gg.h"
	#include "opt.h"

	void
	defframe(Prog *ptxt)
	{
	// fill in argument size
	ptxt->to.offset2 = rnd(curfn->type->argwid, widthptr);

	// fill in final stack size
	if(stksize > maxstksize)
	maxstksize = stksize;
	ptxt->to.offset = rnd(maxstksize+maxarg, widthptr);
	maxstksize = 0;
	}

	// Sweep the prog list to mark any used nodes.
	void
	markautoused(Prog* p)
	{
	for (; p; p = p->link) {
	if (p->from.type == D_AUTO && p->from.node)
	p->from.node->used = 1;

	if (p->to.type == D_AUTO && p->to.node)
	p->to.node->used = 1;
	}
	}

	// Fixup instructions after compactframe has moved all autos around.
	void
	fixautoused(Prog* p)
	{
	for (; p; p = p->link) {
	if (p->from.type == D_AUTO && p->from.node)
	p->from.offset += p->from.node->stkdelta;

	if (p->to.type == D_AUTO && p->to.node)
	p->to.offset += p->to.node->stkdelta;
	}
	}

	void
	clearfat(Node *nl)
	{
	uint32 w, c, q;
	Node n1;

	/* clear a fat object */
	if(debug['g'])
	dump("\nclearfat", nl);

	w = nl->type->width;
	if(w == 8 \|\| w == 12)
	if(componentgen(N, nl))
	return;

	c = w % 4; // bytes
	q = w / 4; // quads

	gconreg(AMOVL, 0, D_AX);
	nodreg(&n1, types[tptr], D_DI);
	agen(nl, &n1);

	if(q >= 4) {
	gconreg(AMOVL, q, D_CX);
	gins(AREP, N, N); // repeat
	gins(ASTOSL, N, N); // STOL AL,*(DI)+
	} else
	while(q > 0) {
	gins(ASTOSL, N, N); // STOL AL,*(DI)+
	q--;
	}

	if(c >= 4) {
	gconreg(AMOVL, c, D_CX);
	gins(AREP, N, N); // repeat
	gins(ASTOSB, N, N); // STOB AL,*(DI)+
	} else
	while(c > 0) {
	gins(ASTOSB, N, N); // STOB AL,*(DI)+
	c--;
	}
	}

	/*
	* generate:
	* call f
	* proc=0 normal call
	* proc=1 goroutine run in new proc
	* proc=2 defer call save away stack
	*/
	void
	ginscall(Node *f, int proc)
	{
	Prog *p;
	Node reg, con;

	switch(proc) {
	default:
	fatal("ginscall: bad proc %d", proc);
	break;

	case 0: // normal call
	case -1: // normal call but no return
	p = gins(ACALL, N, f);
	afunclit(&p->to);
	if(proc == -1 \|\| noreturn(p))
	gins(AUNDEF, N, N);
	break;

	case 1: // call in new proc (go)
	case 2: // deferred call (defer)
	nodreg(&reg, types[TINT32], D_CX);
	gins(APUSHL, f, N);
	nodconst(&con, types[TINT32], argsize(f->type));
	gins(APUSHL, &con, N);
	if(proc == 1)
	ginscall(newproc, 0);
	else
	ginscall(deferproc, 0);
	gins(APOPL, N, &reg);
	gins(APOPL, N, &reg);
	if(proc == 2) {
	nodreg(&reg, types[TINT64], D_AX);
	gins(ATESTL, &reg, &reg);
	patch(gbranch(AJNE, T, -1), retpc);
	}
	break;
	}
	}

	/*
	* n is call to interface method.
	* generate res = n.
	*/
	void
	cgen_callinter(Node n, Node res, int proc)
	{
	Node i, f;
	Node tmpi, nodo, nodr, nodsp;

	i = n->left;
	if(i->op != ODOTINTER)
	fatal("cgen_callinter: not ODOTINTER %O", i->op);

	f = i->right; // field
	if(f->op != ONAME)
	fatal("cgen_callinter: not ONAME %O", f->op);

