src/cmd/9g/ggen.go - 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.

 package main

 import (
 	"cmd/internal/obj"
 	"cmd/internal/obj/ppc64"
 	"fmt"
 )
 import "cmd/internal/gc"

 func defframe(ptxt *obj.Prog) {
 	var n *gc.Node

 	// fill in argument size, stack size
 	ptxt.To.Type = obj.TYPE_TEXTSIZE

 	ptxt.To.U.Argsize = int32(gc.Rnd(gc.Curfn.Type.Argwid, int64(gc.Widthptr)))
 	frame := uint32(gc.Rnd(gc.Stksize+gc.Maxarg, int64(gc.Widthreg)))
 	ptxt.To.Offset = int64(frame)

 	// insert code to zero ambiguously live variables
 	// so that the garbage collector only sees initialized values
 	// when it looks for pointers.
 	p := ptxt

 	hi := int64(0)
 	lo := hi

 	// iterate through declarations - they are sorted in decreasing xoffset order.
 	for l := gc.Curfn.Dcl; l != nil; l = l.Next {
 		n = l.N
 		if n.Needzero == 0 {
 			continue
 		}
 		if n.Class != gc.PAUTO {
 			gc.Fatal("needzero class %d", n.Class)
 		}
 		if n.Type.Width%int64(gc.Widthptr) != 0 || n.Xoffset%int64(gc.Widthptr) != 0 || n.Type.Width == 0 {
 			gc.Fatal("var %v has size %d offset %d", gc.Nconv(n, obj.FmtLong), int(n.Type.Width), int(n.Xoffset))
 		}

 		if lo != hi && n.Xoffset+n.Type.Width >= lo-int64(2*gc.Widthreg) {
 			// merge with range we already have
 			lo = n.Xoffset

 			continue
 		}

 		// zero old range
 		p = zerorange(p, int64(frame), lo, hi)

 		// set new range
 		hi = n.Xoffset + n.Type.Width

 		lo = n.Xoffset
 	}

 	// zero final range
 	zerorange(p, int64(frame), lo, hi)
 }

 func zerorange(p *obj.Prog, frame int64, lo int64, hi int64) *obj.Prog {
 	cnt := hi - lo
 	if cnt == 0 {
 		return p
 	}
 	if cnt < int64(4*gc.Widthptr) {
 		for i := int64(0); i < cnt; i += int64(gc.Widthptr) {
 			p = appendpp(p, ppc64.AMOVD, obj.TYPE_REG, ppc64.REGZERO, 0, obj.TYPE_MEM, ppc64.REGSP, 8+frame+lo+i)
 		}
 	} else if cnt <= int64(128*gc.Widthptr) {
 		p = appendpp(p, ppc64.AADD, obj.TYPE_CONST, 0, 8+frame+lo-8, obj.TYPE_REG, ppc64.REGRT1, 0)
 		p.Reg = ppc64.REGSP
 		p = appendpp(p, obj.ADUFFZERO, obj.TYPE_NONE, 0, 0, obj.TYPE_MEM, 0, 0)
 		f := gc.Sysfunc("duffzero")
 		gc.Naddr(f, &p.To, 1)
 		gc.Afunclit(&p.To, f)
 		p.To.Offset = 4 * (128 - cnt/int64(gc.Widthptr))
 	} else {
 		p = appendpp(p, ppc64.AMOVD, obj.TYPE_CONST, 0, 8+frame+lo-8, obj.TYPE_REG, ppc64.REGTMP, 0)
 		p = appendpp(p, ppc64.AADD, obj.TYPE_REG, ppc64.REGTMP, 0, obj.TYPE_REG, ppc64.REGRT1, 0)
 		p.Reg = ppc64.REGSP
 		p = appendpp(p, ppc64.AMOVD, obj.TYPE_CONST, 0, cnt, obj.TYPE_REG, ppc64.REGTMP, 0)
 		p = appendpp(p, ppc64.AADD, obj.TYPE_REG, ppc64.REGTMP, 0, obj.TYPE_REG, ppc64.REGRT2, 0)
 		p.Reg = ppc64.REGRT1
 		p = appendpp(p, ppc64.AMOVDU, obj.TYPE_REG, ppc64.REGZERO, 0, obj.TYPE_MEM, ppc64.REGRT1, int64(gc.Widthptr))
 		p1 := p
 		p = appendpp(p, ppc64.ACMP, obj.TYPE_REG, ppc64.REGRT1, 0, obj.TYPE_REG, ppc64.REGRT2, 0)
 		p = appendpp(p, ppc64.ABNE, obj.TYPE_NONE, 0, 0, obj.TYPE_BRANCH, 0, 0)
 		gc.Patch(p, p1)
 	}

 	return p
 }

 func appendpp(p *obj.Prog, as int, ftype int, freg int, foffset int64, ttype int, treg int, toffset int64) *obj.Prog {
 	q := gc.Ctxt.NewProg()
 	gc.Clearp(q)
 	q.As = int16(as)
 	q.Lineno = p.Lineno
 	q.From.Type = int16(ftype)
 	q.From.Reg = int16(freg)
 	q.From.Offset = foffset
 	q.To.Type = int16(ttype)
 	q.To.Reg = int16(treg)
 	q.To.Offset = toffset
 	q.Link = p.Link
 	p.Link = q
 	return q
 }

 /*
  * generate: BL reg, f
  * where both reg and f are registers.
  * On power, f must be moved to CTR first.
  */
 func ginsBL(reg *gc.Node, f *gc.Node) {
 	p := gins(ppc64.AMOVD, f, nil)
 	p.To.Type = obj.TYPE_REG
 	p.To.Reg = ppc64.REG_CTR
 	p = gins(ppc64.ABL, reg, nil)
 	p.To.Type = obj.TYPE_REG
 	p.To.Reg = ppc64.REG_CTR
 }

 /*
  * generate:
  *	call f
  *	proc=-1	normal call but no return
  *	proc=0	normal call
  *	proc=1	goroutine run in new proc
  *	proc=2	defer call save away stack
   *	proc=3	normal call to C pointer (not Go func value)
 */
 func ginscall(f *gc.Node, proc int) {
 	if f.Type != nil {
 		extra := int32(0)
 		if proc == 1 || proc == 2 {
 			extra = 2 * int32(gc.Widthptr)
 		}
 		gc.Setmaxarg(f.Type, extra)
 	}

 	switch proc {
 	default:
 		gc.Fatal("ginscall: bad proc %d", proc)

 	case 0, // normal call
 		-1: // normal call but no return
 		if f.Op == gc.ONAME && f.Class == gc.PFUNC {
 			if f == gc.Deferreturn {
 				// Deferred calls will appear to be returning to
 				// the CALL deferreturn(SB) that we are about to emit.
 				// However, the stack trace code will show the line
 				// of the instruction byte before the return PC.
 				// To avoid that being an unrelated instruction,
 				// insert a ppc64 NOP that we will have the right line number.
 				// The ppc64 NOP is really or r0, r0, r0; use that description
 				// because the NOP pseudo-instruction would be removed by
 				// the linker.
 				var reg gc.Node
 				gc.Nodreg(&reg, gc.Types[gc.TINT], ppc64.REG_R0)

 				gins(ppc64.AOR, &reg, &reg)
 			}

 			p := gins(ppc64.ABL, nil, f)
 			gc.Afunclit(&p.To, f)
 			if proc == -1 || gc.Noreturn(p) {
 				gins(obj.AUNDEF, nil, nil)
 			}
 			break
 		}

 		var reg gc.Node
 		gc.Nodreg(&reg, gc.Types[gc.Tptr], ppc64.REGCTXT)
 		var r1 gc.Node
 		gc.Nodreg(&r1, gc.Types[gc.Tptr], ppc64.REG_R3)
 		gmove(f, &reg)
 		reg.Op = gc.OINDREG
 		gmove(&reg, &r1)
 		reg.Op = gc.OREGISTER
 		ginsBL(&reg, &r1)

