Beispiel #1
0
// is reg guaranteed to be truncated by a previous L instruction?
func prevl(r0 *gc.Flow, reg int) bool {
	for r := (*gc.Flow)(gc.Uniqp(r0)); r != nil; r = gc.Uniqp(r) {
		p := r.Prog
		if p.To.Type == obj.TYPE_REG && int(p.To.Reg) == reg {
			flags := progflags(p)
			if flags&gc.RightWrite != 0 {
				if flags&gc.SizeL != 0 {
					return true
				}
				return false
			}
		}
	}

	return false
}
Beispiel #2
0
/*
 * findinc finds ADD instructions with a constant
 * argument which falls within the immed_12 range.
 */
func findinc(r *gc.Flow, r2 *gc.Flow, v *obj.Addr) *gc.Flow {
	var r1 *gc.Flow
	var p *obj.Prog

	for r1 = gc.Uniqs(r); r1 != nil && r1 != r2; r, r1 = r1, gc.Uniqs(r1) {
		if gc.Uniqp(r1) != r {
			return nil
		}
		switch copyu(r1.Prog, v, nil) {
		case 0: /* not touched */
			continue

		case 4: /* set and used */
			p = r1.Prog

			if p.As == arm.AADD {
				if isdconst(&p.From) {
					if p.From.Offset > -4096 && p.From.Offset < 4096 {
						return r1
					}
				}
			}
			fallthrough

		default:
			return nil
		}
	}

	return nil
}
Beispiel #3
0
/*
 * findpre returns the last instruction mentioning v
 * before r. It must be a set, and there must be
 * a unique path from that instruction to r.
 */
func findpre(r *gc.Flow, v *obj.Addr) *gc.Flow {
	var r1 *gc.Flow

	for r1 = gc.Uniqp(r); r1 != nil; r, r1 = r1, gc.Uniqp(r1) {
		if gc.Uniqs(r1) != r {
			return nil
		}
		switch copyu(r1.Prog, v, nil) {
		case 1, /* used */
			2: /* read-alter-rewrite */
			return nil

		case 3, /* set */
			4: /* set and used */
			return r1
		}
	}

	return nil
}
Beispiel #4
0
func conprop(r0 *gc.Flow) {
	var p *obj.Prog
	var t int

	p0 := (*obj.Prog)(r0.Prog)
	v0 := (*obj.Addr)(&p0.To)
	r := (*gc.Flow)(r0)

loop:
	r = gc.Uniqs(r)
	if r == nil || r == r0 {
		return
	}
	if gc.Uniqp(r) == nil {
		return
	}

	p = r.Prog
	t = copyu(p, v0, nil)
	switch t {
	case 0, // miss
		1: // use
		goto loop

	case 2, // rar
		4: // use and set
		break

	case 3: // set
		if p.As == p0.As {
			if p.From.Type == p0.From.Type {
				if p.From.Reg == p0.From.Reg {
					if p.From.Node == p0.From.Node {
						if p.From.Offset == p0.From.Offset {
							if p.From.Scale == p0.From.Scale {
								if p.From.Type == obj.TYPE_FCONST && p.From.Val.(float64) == p0.From.Val.(float64) {
									if p.From.Index == p0.From.Index {
										excise(r)
										goto loop
									}
								}
							}
						}
					}
				}
			}
		}
	}
}
Beispiel #5
0
/*
 * The idea is to remove redundant constants.
 *	$c1->v1
 *	($c1->v2 s/$c1/v1)*
 *	set v1  return
 * The v1->v2 should be eliminated by copy propagation.
 */
func constprop(c1 *obj.Addr, v1 *obj.Addr, r *gc.Flow) {
	if gc.Debug['P'] != 0 {
		fmt.Printf("constprop %v->%v\n", gc.Ctxt.Dconv(c1), gc.Ctxt.Dconv(v1))
	}
	var p *obj.Prog
	for ; r != nil; r = r.S1 {
		p = r.Prog
		if gc.Debug['P'] != 0 {
			fmt.Printf("%v", p)
		}
		if gc.Uniqp(r) == nil {
			if gc.Debug['P'] != 0 {
				fmt.Printf("; merge; return\n")
			}
			return
		}