	i = i->left; // interface

	if(!i->addable) {
	tempname(&tmpi, i->type);
	cgen(i, &tmpi);
	i = &tmpi;
	}

	genlist(n->list); // assign the args

	// Can regalloc now; i is known to be addable,
	// so the agen will be easy.
	regalloc(&nodr, types[tptr], res);
	regalloc(&nodo, types[tptr], &nodr);
	nodo.op = OINDREG;

	agen(i, &nodr); // REG = &inter

	nodindreg(&nodsp, types[tptr], D_SP);
	nodo.xoffset += widthptr;
	cgen(&nodo, &nodsp); // 0(SP) = 4(REG) -- i.data

	nodo.xoffset -= widthptr;
	cgen(&nodo, &nodr); // REG = 0(REG) -- i.tab

	if(n->left->xoffset == BADWIDTH)
	fatal("cgen_callinter: badwidth");
	nodo.xoffset = n->left->xoffset + 3*widthptr + 8;
	cgen(&nodo, &nodr); // REG = 20+offset(REG) -- i.tab->fun[f]

	// BOTCH nodr.type = fntype;
	nodr.type = n->left->type;
	ginscall(&nodr, proc);

	regfree(&nodr);
	regfree(&nodo);

	setmaxarg(n->left->type);
	}

	/*
	* generate function call;
	* proc=0 normal call
	* proc=1 goroutine run in new proc
	* proc=2 defer call save away stack
	*/
	void
	cgen_call(Node *n, int proc)
	{
	Type *t;
	Node nod, afun;

	if(n == N)
	return;

	if(n->left->ullman >= UINF) {
	// if name involves a fn call
	// precompute the address of the fn
	tempname(&afun, types[tptr]);
	cgen(n->left, &afun);
	}

	genlist(n->list); // assign the args
	t = n->left->type;

	setmaxarg(t);

	// call tempname pointer
	if(n->left->ullman >= UINF) {
	regalloc(&nod, types[tptr], N);
	cgen_as(&nod, &afun);
	nod.type = t;
	ginscall(&nod, proc);
	regfree(&nod);
	return;
	}

	// call pointer
	if(n->left->op != ONAME \|\| n->left->class != PFUNC) {
	regalloc(&nod, types[tptr], N);
	cgen_as(&nod, n->left);
	nod.type = t;
	ginscall(&nod, proc);
	regfree(&nod);
	return;
	}

	// call direct
	n->left->method = 1;
	ginscall(n->left, proc);
	}

	/*
	* call to n has already been generated.
	* generate:
	* res = return value from call.
	*/
	void
	cgen_callret(Node n, Node res)
	{
	Node nod;
	Type fp, t;
	Iter flist;

	t = n->left->type;
	if(t->etype == TPTR32 \|\| t->etype == TPTR64)
	t = t->type;

	fp = structfirst(&flist, getoutarg(t));
	if(fp == T)
	fatal("cgen_callret: nil");

	memset(&nod, 0, sizeof(nod));
	nod.op = OINDREG;
	nod.val.u.reg = D_SP;
	nod.addable = 1;

	nod.xoffset = fp->width;
	nod.type = fp->type;
	cgen_as(res, &nod);
	}

	/*
	* call to n has already been generated.
	* generate:
	* res = &return value from call.
	*/
	void
	cgen_aret(Node n, Node res)
	{
	Node nod1, nod2;
	Type fp, t;
	Iter flist;

	t = n->left->type;
	if(isptr[t->etype])
	t = t->type;

	fp = structfirst(&flist, getoutarg(t));
	if(fp == T)
	fatal("cgen_aret: nil");

	memset(&nod1, 0, sizeof(nod1));
	nod1.op = OINDREG;
	nod1.val.u.reg = D_SP;
	nod1.addable = 1;

	nod1.xoffset = fp->width;
	nod1.type = fp->type;

	if(res->op != OREGISTER) {
	regalloc(&nod2, types[tptr], res);
	gins(ALEAL, &nod1, &nod2);
	gins(AMOVL, &nod2, res);
	regfree(&nod2);
	} else
	gins(ALEAL, &nod1, res);
	}

	/*
	* generate return.
	* n->left is assignments to return values.
	*/
	void
	cgen_ret(Node *n)
	{
	genlist(n->list); // copy out args
	if(retpc)
	gjmp(retpc);
	else
	gins(ARET, N, N);
	}