 	case 3: // normal call of c function pointer
 		ginsBL(nil, f)

 	case 1, // call in new proc (go)
 		2: // deferred call (defer)
 		var con gc.Node
 		gc.Nodconst(&con, gc.Types[gc.TINT64], int64(gc.Argsize(f.Type)))

 		var reg gc.Node
 		gc.Nodreg(&reg, gc.Types[gc.TINT64], ppc64.REG_R3)
 		var reg2 gc.Node
 		gc.Nodreg(&reg2, gc.Types[gc.TINT64], ppc64.REG_R4)
 		gmove(f, &reg)

 		gmove(&con, &reg2)
 		p := gins(ppc64.AMOVW, &reg2, nil)
 		p.To.Type = obj.TYPE_MEM
 		p.To.Reg = ppc64.REGSP
 		p.To.Offset = 8

 		p = gins(ppc64.AMOVD, &reg, nil)
 		p.To.Type = obj.TYPE_MEM
 		p.To.Reg = ppc64.REGSP
 		p.To.Offset = 16

 		if proc == 1 {
 			ginscall(gc.Newproc, 0)
 		} else {
 			if gc.Hasdefer == 0 {
 				gc.Fatal("hasdefer=0 but has defer")
 			}
 			ginscall(gc.Deferproc, 0)
 		}

 		if proc == 2 {
 			gc.Nodreg(&reg, gc.Types[gc.TINT64], ppc64.REG_R3)
 			p := gins(ppc64.ACMP, &reg, nil)
 			p.To.Type = obj.TYPE_REG
 			p.To.Reg = ppc64.REG_R0
 			p = gc.Gbranch(ppc64.ABEQ, nil, +1)
 			cgen_ret(nil)
 			gc.Patch(p, gc.Pc)
 		}
 	}
 }

 /*
  * n is call to interface method.
  * generate res = n.
  */
 func cgen_callinter(n *gc.Node, res *gc.Node, proc int) {
 	i := n.Left
 	if i.Op != gc.ODOTINTER {
 		gc.Fatal("cgen_callinter: not ODOTINTER %v", gc.Oconv(int(i.Op), 0))
 	}

 	f := i.Right // field
 	if f.Op != gc.ONAME {
 		gc.Fatal("cgen_callinter: not ONAME %v", gc.Oconv(int(f.Op), 0))
 	}

 	i = i.Left // interface

 	if i.Addable == 0 {
 		var tmpi gc.Node
 		gc.Tempname(&tmpi, i.Type)
 		cgen(i, &tmpi)
 		i = &tmpi
 	}

 	gc.Genlist(n.List) // assign the args

 	// i is now addable, prepare an indirected
 	// register to hold its address.
 	var nodi gc.Node
 	igen(i, &nodi, res) // REG = &inter

 	var nodsp gc.Node
 	gc.Nodindreg(&nodsp, gc.Types[gc.Tptr], ppc64.REGSP)

 	nodsp.Xoffset = int64(gc.Widthptr)
 	if proc != 0 {
 		nodsp.Xoffset += 2 * int64(gc.Widthptr) // leave room for size & fn
 	}
 	nodi.Type = gc.Types[gc.Tptr]
 	nodi.Xoffset += int64(gc.Widthptr)
 	cgen(&nodi, &nodsp) // {8 or 24}(SP) = 8(REG) -- i.data

 	var nodo gc.Node
 	regalloc(&nodo, gc.Types[gc.Tptr], res)

 	nodi.Type = gc.Types[gc.Tptr]
 	nodi.Xoffset -= int64(gc.Widthptr)
 	cgen(&nodi, &nodo) // REG = 0(REG) -- i.tab
 	regfree(&nodi)

 	var nodr gc.Node
 	regalloc(&nodr, gc.Types[gc.Tptr], &nodo)
 	if n.Left.Xoffset == gc.BADWIDTH {
 		gc.Fatal("cgen_callinter: badwidth")
 	}
 	gc.Cgen_checknil(&nodo) // in case offset is huge
 	nodo.Op = gc.OINDREG
 	nodo.Xoffset = n.Left.Xoffset + 3*int64(gc.Widthptr) + 8
 	if proc == 0 {
 		// plain call: use direct c function pointer - more efficient
 		cgen(&nodo, &nodr) // REG = 32+offset(REG) -- i.tab->fun[f]
 		proc = 3
 	} else {
 		// go/defer. generate go func value.
 		p := gins(ppc64.AMOVD, &nodo, &nodr) // REG = &(32+offset(REG)) -- i.tab->fun[f]
 		p.From.Type = obj.TYPE_ADDR
 	}

 	nodr.Type = n.Left.Type
 	ginscall(&nodr, proc)

 	regfree(&nodr)
 	regfree(&nodo)
 }

 /*
  * generate function call;
  *	proc=0	normal call
  *	proc=1	goroutine run in new proc
  *	proc=2	defer call save away stack
  */
 func cgen_call(n *gc.Node, proc int) {
 	if n == nil {
 		return
 	}

 	var afun gc.Node
 	if n.Left.Ullman >= gc.UINF {
 		// if name involves a fn call
 		// precompute the address of the fn
 		gc.Tempname(&afun, gc.Types[gc.Tptr])

 		cgen(n.Left, &afun)
 	}

 	gc.Genlist(n.List) // assign the args
 	t := n.Left.Type

 	// call tempname pointer
 	if n.Left.Ullman >= gc.UINF {
 		var nod gc.Node
 		regalloc(&nod, gc.Types[gc.Tptr], nil)
 		gc.Cgen_as(&nod, &afun)
 		nod.Type = t
 		ginscall(&nod, proc)
 		regfree(&nod)
 		return
 	}

 	// call pointer
 	if n.Left.Op != gc.ONAME || n.Left.Class != gc.PFUNC {
 		var nod gc.Node
 		regalloc(&nod, gc.Types[gc.Tptr], nil)
 		gc.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.
  */
 func cgen_callret(n *gc.Node, res *gc.Node) {
 	t := n.Left.Type
 	if t.Etype == gc.TPTR32 || t.Etype == gc.TPTR64 {
 		t = t.Type
 	}

 	var flist gc.Iter
 	fp := gc.Structfirst(&flist, gc.Getoutarg(t))
 	if fp == nil {
 		gc.Fatal("cgen_callret: nil")
 	}

 	nod := gc.Node{}
 	nod.Op = gc.OINDREG
 	nod.Val.U.Reg = ppc64.REGSP
 	nod.Addable = 1

 	nod.Xoffset = fp.Width + int64(gc.Widthptr) // +widthptr: saved LR at 0(R1)
 	nod.Type = fp.Type
 	gc.Cgen_as(res, &nod)
 }

 /*
  * call to n has already been generated.
  * generate:
  *	res = &return value from call.
  */
 func cgen_aret(n *gc.Node, res *gc.Node) {
 	t := n.Left.Type
 	if gc.Isptr[t.Etype] != 0 {
 		t = t.Type
 	}

 	var flist gc.Iter
 	fp := gc.Structfirst(&flist, gc.Getoutarg(t))
 	if fp == nil {
 		gc.Fatal("cgen_aret: nil")
 	}

 	nod1 := gc.Node{}
 	nod1.Op = gc.OINDREG
 	nod1.Val.U.Reg = ppc64.REGSP
 	nod1.Addable = 1

 	nod1.Xoffset = fp.Width + int64(gc.Widthptr) // +widthptr: saved lr at 0(SP)
 	nod1.Type = fp.Type

 	if res.Op != gc.OREGISTER {
 		var nod2 gc.Node
 		regalloc(&nod2, gc.Types[gc.Tptr], res)
 		agen(&nod1, &nod2)
 		gins(ppc64.AMOVD, &nod2, res)
 		regfree(&nod2)
 	} else {
 		agen(&nod1, res)
 	}
 }