		if p.As == arm.AMOVW && copyas(&p.From, c1) {
			if gc.Debug['P'] != 0 {
				fmt.Printf("; sub%v/%v", gc.Ctxt.Dconv(&p.From), gc.Ctxt.Dconv(v1))
			}
			p.From = *v1
		} else if copyu(p, v1, nil) > 1 {
			if gc.Debug['P'] != 0 {
				fmt.Printf("; %vset; return\n", gc.Ctxt.Dconv(v1))
			}
			return
		}

		if gc.Debug['P'] != 0 {
			fmt.Printf("\n")
		}
		if r.S2 != nil {
			constprop(c1, v1, r.S2)
		}
	}
}
Beispiel #6
0
// copy1 replaces uses of v2 with v1 starting at r and returns 1 if
// all uses were rewritten.
func copy1(v1 *obj.Addr, v2 *obj.Addr, r *gc.Flow, f int) bool {
	if uint32(r.Active) == gactive {
		if gc.Debug['P'] != 0 {
			fmt.Printf("act set; return 1\n")
		}
		return true
	}

	r.Active = int32(gactive)
	if gc.Debug['P'] != 0 {
		fmt.Printf("copy1 replace %v with %v f=%d\n", gc.Ctxt.Dconv(v2), gc.Ctxt.Dconv(v1), f)
	}
	var t int
	var p *obj.Prog
	for ; r != nil; r = r.S1 {
		p = r.Prog
		if gc.Debug['P'] != 0 {
			fmt.Printf("%v", p)
		}
		if f == 0 && gc.Uniqp(r) == nil {
			// Multiple predecessors; conservatively
			// assume v1 was set on other path
			f = 1

			if gc.Debug['P'] != 0 {
				fmt.Printf("; merge; f=%d", f)
			}
		}

		t = copyu(p, v2, nil)
		switch t {
		case 2: /* rar, can't split */
			if gc.Debug['P'] != 0 {
				fmt.Printf("; %v rar; return 0\n", gc.Ctxt.Dconv(v2))
			}
			return false

		case 3: /* set */
			if gc.Debug['P'] != 0 {
				fmt.Printf("; %v set; return 1\n", gc.Ctxt.Dconv(v2))
			}
			return true

		case 1, /* used, substitute */
			4: /* use and set */
			if f != 0 {
				if gc.Debug['P'] == 0 {
					return false
				}
				if t == 4 {
					fmt.Printf("; %v used+set and f=%d; return 0\n", gc.Ctxt.Dconv(v2), f)
				} else {
					fmt.Printf("; %v used and f=%d; return 0\n", gc.Ctxt.Dconv(v2), f)
				}
				return false
			}

			if copyu(p, v2, v1) != 0 {
				if gc.Debug['P'] != 0 {
					fmt.Printf("; sub fail; return 0\n")
				}
				return false
			}

			if gc.Debug['P'] != 0 {
				fmt.Printf("; sub %v->%v\n => %v", gc.Ctxt.Dconv(v2), gc.Ctxt.Dconv(v1), p)
			}
			if t == 4 {
				if gc.Debug['P'] != 0 {
					fmt.Printf("; %v used+set; return 1\n", gc.Ctxt.Dconv(v2))
				}
				return true
			}
		}

		if f == 0 {
			t = copyu(p, v1, nil)
			if f == 0 && (t == 2 || t == 3 || t == 4) {
				f = 1
				if gc.Debug['P'] != 0 {
					fmt.Printf("; %v set and !f; f=%d", gc.Ctxt.Dconv(v1), f)
				}
			}
		}

		if gc.Debug['P'] != 0 {
			fmt.Printf("\n")
		}
		if r.S2 != nil {
			if !copy1(v1, v2, r.S2, f) {
				return false
			}
		}
	}