	/*
	* generate += *= etc.
	*/
	void
	cgen_asop(Node *n)
	{
	Node n1, n2, n3, n4;
	Node nl, nr;
	Prog *p1;
	Addr addr;
	int a;

	nl = n->left;
	nr = n->right;

	if(nr->ullman >= UINF && nl->ullman >= UINF) {
	tempname(&n1, nr->type);
	cgen(nr, &n1);
	n2 = *n;
	n2.right = &n1;
	cgen_asop(&n2);
	goto ret;
	}

	if(!isint[nl->type->etype])
	goto hard;
	if(!isint[nr->type->etype])
	goto hard;
	if(is64(nl->type) \|\| is64(nr->type))
	goto hard;

	switch(n->etype) {
	case OADD:
	if(smallintconst(nr))
	if(mpgetfix(nr->val.u.xval) == 1) {
	a = optoas(OINC, nl->type);
	if(nl->addable) {
	gins(a, N, nl);
	goto ret;
	}
	if(sudoaddable(a, nl, &addr)) {
	p1 = gins(a, N, N);
	p1->to = addr;
	sudoclean();
	goto ret;
	}
	}
	break;

	case OSUB:
	if(smallintconst(nr))
	if(mpgetfix(nr->val.u.xval) == 1) {
	a = optoas(ODEC, nl->type);
	if(nl->addable) {
	gins(a, N, nl);
	goto ret;
	}
	if(sudoaddable(a, nl, &addr)) {
	p1 = gins(a, N, N);
	p1->to = addr;
	sudoclean();
	goto ret;
	}
	}
	break;
	}

	switch(n->etype) {
	case OADD:
	case OSUB:
	case OXOR:
	case OAND:
	case OOR:
	a = optoas(n->etype, nl->type);
	if(nl->addable) {
	if(smallintconst(nr)) {
	gins(a, nr, nl);
	goto ret;
	}
	regalloc(&n2, nr->type, N);
	cgen(nr, &n2);
	gins(a, &n2, nl);
	regfree(&n2);
	goto ret;
	}
	if(nr->ullman < UINF)
	if(sudoaddable(a, nl, &addr)) {
	if(smallintconst(nr)) {
	p1 = gins(a, nr, N);
	p1->to = addr;
	sudoclean();
	goto ret;
	}
	regalloc(&n2, nr->type, N);
	cgen(nr, &n2);
	p1 = gins(a, &n2, N);
	p1->to = addr;
	regfree(&n2);
	sudoclean();
	goto ret;
	}
	}

	hard:
	n2.op = 0;
	n1.op = 0;
	if(nr->ullman >= nl->ullman \|\| nl->addable) {
	mgen(nr, &n2, N);
	nr = &n2;
	} else {
	tempname(&n2, nr->type);
	cgen(nr, &n2);
	nr = &n2;
	}
	if(!nl->addable) {
	igen(nl, &n1, N);
	nl = &n1;
	}

	n3 = *n;
	n3.left = nl;
	n3.right = nr;
	n3.op = n->etype;

	mgen(&n3, &n4, N);
	gmove(&n4, nl);

	if(n1.op)
	regfree(&n1);
	mfree(&n2);
	mfree(&n4);

	ret:
	;
	}

	int
	samereg(Node a, Node b)
	{
	if(a->op != OREGISTER)
	return 0;
	if(b->op != OREGISTER)
	return 0;
	if(a->val.u.reg != b->val.u.reg)
	return 0;
	return 1;
	}

	/*
	* generate division.
	* caller must set:
	* ax = allocated AX register
	* dx = allocated DX register
	* generates one of:
	* res = nl / nr
	* res = nl % nr
	* according to op.
	*/
	void
	dodiv(int op, Node nl, Node nr, Node res, Node ax, Node *dx)
	{
	int check;
	Node n1, t1, t2, t3, t4, n4, nz;
	Type t, t0;
	Prog p1, p2, *p3;