 /*
  * generate return.
  * n->left is assignments to return values.
  */
 func cgen_ret(n *gc.Node) {
 	if n != nil {
 		gc.Genlist(n.List) // copy out args
 	}
 	if gc.Hasdefer != 0 {
 		ginscall(gc.Deferreturn, 0)
 	}
 	gc.Genlist(gc.Curfn.Exit)
 	p := gins(obj.ARET, nil, nil)
 	if n != nil && n.Op == gc.ORETJMP {
 		p.To.Name = obj.NAME_EXTERN
 		p.To.Type = obj.TYPE_ADDR
 		p.To.Sym = gc.Linksym(n.Left.Sym)
 	}
 }

 /*
  * generate division.
  * generates one of:
  *	res = nl / nr
  *	res = nl % nr
  * according to op.
  */
 func dodiv(op int, nl *gc.Node, nr *gc.Node, res *gc.Node) {
 	// Have to be careful about handling
 	// most negative int divided by -1 correctly.
 	// The hardware will generate undefined result.
 	// Also need to explicitly trap on division on zero,
 	// the hardware will silently generate undefined result.
 	// DIVW will leave unpredicable result in higher 32-bit,
 	// so always use DIVD/DIVDU.
 	t := nl.Type

 	t0 := t
 	check := 0
 	if gc.Issigned[t.Etype] != 0 {
 		check = 1
 		if gc.Isconst(nl, gc.CTINT) && gc.Mpgetfix(nl.Val.U.Xval) != -(1<<uint64(t.Width*8-1)) {
 			check = 0
 		} else if gc.Isconst(nr, gc.CTINT) && gc.Mpgetfix(nr.Val.U.Xval) != -1 {
 			check = 0
 		}
 	}

 	if t.Width < 8 {
 		if gc.Issigned[t.Etype] != 0 {
 			t = gc.Types[gc.TINT64]
 		} else {
 			t = gc.Types[gc.TUINT64]
 		}
 		check = 0
 	}

 	a := optoas(gc.ODIV, t)

 	var tl gc.Node
 	regalloc(&tl, t0, nil)
 	var tr gc.Node
 	regalloc(&tr, t0, nil)
 	if nl.Ullman >= nr.Ullman {
 		cgen(nl, &tl)
 		cgen(nr, &tr)
 	} else {
 		cgen(nr, &tr)
 		cgen(nl, &tl)
 	}

 	if t != t0 {
 		// Convert
 		tl2 := tl

 		tr2 := tr
 		tl.Type = t
 		tr.Type = t
 		gmove(&tl2, &tl)
 		gmove(&tr2, &tr)
 	}

 	// Handle divide-by-zero panic.
 	p1 := gins(optoas(gc.OCMP, t), &tr, nil)

 	p1.To.Type = obj.TYPE_REG
 	p1.To.Reg = ppc64.REGZERO
 	p1 = gc.Gbranch(optoas(gc.ONE, t), nil, +1)
 	if panicdiv == nil {
 		panicdiv = gc.Sysfunc("panicdivide")
 	}
 	ginscall(panicdiv, -1)
 	gc.Patch(p1, gc.Pc)

 	var p2 *obj.Prog
 	if check != 0 {
 		var nm1 gc.Node
 		gc.Nodconst(&nm1, t, -1)
 		gins(optoas(gc.OCMP, t), &tr, &nm1)
 		p1 := gc.Gbranch(optoas(gc.ONE, t), nil, +1)
 		if op == gc.ODIV {
 			// a / (-1) is -a.
 			gins(optoas(gc.OMINUS, t), nil, &tl)

 			gmove(&tl, res)
 		} else {
 			// a % (-1) is 0.
 			var nz gc.Node
 			gc.Nodconst(&nz, t, 0)

 			gmove(&nz, res)
 		}

 		p2 = gc.Gbranch(obj.AJMP, nil, 0)
 		gc.Patch(p1, gc.Pc)
 	}

 	p1 = gins(a, &tr, &tl)
 	if op == gc.ODIV {
 		regfree(&tr)
 		gmove(&tl, res)
 	} else {
 		// A%B = A-(A/B*B)
 		var tm gc.Node
 		regalloc(&tm, t, nil)

 		// patch div to use the 3 register form
 		// TODO(minux): add gins3?
 		p1.Reg = p1.To.Reg

 		p1.To.Reg = tm.Val.U.Reg
 		gins(optoas(gc.OMUL, t), &tr, &tm)
 		regfree(&tr)
 		gins(optoas(gc.OSUB, t), &tm, &tl)
 		regfree(&tm)
 		gmove(&tl, res)
 	}

 	regfree(&tl)
 	if check != 0 {
 		gc.Patch(p2, gc.Pc)
 	}
 }

 /*
  * generate division according to op, one of:
  *	res = nl / nr
  *	res = nl % nr
  */
 func cgen_div(op int, nl *gc.Node, nr *gc.Node, res *gc.Node) {
 	// TODO(minux): enable division by magic multiply (also need to fix longmod below)
 	//if(nr->op != OLITERAL)
 	goto longdiv

 	// division and mod using (slow) hardware instruction
 longdiv:
 	dodiv(op, nl, nr, res)

 	return
 }

 /*
  * generate high multiply:
  *   res = (nl*nr) >> width
  */
 func cgen_hmul(nl *gc.Node, nr *gc.Node, res *gc.Node) {
 	// largest ullman on left.
 	if nl.Ullman < nr.Ullman {
 		tmp := (*gc.Node)(nl)
 		nl = nr
 		nr = tmp
 	}

 	t := (*gc.Type)(nl.Type)
 	w := int(int(t.Width * 8))
 	var n1 gc.Node
 	cgenr(nl, &n1, res)
 	var n2 gc.Node
 	cgenr(nr, &n2, nil)
 	switch gc.Simtype[t.Etype] {
 	case gc.TINT8,
 		gc.TINT16,
 		gc.TINT32:
 		gins(optoas(gc.OMUL, t), &n2, &n1)
 		p := (*obj.Prog)(gins(ppc64.ASRAD, nil, &n1))
 		p.From.Type = obj.TYPE_CONST
 		p.From.Offset = int64(w)

 	case gc.TUINT8,
 		gc.TUINT16,
 		gc.TUINT32:
 		gins(optoas(gc.OMUL, t), &n2, &n1)
 		p := (*obj.Prog)(gins(ppc64.ASRD, nil, &n1))
 		p.From.Type = obj.TYPE_CONST
 		p.From.Offset = int64(w)

 	case gc.TINT64,
 		gc.TUINT64:
 		if gc.Issigned[t.Etype] != 0 {
 			gins(ppc64.AMULHD, &n2, &n1)
 		} else {
 			gins(ppc64.AMULHDU, &n2, &n1)
 		}

 	default:
 		gc.Fatal("cgen_hmul %v", gc.Tconv(t, 0))
 	}

 	cgen(&n1, res)
 	regfree(&n1)
 	regfree(&n2)
 }

 /*
  * generate shift according to op, one of:
  *	res = nl << nr
  *	res = nl >> nr
  */
 func cgen_shift(op int, bounded bool, nl *gc.Node, nr *gc.Node, res *gc.Node) {
 	var n1 gc.Node
 	var n2 gc.Node
 	var n3 gc.Node
 	var tcount *gc.Type

 	a := int(optoas(op, nl.Type))

 	if nr.Op == gc.OLITERAL {
 		var n1 gc.Node
 		regalloc(&n1, nl.Type, res)
 		cgen(nl, &n1)
 		sc := uint64(uint64(gc.Mpgetfix(nr.Val.U.Xval)))
 		if sc >= uint64(nl.Type.Width*8) {
 			// large shift gets 2 shifts by width-1
 			var n3 gc.Node
 			gc.Nodconst(&n3, gc.Types[gc.TUINT32], nl.Type.Width*8-1)

 			gins(a, &n3, &n1)
 			gins(a, &n3, &n1)
 		} else {
 			gins(a, nr, &n1)
 		}
 		gmove(&n1, res)
 		regfree(&n1)
 		goto ret
 	}

 	if nl.Ullman >= gc.UINF {
 		var n4 gc.Node
 		gc.Tempname(&n4, nl.Type)
 		cgen(nl, &n4)
 		nl = &n4
 	}

 	if nr.Ullman >= gc.UINF {
 		var n5 gc.Node
 		gc.Tempname(&n5, nr.Type)
 		cgen(nr, &n5)
 		nr = &n5
 	}

 	// Allow either uint32 or uint64 as shift type,
 	// to avoid unnecessary conversion from uint32 to uint64
 	// just to do the comparison.
 	tcount = gc.Types[gc.Simtype[nr.Type.Etype]]

 	if tcount.Etype < gc.TUINT32 {
 		tcount = gc.Types[gc.TUINT32]
 	}

 	regalloc(&n1, nr.Type, nil) // to hold the shift type in CX
 	regalloc(&n3, tcount, &n1)  // to clear high bits of CX

 	regalloc(&n2, nl.Type, res)

 	if nl.Ullman >= nr.Ullman {
 		cgen(nl, &n2)
 		cgen(nr, &n1)
 		gmove(&n1, &n3)
 	} else {
 		cgen(nr, &n1)
 		gmove(&n1, &n3)
 		cgen(nl, &n2)
 	}

 	regfree(&n3)

 	// test and fix up large shifts
 	if !bounded {
 		gc.Nodconst(&n3, tcount, nl.Type.Width*8)
 		gins(optoas(gc.OCMP, tcount), &n1, &n3)
 		p1 := (*obj.Prog)(gc.Gbranch(optoas(gc.OLT, tcount), nil, +1))
 		if op == gc.ORSH && gc.Issigned[nl.Type.Etype] != 0 {
 			gc.Nodconst(&n3, gc.Types[gc.TUINT32], nl.Type.Width*8-1)
 			gins(a, &n3, &n2)
 		} else {
 			gc.Nodconst(&n3, nl.Type, 0)
 			gmove(&n3, &n2)
 		}

 		gc.Patch(p1, gc.Pc)
 	}

 	gins(a, &n1, &n2)

 	gmove(&n2, res)

 	regfree(&n1)
 	regfree(&n2)

 ret:
 }

 func clearfat(nl *gc.Node) {
 	/* clear a fat object */
 	if gc.Debug['g'] != 0 {
 		fmt.Printf("clearfat %v (%v, size: %d)\n", gc.Nconv(nl, 0), gc.Tconv(nl.Type, 0), nl.Type.Width)
 	}

 	w := uint64(uint64(nl.Type.Width))

 	// Avoid taking the address for simple enough types.
 	//if(componentgen(N, nl))
 	//	return;

 	c := uint64(w % 8) // bytes
 	q := uint64(w / 8) // dwords

 	if reg[ppc64.REGRT1] > 0 {
 		gc.Fatal("R%d in use during clearfat", ppc64.REGRT1)
 	}

 	var r0 gc.Node
 	gc.Nodreg(&r0, gc.Types[gc.TUINT64], ppc64.REG_R0) // r0 is always zero
 	var dst gc.Node
 	gc.Nodreg(&dst, gc.Types[gc.Tptr], ppc64.REGRT1)
 	reg[ppc64.REGRT1]++
 	agen(nl, &dst)

 	var boff uint64
 	var p *obj.Prog
 	if q > 128 {
 		p = gins(ppc64.ASUB, nil, &dst)
 		p.From.Type = obj.TYPE_CONST
 		p.From.Offset = 8

 		var end gc.Node
 		regalloc(&end, gc.Types[gc.Tptr], nil)
 		p = gins(ppc64.AMOVD, &dst, &end)
 		p.From.Type = obj.TYPE_ADDR
 		p.From.Offset = int64(q * 8)

 		p = gins(ppc64.AMOVDU, &r0, &dst)
 		p.To.Type = obj.TYPE_MEM
 		p.To.Offset = 8
 		pl := (*obj.Prog)(p)

 		p = gins(ppc64.ACMP, &dst, &end)
 		gc.Patch(gc.Gbranch(ppc64.ABNE, nil, 0), pl)

 		regfree(&end)

 		// The loop leaves R3 on the last zeroed dword
 		boff = 8
 	} else if q >= 4 {
 		p = gins(ppc64.ASUB, nil, &dst)
 		p.From.Type = obj.TYPE_CONST
 		p.From.Offset = 8
 		f := (*gc.Node)(gc.Sysfunc("duffzero"))
 		p = gins(obj.ADUFFZERO, nil, f)
 		gc.Afunclit(&p.To, f)

 		// 4 and 128 = magic constants: see ../../runtime/asm_ppc64x.s
 		p.To.Offset = int64(4 * (128 - q))

 		// duffzero leaves R3 on the last zeroed dword
 		boff = 8
 	} else {
 		for t := uint64(0); t < q; t++ {
 			p = gins(ppc64.AMOVD, &r0, &dst)
 			p.To.Type = obj.TYPE_MEM
 			p.To.Offset = int64(8 * t)
 		}

 		boff = 8 * q
 	}

 	for t := uint64(0); t < c; t++ {
 		p = gins(ppc64.AMOVB, &r0, &dst)
 		p.To.Type = obj.TYPE_MEM
 		p.To.Offset = int64(t + boff)
 	}

 	reg[ppc64.REGRT1]--
 }

 // Called after regopt and peep have run.
 // Expand CHECKNIL pseudo-op into actual nil pointer check.
 func expandchecks(firstp *obj.Prog) {
 	var p1 *obj.Prog
 	var p2 *obj.Prog

 	for p := (*obj.Prog)(firstp); p != nil; p = p.Link {
 		if gc.Debug_checknil != 0 && gc.Ctxt.Debugvlog != 0 {
 			fmt.Printf("expandchecks: %v\n", p)
 		}
 		if p.As != obj.ACHECKNIL {
 			continue
 		}
 		if gc.Debug_checknil != 0 && p.Lineno > 1 { // p->lineno==1 in generated wrappers
 			gc.Warnl(int(p.Lineno), "generated nil check")
 		}
 		if p.From.Type != obj.TYPE_REG {
 			gc.Fatal("invalid nil check %v\n", p)
 		}

 		/*
 			// check is
 			//	TD $4, R0, arg (R0 is always zero)
 			// eqv. to:
 			// 	tdeq r0, arg
 			// NOTE: this needs special runtime support to make SIGTRAP recoverable.
 			reg = p->from.reg;
 			p->as = ATD;
 			p->from = p->to = p->from3 = zprog.from;
 			p->from.type = TYPE_CONST;
 			p->from.offset = 4;
 			p->from.reg = 0;
 			p->reg = REG_R0;
 			p->to.type = TYPE_REG;
 			p->to.reg = reg;
 		*/
 		// check is
 		//	CMP arg, R0
 		//	BNE 2(PC) [likely]
 		//	MOVD R0, 0(R0)
 		p1 = gc.Ctxt.NewProg()

 		p2 = gc.Ctxt.NewProg()
 		gc.Clearp(p1)
 		gc.Clearp(p2)
 		p1.Link = p2
 		p2.Link = p.Link
 		p.Link = p1
 		p1.Lineno = p.Lineno
 		p2.Lineno = p.Lineno
 		p1.Pc = 9999
 		p2.Pc = 9999
 		p.As = ppc64.ACMP
 		p.To.Type = obj.TYPE_REG
 		p.To.Reg = ppc64.REGZERO
 		p1.As = ppc64.ABNE