	// Have to be careful about handling
	// most negative int divided by -1 correctly.
	// The hardware will trap.
	// Also the byte divide instruction needs AH,
	// which we otherwise don't have to deal with.
	// Easiest way to avoid for int8, int16: use int32.
	// For int32 and int64, use explicit test.
	// Could use int64 hw for int32.
	t = nl->type;
	t0 = t;
	check = 0;
	if(issigned[t->etype]) {
	check = 1;
	if(isconst(nl, CTINT) && mpgetfix(nl->val.u.xval) != -1LL<<(t->width*8-1))
	check = 0;
	else if(isconst(nr, CTINT) && mpgetfix(nr->val.u.xval) != -1)
	check = 0;
	}
	if(t->width < 4) {
	if(issigned[t->etype])
	t = types[TINT32];
	else
	t = types[TUINT32];
	check = 0;
	}

	tempname(&t1, t);
	tempname(&t2, t);
	if(t0 != t) {
	tempname(&t3, t0);
	tempname(&t4, t0);
	cgen(nl, &t3);
	cgen(nr, &t4);
	// Convert.
	gmove(&t3, &t1);
	gmove(&t4, &t2);
	} else {
	cgen(nl, &t1);
	cgen(nr, &t2);
	}

	if(!samereg(ax, res) && !samereg(dx, res))
	regalloc(&n1, t, res);
	else
	regalloc(&n1, t, N);
	gmove(&t2, &n1);
	gmove(&t1, ax);
	p3 = P;
	if(check) {
	nodconst(&n4, t, -1);
	gins(optoas(OCMP, t), &n1, &n4);
	p1 = gbranch(optoas(ONE, t), T, +1);
	nodconst(&n4, t, -1LL<<(t->width*8-1));
	gins(optoas(OCMP, t), ax, &n4);
	p2 = gbranch(optoas(ONE, t), T, +1);
	if(op == ODIV)
	gmove(&n4, res);
	if(op == OMOD) {
	nodconst(&n4, t, 0);
	gmove(&n4, res);
	}
	p3 = gbranch(AJMP, T, 0);
	patch(p1, pc);
	patch(p2, pc);
	}
	if(!issigned[t->etype]) {
	nodconst(&nz, t, 0);
	gmove(&nz, dx);
	} else
	gins(optoas(OEXTEND, t), N, N);
	gins(optoas(op, t), &n1, N);
	regfree(&n1);

	if(op == ODIV)
	gmove(ax, res);
	else
	gmove(dx, res);
	if(check)
	patch(p3, pc);
	}

	static void
	savex(int dr, Node x, Node oldx, Node res, Type t)
	{
	int r;

	r = reg[dr];
	nodreg(x, types[TINT32], dr);

	// save current ax and dx if they are live
	// and not the destination
	memset(oldx, 0, sizeof *oldx);
	if(r > 0 && !samereg(x, res)) {
	tempname(oldx, types[TINT32]);
	gmove(x, oldx);
	}

	regalloc(x, t, x);
	}

	static void
	restx(Node x, Node oldx)
	{
	regfree(x);

	if(oldx->op != 0) {
	x->type = types[TINT32];
	gmove(oldx, x);
	}
	}

	/*
	* generate division according to op, one of:
	* res = nl / nr
	* res = nl % nr
	*/
	void
	cgen_div(int op, Node nl, Node nr, Node *res)
	{
	Node ax, dx, oldax, olddx;
	Type *t;

	if(is64(nl->type))
	fatal("cgen_div %T", nl->type);

	if(issigned[nl->type->etype])
	t = types[TINT32];
	else
	t = types[TUINT32];
	savex(D_AX, &ax, &oldax, res, t);
	savex(D_DX, &dx, &olddx, res, t);
	dodiv(op, nl, nr, res, &ax, &dx);
	restx(&dx, &olddx);
	restx(&ax, &oldax);
	}