 		//p1->from.type = TYPE_CONST;
 		//p1->from.offset = 1; // likely
 		p1.To.Type = obj.TYPE_BRANCH

 		p1.To.U.Branch = p2.Link

 		// crash by write to memory address 0.
 		p2.As = ppc64.AMOVD

 		p2.From.Type = obj.TYPE_REG
 		p2.From.Reg = ppc64.REG_R0
 		p2.To.Type = obj.TYPE_MEM
 		p2.To.Reg = ppc64.REG_R0
 		p2.To.Offset = 0
 	}
 }
	// 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.

	package main

	import (
	"cmd/internal/obj"
	"cmd/internal/obj/ppc64"
	"fmt"
	)
	import "cmd/internal/gc"

	func defframe(ptxt *obj.Prog) {
	var n *gc.Node

	// fill in argument size, stack size
	ptxt.To.Type = obj.TYPE_TEXTSIZE

	ptxt.To.U.Argsize = int32(gc.Rnd(gc.Curfn.Type.Argwid, int64(gc.Widthptr)))
	frame := uint32(gc.Rnd(gc.Stksize+gc.Maxarg, int64(gc.Widthreg)))
	ptxt.To.Offset = int64(frame)

	// insert code to zero ambiguously live variables
	// so that the garbage collector only sees initialized values
	// when it looks for pointers.
	p := ptxt

	hi := int64(0)
	lo := hi

	// iterate through declarations - they are sorted in decreasing xoffset order.
	for l := gc.Curfn.Dcl; l != nil; l = l.Next {
	n = l.N
	if n.Needzero == 0 {
	continue
	}
	if n.Class != gc.PAUTO {
	gc.Fatal("needzero class %d", n.Class)
	}
	if n.Type.Width%int64(gc.Widthptr) != 0 \|\| n.Xoffset%int64(gc.Widthptr) != 0 \|\| n.Type.Width == 0 {
	gc.Fatal("var %v has size %d offset %d", gc.Nconv(n, obj.FmtLong), int(n.Type.Width), int(n.Xoffset))
	}

	if lo != hi && n.Xoffset+n.Type.Width >= lo-int64(2*gc.Widthreg) {
	// merge with range we already have
	lo = n.Xoffset

	continue
	}

	// zero old range
	p = zerorange(p, int64(frame), lo, hi)

	// set new range
	hi = n.Xoffset + n.Type.Width

	lo = n.Xoffset
	}

	// zero final range
	zerorange(p, int64(frame), lo, hi)
	}

	func zerorange(p obj.Prog, frame int64, lo int64, hi int64) obj.Prog {
	cnt := hi - lo
	if cnt == 0 {
	return p
	}
	if cnt < int64(4*gc.Widthptr) {
	for i := int64(0); i < cnt; i += int64(gc.Widthptr) {
	p = appendpp(p, ppc64.AMOVD, obj.TYPE_REG, ppc64.REGZERO, 0, obj.TYPE_MEM, ppc64.REGSP, 8+frame+lo+i)
	}
	} else if cnt <= int64(128*gc.Widthptr) {
	p = appendpp(p, ppc64.AADD, obj.TYPE_CONST, 0, 8+frame+lo-8, obj.TYPE_REG, ppc64.REGRT1, 0)
	p.Reg = ppc64.REGSP
	p = appendpp(p, obj.ADUFFZERO, obj.TYPE_NONE, 0, 0, obj.TYPE_MEM, 0, 0)
	f := gc.Sysfunc("duffzero")
	gc.Naddr(f, &p.To, 1)
	gc.Afunclit(&p.To, f)
	p.To.Offset = 4 * (128 - cnt/int64(gc.Widthptr))
	} else {
	p = appendpp(p, ppc64.AMOVD, obj.TYPE_CONST, 0, 8+frame+lo-8, obj.TYPE_REG, ppc64.REGTMP, 0)
	p = appendpp(p, ppc64.AADD, obj.TYPE_REG, ppc64.REGTMP, 0, obj.TYPE_REG, ppc64.REGRT1, 0)
	p.Reg = ppc64.REGSP
	p = appendpp(p, ppc64.AMOVD, obj.TYPE_CONST, 0, cnt, obj.TYPE_REG, ppc64.REGTMP, 0)
	p = appendpp(p, ppc64.AADD, obj.TYPE_REG, ppc64.REGTMP, 0, obj.TYPE_REG, ppc64.REGRT2, 0)
	p.Reg = ppc64.REGRT1
	p = appendpp(p, ppc64.AMOVDU, obj.TYPE_REG, ppc64.REGZERO, 0, obj.TYPE_MEM, ppc64.REGRT1, int64(gc.Widthptr))
	p1 := p
	p = appendpp(p, ppc64.ACMP, obj.TYPE_REG, ppc64.REGRT1, 0, obj.TYPE_REG, ppc64.REGRT2, 0)
	p = appendpp(p, ppc64.ABNE, obj.TYPE_NONE, 0, 0, obj.TYPE_BRANCH, 0, 0)
	gc.Patch(p, p1)
	}

	return p
	}

	func appendpp(p obj.Prog, as int, ftype int, freg int, foffset int64, ttype int, treg int, toffset int64) obj.Prog {
	q := gc.Ctxt.NewProg()
	gc.Clearp(q)
	q.As = int16(as)
	q.Lineno = p.Lineno
	q.From.Type = int16(ftype)
	q.From.Reg = int16(freg)
	q.From.Offset = foffset
	q.To.Type = int16(ttype)
	q.To.Reg = int16(treg)
	q.To.Offset = toffset
	q.Link = p.Link
	p.Link = q
	return q
	}

	/*
	* generate: BL reg, f
	* where both reg and f are registers.
	* On power, f must be moved to CTR first.
	*/
	func ginsBL(reg gc.Node, f gc.Node) {
	p := gins(ppc64.AMOVD, f, nil)
	p.To.Type = obj.TYPE_REG
	p.To.Reg = ppc64.REG_CTR
	p = gins(ppc64.ABL, reg, nil)
	p.To.Type = obj.TYPE_REG
	p.To.Reg = ppc64.REG_CTR
	}

	/*
	* generate:
	* call f
	* proc=-1 normal call but no return
	* proc=0 normal call
	* proc=1 goroutine run in new proc
	* proc=2 defer call save away stack
	* proc=3 normal call to C pointer (not Go func value)
	*/
	func ginscall(f *gc.Node, proc int) {
	if f.Type != nil {
	extra := int32(0)
	if proc == 1 \|\| proc == 2 {
	extra = 2 * int32(gc.Widthptr)
	}
	gc.Setmaxarg(f.Type, extra)
	}

	switch proc {
	default:
	gc.Fatal("ginscall: bad proc %d", proc)

	case 0, // normal call
	-1: // normal call but no return
	if f.Op == gc.ONAME && f.Class == gc.PFUNC {
	if f == gc.Deferreturn {
	// Deferred calls will appear to be returning to
	// the CALL deferreturn(SB) that we are about to emit.
	// However, the stack trace code will show the line
	// of the instruction byte before the return PC.
	// To avoid that being an unrelated instruction,
	// insert a ppc64 NOP that we will have the right line number.
	// The ppc64 NOP is really or r0, r0, r0; use that description
	// because the NOP pseudo-instruction would be removed by
	// the linker.
	var reg gc.Node
	gc.Nodreg(&reg, gc.Types[gc.TINT], ppc64.REG_R0)

	gins(ppc64.AOR, &reg, &reg)
	}

	p := gins(ppc64.ABL, nil, f)
	gc.Afunclit(&p.To, f)
	if proc == -1 \|\| gc.Noreturn(p) {
	gins(obj.AUNDEF, nil, nil)
	}
	break
	}

	var reg gc.Node
	gc.Nodreg(&reg, gc.Types[gc.Tptr], ppc64.REGCTXT)
	var r1 gc.Node
	gc.Nodreg(&r1, gc.Types[gc.Tptr], ppc64.REG_R3)
	gmove(f, &reg)
	reg.Op = gc.OINDREG
	gmove(&reg, &r1)
	reg.Op = gc.OREGISTER
	ginsBL(&reg, &r1)

	case 3: // normal call of c function pointer
	ginsBL(nil, f)

	case 1, // call in new proc (go)
	2: // deferred call (defer)
	var con gc.Node
	gc.Nodconst(&con, gc.Types[gc.TINT64], int64(gc.Argsize(f.Type)))

	var reg gc.Node
	gc.Nodreg(&reg, gc.Types[gc.TINT64], ppc64.REG_R3)
	var reg2 gc.Node
	gc.Nodreg(&reg2, gc.Types[gc.TINT64], ppc64.REG_R4)
	gmove(f, &reg)

	gmove(&con, &reg2)
	p := gins(ppc64.AMOVW, &reg2, nil)
	p.To.Type = obj.TYPE_MEM
	p.To.Reg = ppc64.REGSP
	p.To.Offset = 8

	p = gins(ppc64.AMOVD, &reg, nil)
	p.To.Type = obj.TYPE_MEM
	p.To.Reg = ppc64.REGSP
	p.To.Offset = 16

	if proc == 1 {
	ginscall(gc.Newproc, 0)
	} else {
	if gc.Hasdefer == 0 {
	gc.Fatal("hasdefer=0 but has defer")
	}
	ginscall(gc.Deferproc, 0)
	}

	if proc == 2 {
	gc.Nodreg(&reg, gc.Types[gc.TINT64], ppc64.REG_R3)
	p := gins(ppc64.ACMP, &reg, nil)
	p.To.Type = obj.TYPE_REG
	p.To.Reg = ppc64.REG_R0
	p = gc.Gbranch(ppc64.ABEQ, nil, +1)
	cgen_ret(nil)
	gc.Patch(p, gc.Pc)
	}
	}
	}

	/*
	* n is call to interface method.
	* generate res = n.
	*/
	func cgen_callinter(n gc.Node, res gc.Node, proc int) {
	i := n.Left
	if i.Op != gc.ODOTINTER {
	gc.Fatal("cgen_callinter: not ODOTINTER %v", gc.Oconv(int(i.Op), 0))
	}

	f := i.Right // field
	if f.Op != gc.ONAME {
	gc.Fatal("cgen_callinter: not ONAME %v", gc.Oconv(int(f.Op), 0))
	}

	i = i.Left // interface

	if i.Addable == 0 {
	var tmpi gc.Node
	gc.Tempname(&tmpi, i.Type)
	cgen(i, &tmpi)
	i = &tmpi
	}

	gc.Genlist(n.List) // assign the args

	// i is now addable, prepare an indirected
	// register to hold its address.
	var nodi gc.Node
	igen(i, &nodi, res) // REG = &inter

	var nodsp gc.Node
	gc.Nodindreg(&nodsp, gc.Types[gc.Tptr], ppc64.REGSP)

	nodsp.Xoffset = int64(gc.Widthptr)
	if proc != 0 {
	nodsp.Xoffset += 2 * int64(gc.Widthptr) // leave room for size & fn
	}
	nodi.Type = gc.Types[gc.Tptr]
	nodi.Xoffset += int64(gc.Widthptr)
	cgen(&nodi, &nodsp) // {8 or 24}(SP) = 8(REG) -- i.data

	var nodo gc.Node
	regalloc(&nodo, gc.Types[gc.Tptr], res)

	nodi.Type = gc.Types[gc.Tptr]
	nodi.Xoffset -= int64(gc.Widthptr)
	cgen(&nodi, &nodo) // REG = 0(REG) -- i.tab
	regfree(&nodi)

	var nodr gc.Node
	regalloc(&nodr, gc.Types[gc.Tptr], &nodo)
	if n.Left.Xoffset == gc.BADWIDTH {
	gc.Fatal("cgen_callinter: badwidth")
	}
	gc.Cgen_checknil(&nodo) // in case offset is huge
	nodo.Op = gc.OINDREG
	nodo.Xoffset = n.Left.Xoffset + 3*int64(gc.Widthptr) + 8
	if proc == 0 {
	// plain call: use direct c function pointer - more efficient
	cgen(&nodo, &nodr) // REG = 32+offset(REG) -- i.tab->fun[f]
	proc = 3
	} else {
	// go/defer. generate go func value.
	p := gins(ppc64.AMOVD, &nodo, &nodr) // REG = &(32+offset(REG)) -- i.tab->fun[f]
	p.From.Type = obj.TYPE_ADDR
	}

	nodr.Type = n.Left.Type
	ginscall(&nodr, proc)

	regfree(&nodr)
	regfree(&nodo)
	}

	/*
	* generate function call;
	* proc=0 normal call
	* proc=1 goroutine run in new proc
	* proc=2 defer call save away stack
	*/
	func cgen_call(n *gc.Node, proc int) {
	if n == nil {
	return
	}

	var afun gc.Node
	if n.Left.Ullman >= gc.UINF {
	// if name involves a fn call
	// precompute the address of the fn
	gc.Tempname(&afun, gc.Types[gc.Tptr])

	cgen(n.Left, &afun)
	}

	gc.Genlist(n.List) // assign the args
	t := n.Left.Type

	// call tempname pointer
	if n.Left.Ullman >= gc.UINF {
	var nod gc.Node
	regalloc(&nod, gc.Types[gc.Tptr], nil)
	gc.Cgen_as(&nod, &afun)
	nod.Type = t
	ginscall(&nod, proc)
	regfree(&nod)
	return
	}

	// call pointer
	if n.Left.Op != gc.ONAME \|\| n.Left.Class != gc.PFUNC {
	var nod gc.Node
	regalloc(&nod, gc.Types[gc.Tptr], nil)
	gc.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.
	*/
	func cgen_callret(n gc.Node, res gc.Node) {
	t := n.Left.Type
	if t.Etype == gc.TPTR32 \|\| t.Etype == gc.TPTR64 {
	t = t.Type
	}

	var flist gc.Iter
	fp := gc.Structfirst(&flist, gc.Getoutarg(t))
	if fp == nil {
	gc.Fatal("cgen_callret: nil")
	}

	nod := gc.Node{}
	nod.Op = gc.OINDREG
	nod.Val.U.Reg = ppc64.REGSP
	nod.Addable = 1

	nod.Xoffset = fp.Width + int64(gc.Widthptr) // +widthptr: saved LR at 0(R1)
	nod.Type = fp.Type
	gc.Cgen_as(res, &nod)
	}

	/*
	* call to n has already been generated.
	* generate:
	* res = &return value from call.
	*/
	func cgen_aret(n gc.Node, res gc.Node) {
	t := n.Left.Type
	if gc.Isptr[t.Etype] != 0 {
	t = t.Type
	}

	var flist gc.Iter
	fp := gc.Structfirst(&flist, gc.Getoutarg(t))
	if fp == nil {
	gc.Fatal("cgen_aret: nil")
	}

	nod1 := gc.Node{}
	nod1.Op = gc.OINDREG
	nod1.Val.U.Reg = ppc64.REGSP
	nod1.Addable = 1

	nod1.Xoffset = fp.Width + int64(gc.Widthptr) // +widthptr: saved lr at 0(SP)
	nod1.Type = fp.Type

	if res.Op != gc.OREGISTER {
	var nod2 gc.Node
	regalloc(&nod2, gc.Types[gc.Tptr], res)
	agen(&nod1, &nod2)
	gins(ppc64.AMOVD, &nod2, res)
	regfree(&nod2)
	} else {
	agen(&nod1, res)
	}
	}