	/*
	* generate shift according to op, one of:
	* res = nl << nr
	* res = nl >> nr
	*/
	void
	cgen_shift(int op, int bounded, Node nl, Node nr, Node *res)
	{
	Node n1, n2, nt, cx, oldcx, hi, lo;
	int a, w;
	Prog p1, p2;
	uvlong sc;

	if(nl->type->width > 4)
	fatal("cgen_shift %T", nl->type);

	w = nl->type->width * 8;

	a = optoas(op, nl->type);

	if(nr->op == OLITERAL) {
	tempname(&n2, nl->type);
	cgen(nl, &n2);
	regalloc(&n1, nl->type, res);
	gmove(&n2, &n1);
	sc = mpgetfix(nr->val.u.xval);
	if(sc >= nl->type->width*8) {
	// large shift gets 2 shifts by width-1
	gins(a, ncon(w-1), &n1);
	gins(a, ncon(w-1), &n1);
	} else
	gins(a, nr, &n1);
	gmove(&n1, res);
	regfree(&n1);
	return;
	}

	memset(&oldcx, 0, sizeof oldcx);
	nodreg(&cx, types[TUINT32], D_CX);
	if(reg[D_CX] > 1 && !samereg(&cx, res)) {
	tempname(&oldcx, types[TUINT32]);
	gmove(&cx, &oldcx);
	}

	if(nr->type->width > 4) {
	tempname(&nt, nr->type);
	n1 = nt;
	} else {
	nodreg(&n1, types[TUINT32], D_CX);
	regalloc(&n1, nr->type, &n1); // to hold the shift type in CX
	}

	if(samereg(&cx, res))
	regalloc(&n2, nl->type, N);
	else
	regalloc(&n2, nl->type, res);
	if(nl->ullman >= nr->ullman) {
	cgen(nl, &n2);
	cgen(nr, &n1);
	} else {
	cgen(nr, &n1);
	cgen(nl, &n2);
	}

	// test and fix up large shifts
	if(bounded) {
	if(nr->type->width > 4) {
	// delayed reg alloc
	nodreg(&n1, types[TUINT32], D_CX);
	regalloc(&n1, types[TUINT32], &n1); // to hold the shift type in CX
	split64(&nt, &lo, &hi);
	gmove(&lo, &n1);
	}
	} else {
	if(nr->type->width > 4) {
	// delayed reg alloc
	nodreg(&n1, types[TUINT32], D_CX);
	regalloc(&n1, types[TUINT32], &n1); // to hold the shift type in CX
	split64(&nt, &lo, &hi);
	gmove(&lo, &n1);
	gins(optoas(OCMP, types[TUINT32]), &hi, ncon(0));
	p2 = gbranch(optoas(ONE, types[TUINT32]), T, +1);
	gins(optoas(OCMP, types[TUINT32]), &n1, ncon(w));
	p1 = gbranch(optoas(OLT, types[TUINT32]), T, +1);
	patch(p2, pc);
	} else {
	gins(optoas(OCMP, nr->type), &n1, ncon(w));
	p1 = gbranch(optoas(OLT, types[TUINT32]), T, +1);
	}
	if(op == ORSH && issigned[nl->type->etype]) {
	gins(a, ncon(w-1), &n2);
	} else {
	gmove(ncon(0), &n2);
	}
	patch(p1, pc);
	}
	gins(a, &n1, &n2);

	if(oldcx.op != 0)
	gmove(&oldcx, &cx);

	gmove(&n2, res);

	regfree(&n1);
	regfree(&n2);
	}

	/*
	* generate byte multiply:
	* res = nl * nr
	* no byte multiply instruction so have to do
	* 16-bit multiply and take bottom half.
	*/
	void
	cgen_bmul(int op, Node nl, Node nr, Node *res)
	{
	Node n1b, n2b, n1w, n2w;
	Type *t;
	int a;

	if(nl->ullman >= nr->ullman) {
	regalloc(&n1b, nl->type, res);
	cgen(nl, &n1b);
	regalloc(&n2b, nr->type, N);
	cgen(nr, &n2b);
	} else {
	regalloc(&n2b, nr->type, N);
	cgen(nr, &n2b);
	regalloc(&n1b, nl->type, res);
	cgen(nl, &n1b);
	}

	// copy from byte to short registers
	t = types[TUINT16];
	if(issigned[nl->type->etype])
	t = types[TINT16];

	regalloc(&n2w, t, &n2b);
	cgen(&n2b, &n2w);

	regalloc(&n1w, t, &n1b);
	cgen(&n1b, &n1w);

	a = optoas(op, t);
	gins(a, &n2w, &n1w);
	cgen(&n1w, &n1b);
	cgen(&n1b, res);

	regfree(&n1w);
	regfree(&n2w);
	regfree(&n1b);
	regfree(&n2b);
	}