	/*
	* generate return.
	* n->left is assignments to return values.
	*/
	func cgen_ret(n *gc.Node) {
	if n != nil {
	gc.Genlist(n.List) // copy out args
	}
	if gc.Hasdefer != 0 {
	ginscall(gc.Deferreturn, 0)
	}
	gc.Genlist(gc.Curfn.Exit)
	p := gins(obj.ARET, nil, nil)
	if n != nil && n.Op == gc.ORETJMP {
	p.To.Name = obj.NAME_EXTERN
	p.To.Type = obj.TYPE_ADDR
	p.To.Sym = gc.Linksym(n.Left.Sym)
	}
	}

	/*
	* generate division.
	* generates one of:
	* res = nl / nr
	* res = nl % nr
	* according to op.
	*/
	func dodiv(op int, nl gc.Node, nr gc.Node, res *gc.Node) {
	// Have to be careful about handling
	// most negative int divided by -1 correctly.
	// The hardware will generate undefined result.
	// Also need to explicitly trap on division on zero,
	// the hardware will silently generate undefined result.
	// DIVW will leave unpredicable result in higher 32-bit,
	// so always use DIVD/DIVDU.
	t := nl.Type

	t0 := t
	check := 0
	if gc.Issigned[t.Etype] != 0 {
	check = 1
	if gc.Isconst(nl, gc.CTINT) && gc.Mpgetfix(nl.Val.U.Xval) != -(1<<uint64(t.Width*8-1)) {
	check = 0
	} else if gc.Isconst(nr, gc.CTINT) && gc.Mpgetfix(nr.Val.U.Xval) != -1 {
	check = 0
	}
	}

	if t.Width < 8 {
	if gc.Issigned[t.Etype] != 0 {
	t = gc.Types[gc.TINT64]
	} else {
	t = gc.Types[gc.TUINT64]
	}
	check = 0
	}

	a := optoas(gc.ODIV, t)

	var tl gc.Node
	regalloc(&tl, t0, nil)
	var tr gc.Node
	regalloc(&tr, t0, nil)
	if nl.Ullman >= nr.Ullman {
	cgen(nl, &tl)
	cgen(nr, &tr)
	} else {
	cgen(nr, &tr)
	cgen(nl, &tl)
	}

	if t != t0 {
	// Convert
	tl2 := tl

	tr2 := tr
	tl.Type = t
	tr.Type = t
	gmove(&tl2, &tl)
	gmove(&tr2, &tr)
	}

	// Handle divide-by-zero panic.
	p1 := gins(optoas(gc.OCMP, t), &tr, nil)

	p1.To.Type = obj.TYPE_REG
	p1.To.Reg = ppc64.REGZERO
	p1 = gc.Gbranch(optoas(gc.ONE, t), nil, +1)
	if panicdiv == nil {
	panicdiv = gc.Sysfunc("panicdivide")
	}
	ginscall(panicdiv, -1)
	gc.Patch(p1, gc.Pc)

	var p2 *obj.Prog
	if check != 0 {
	var nm1 gc.Node
	gc.Nodconst(&nm1, t, -1)
	gins(optoas(gc.OCMP, t), &tr, &nm1)
	p1 := gc.Gbranch(optoas(gc.ONE, t), nil, +1)
	if op == gc.ODIV {
	// a / (-1) is -a.
	gins(optoas(gc.OMINUS, t), nil, &tl)

	gmove(&tl, res)
	} else {
	// a % (-1) is 0.
	var nz gc.Node
	gc.Nodconst(&nz, t, 0)

	gmove(&nz, res)
	}

	p2 = gc.Gbranch(obj.AJMP, nil, 0)
	gc.Patch(p1, gc.Pc)
	}

	p1 = gins(a, &tr, &tl)
	if op == gc.ODIV {
	regfree(&tr)
	gmove(&tl, res)
	} else {
	// A%B = A-(A/B*B)
	var tm gc.Node
	regalloc(&tm, t, nil)

	// patch div to use the 3 register form
	// TODO(minux): add gins3?
	p1.Reg = p1.To.Reg

	p1.To.Reg = tm.Val.U.Reg
	gins(optoas(gc.OMUL, t), &tr, &tm)
	regfree(&tr)
	gins(optoas(gc.OSUB, t), &tm, &tl)
	regfree(&tm)
	gmove(&tl, res)
	}

	regfree(&tl)
	if check != 0 {
	gc.Patch(p2, gc.Pc)
	}
	}

	/*
	* generate division according to op, one of:
	* res = nl / nr
	* res = nl % nr
	*/
	func cgen_div(op int, nl gc.Node, nr gc.Node, res *gc.Node) {
	// TODO(minux): enable division by magic multiply (also need to fix longmod below)
	//if(nr->op != OLITERAL)
	goto longdiv

	// division and mod using (slow) hardware instruction
	longdiv:
	dodiv(op, nl, nr, res)

	return
	}

	/*
	* generate high multiply:
	* res = (nl*nr) >> width
	*/
	func cgen_hmul(nl gc.Node, nr gc.Node, res *gc.Node) {
	// largest ullman on left.
	if nl.Ullman < nr.Ullman {
	tmp := (*gc.Node)(nl)
	nl = nr
	nr = tmp
	}

	t := (*gc.Type)(nl.Type)
	w := int(int(t.Width * 8))
	var n1 gc.Node
	cgenr(nl, &n1, res)
	var n2 gc.Node
	cgenr(nr, &n2, nil)
	switch gc.Simtype[t.Etype] {
	case gc.TINT8,
	gc.TINT16,
	gc.TINT32:
	gins(optoas(gc.OMUL, t), &n2, &n1)
	p := (*obj.Prog)(gins(ppc64.ASRAD, nil, &n1))
	p.From.Type = obj.TYPE_CONST
	p.From.Offset = int64(w)

	case gc.TUINT8,
	gc.TUINT16,
	gc.TUINT32:
	gins(optoas(gc.OMUL, t), &n2, &n1)
	p := (*obj.Prog)(gins(ppc64.ASRD, nil, &n1))
	p.From.Type = obj.TYPE_CONST
	p.From.Offset = int64(w)

	case gc.TINT64,
	gc.TUINT64:
	if gc.Issigned[t.Etype] != 0 {
	gins(ppc64.AMULHD, &n2, &n1)
	} else {
	gins(ppc64.AMULHDU, &n2, &n1)
	}

	default:
	gc.Fatal("cgen_hmul %v", gc.Tconv(t, 0))
	}

	cgen(&n1, res)
	regfree(&n1)
	regfree(&n2)
	}

	/*
	* generate shift according to op, one of:
	* res = nl << nr
	* res = nl >> nr
	*/
	func cgen_shift(op int, bounded bool, nl gc.Node, nr gc.Node, res *gc.Node) {
	var n1 gc.Node
	var n2 gc.Node
	var n3 gc.Node
	var tcount *gc.Type

	a := int(optoas(op, nl.Type))

	if nr.Op == gc.OLITERAL {
	var n1 gc.Node
	regalloc(&n1, nl.Type, res)
	cgen(nl, &n1)
	sc := uint64(uint64(gc.Mpgetfix(nr.Val.U.Xval)))
	if sc >= uint64(nl.Type.Width*8) {
	// large shift gets 2 shifts by width-1
	var n3 gc.Node
	gc.Nodconst(&n3, gc.Types[gc.TUINT32], nl.Type.Width*8-1)

	gins(a, &n3, &n1)
	gins(a, &n3, &n1)
	} else {
	gins(a, nr, &n1)
	}
	gmove(&n1, res)
	regfree(&n1)
	goto ret
	}

	if nl.Ullman >= gc.UINF {
	var n4 gc.Node
	gc.Tempname(&n4, nl.Type)
	cgen(nl, &n4)
	nl = &n4
	}

	if nr.Ullman >= gc.UINF {
	var n5 gc.Node
	gc.Tempname(&n5, nr.Type)
	cgen(nr, &n5)
	nr = &n5
	}

	// Allow either uint32 or uint64 as shift type,
	// to avoid unnecessary conversion from uint32 to uint64
	// just to do the comparison.
	tcount = gc.Types[gc.Simtype[nr.Type.Etype]]

	if tcount.Etype < gc.TUINT32 {
	tcount = gc.Types[gc.TUINT32]
	}

	regalloc(&n1, nr.Type, nil) // to hold the shift type in CX
	regalloc(&n3, tcount, &n1) // to clear high bits of CX

	regalloc(&n2, nl.Type, res)

	if nl.Ullman >= nr.Ullman {
	cgen(nl, &n2)
	cgen(nr, &n1)
	gmove(&n1, &n3)
	} else {
	cgen(nr, &n1)
	gmove(&n1, &n3)
	cgen(nl, &n2)
	}

	regfree(&n3)

	// test and fix up large shifts
	if !bounded {
	gc.Nodconst(&n3, tcount, nl.Type.Width*8)
	gins(optoas(gc.OCMP, tcount), &n1, &n3)
	p1 := (*obj.Prog)(gc.Gbranch(optoas(gc.OLT, tcount), nil, +1))
	if op == gc.ORSH && gc.Issigned[nl.Type.Etype] != 0 {
	gc.Nodconst(&n3, gc.Types[gc.TUINT32], nl.Type.Width*8-1)
	gins(a, &n3, &n2)
	} else {
	gc.Nodconst(&n3, nl.Type, 0)
	gmove(&n3, &n2)
	}

	gc.Patch(p1, gc.Pc)
	}

	gins(a, &n1, &n2)

	gmove(&n2, res)

	regfree(&n1)
	regfree(&n2)

	ret:
	}

	func clearfat(nl *gc.Node) {
	/* clear a fat object */
	if gc.Debug['g'] != 0 {
	fmt.Printf("clearfat %v (%v, size: %d)\n", gc.Nconv(nl, 0), gc.Tconv(nl.Type, 0), nl.Type.Width)
	}

	w := uint64(uint64(nl.Type.Width))

	// Avoid taking the address for simple enough types.
	//if(componentgen(N, nl))
	// return;

	c := uint64(w % 8) // bytes
	q := uint64(w / 8) // dwords

	if reg[ppc64.REGRT1] > 0 {
	gc.Fatal("R%d in use during clearfat", ppc64.REGRT1)
	}

	var r0 gc.Node
	gc.Nodreg(&r0, gc.Types[gc.TUINT64], ppc64.REG_R0) // r0 is always zero
	var dst gc.Node
	gc.Nodreg(&dst, gc.Types[gc.Tptr], ppc64.REGRT1)
	reg[ppc64.REGRT1]++
	agen(nl, &dst)

	var boff uint64
	var p *obj.Prog
	if q > 128 {
	p = gins(ppc64.ASUB, nil, &dst)
	p.From.Type = obj.TYPE_CONST
	p.From.Offset = 8

	var end gc.Node
	regalloc(&end, gc.Types[gc.Tptr], nil)
	p = gins(ppc64.AMOVD, &dst, &end)
	p.From.Type = obj.TYPE_ADDR
	p.From.Offset = int64(q * 8)

	p = gins(ppc64.AMOVDU, &r0, &dst)
	p.To.Type = obj.TYPE_MEM
	p.To.Offset = 8
	pl := (*obj.Prog)(p)

	p = gins(ppc64.ACMP, &dst, &end)
	gc.Patch(gc.Gbranch(ppc64.ABNE, nil, 0), pl)

	regfree(&end)

	// The loop leaves R3 on the last zeroed dword
	boff = 8
	} else if q >= 4 {
	p = gins(ppc64.ASUB, nil, &dst)
	p.From.Type = obj.TYPE_CONST
	p.From.Offset = 8
	f := (*gc.Node)(gc.Sysfunc("duffzero"))
	p = gins(obj.ADUFFZERO, nil, f)
	gc.Afunclit(&p.To, f)

	// 4 and 128 = magic constants: see ../../runtime/asm_ppc64x.s
	p.To.Offset = int64(4 * (128 - q))

	// duffzero leaves R3 on the last zeroed dword
	boff = 8
	} else {
	for t := uint64(0); t < q; t++ {
	p = gins(ppc64.AMOVD, &r0, &dst)
	p.To.Type = obj.TYPE_MEM
	p.To.Offset = int64(8 * t)
	}

	boff = 8 * q
	}

	for t := uint64(0); t < c; t++ {
	p = gins(ppc64.AMOVB, &r0, &dst)
	p.To.Type = obj.TYPE_MEM
	p.To.Offset = int64(t + boff)
	}

	reg[ppc64.REGRT1]--
	}

	// Called after regopt and peep have run.
	// Expand CHECKNIL pseudo-op into actual nil pointer check.
	func expandchecks(firstp *obj.Prog) {
	var p1 *obj.Prog
	var p2 *obj.Prog

	for p := (*obj.Prog)(firstp); p != nil; p = p.Link {
	if gc.Debug_checknil != 0 && gc.Ctxt.Debugvlog != 0 {
	fmt.Printf("expandchecks: %v\n", p)
	}
	if p.As != obj.ACHECKNIL {
	continue
	}
	if gc.Debug_checknil != 0 && p.Lineno > 1 { // p->lineno==1 in generated wrappers
	gc.Warnl(int(p.Lineno), "generated nil check")
	}
	if p.From.Type != obj.TYPE_REG {
	gc.Fatal("invalid nil check %v\n", p)
	}

	/*
	// check is
	// TD $4, R0, arg (R0 is always zero)
	// eqv. to:
	// tdeq r0, arg
	// NOTE: this needs special runtime support to make SIGTRAP recoverable.
	reg = p->from.reg;
	p->as = ATD;
	p->from = p->to = p->from3 = zprog.from;
	p->from.type = TYPE_CONST;
	p->from.offset = 4;
	p->from.reg = 0;
	p->reg = REG_R0;
	p->to.type = TYPE_REG;
	p->to.reg = reg;
	*/
	// check is
	// CMP arg, R0
	// BNE 2(PC) [likely]
	// MOVD R0, 0(R0)
	p1 = gc.Ctxt.NewProg()

	p2 = gc.Ctxt.NewProg()
	gc.Clearp(p1)
	gc.Clearp(p2)
	p1.Link = p2
	p2.Link = p.Link
	p.Link = p1
	p1.Lineno = p.Lineno
	p2.Lineno = p.Lineno
	p1.Pc = 9999
	p2.Pc = 9999
	p.As = ppc64.ACMP
	p.To.Type = obj.TYPE_REG
	p.To.Reg = ppc64.REGZERO
	p1.As = ppc64.ABNE

	//p1->from.type = TYPE_CONST;
	//p1->from.offset = 1; // likely
	p1.To.Type = obj.TYPE_BRANCH

	p1.To.U.Branch = p2.Link

	// crash by write to memory address 0.
	p2.As = ppc64.AMOVD

	p2.From.Type = obj.TYPE_REG
	p2.From.Reg = ppc64.REG_R0
	p2.To.Type = obj.TYPE_MEM
	p2.To.Reg = ppc64.REG_R0
	p2.To.Offset = 0
	}
	}