	return true
}
Beispiel #7
0
/*
 * the idea is to substitute
 * one register for another
 * from one MOV to another
 *	MOV	a, R1
 *	ADD	b, R1	/ no use of R2
 *	MOV	R1, R2
 * would be converted to
 *	MOV	a, R2
 *	ADD	b, R2
 *	MOV	R2, R1
 * hopefully, then the former or latter MOV
 * will be eliminated by copy propagation.
 *
 * r0 (the argument, not the register) is the MOV at the end of the
 * above sequences.  This returns 1 if it modified any instructions.
 */
func subprop(r0 *gc.Flow) bool {
	p := (*obj.Prog)(r0.Prog)
	v1 := (*obj.Addr)(&p.From)
	if !regtyp(v1) {
		return false
	}
	v2 := (*obj.Addr)(&p.To)
	if !regtyp(v2) {
		return false
	}
	for r := gc.Uniqp(r0); r != nil; r = gc.Uniqp(r) {
		if gc.Uniqs(r) == nil {
			break
		}
		p = r.Prog
		if p.As == obj.AVARDEF || p.As == obj.AVARKILL {
			continue
		}
		if p.Info.Flags&gc.Call != 0 {
			return false
		}

		if p.Info.Flags&(gc.RightRead|gc.RightWrite) == gc.RightWrite {
			if p.To.Type == v1.Type {
				if p.To.Reg == v1.Reg {
					copysub(&p.To, v1, v2, 1)
					if gc.Debug['P'] != 0 {
						fmt.Printf("gotit: %v->%v\n%v", gc.Ctxt.Dconv(v1), gc.Ctxt.Dconv(v2), r.Prog)
						if p.From.Type == v2.Type {
							fmt.Printf(" excise")
						}
						fmt.Printf("\n")
					}

					for r = gc.Uniqs(r); r != r0; r = gc.Uniqs(r) {
						p = r.Prog
						copysub(&p.From, v1, v2, 1)
						copysub1(p, v1, v2, 1)
						copysub(&p.To, v1, v2, 1)
						if gc.Debug['P'] != 0 {
							fmt.Printf("%v\n", r.Prog)
						}
					}

					t := int(int(v1.Reg))
					v1.Reg = v2.Reg
					v2.Reg = int16(t)
					if gc.Debug['P'] != 0 {
						fmt.Printf("%v last\n", r.Prog)
					}
					return true
				}
			}
		}

		if copyau(&p.From, v2) || copyau1(p, v2) || copyau(&p.To, v2) {
			break
		}
		if copysub(&p.From, v1, v2, 0) != 0 || copysub1(p, v1, v2, 0) != 0 || copysub(&p.To, v1, v2, 0) != 0 {
			break
		}
	}

	return false
}
Beispiel #8
0
/*
 * ASLL x,y,w
 * .. (not use w, not set x y w)
 * AXXX w,a,b (a != w)
 * .. (not use w)
 * (set w)
 * ----------- changed to
 * ..
 * AXXX (x<<y),a,b
 * ..
 */
func shiftprop(r *gc.Flow) bool {
	p := (*obj.Prog)(r.Prog)
	if p.To.Type != obj.TYPE_REG {
		if gc.Debug['P'] != 0 {
			fmt.Printf("\tBOTCH: result not reg; FAILURE\n")
		}
		return false
	}

	n := int(int(p.To.Reg))
	a := obj.Addr(obj.Addr{})
	if p.Reg != 0 && p.Reg != p.To.Reg {
		a.Type = obj.TYPE_REG
		a.Reg = p.Reg
	}

	if gc.Debug['P'] != 0 {
		fmt.Printf("shiftprop\n%v", p)
	}
	r1 := (*gc.Flow)(r)
	var p1 *obj.Prog
	for {
		/* find first use of shift result; abort if shift operands or result are changed */
		r1 = gc.Uniqs(r1)

		if r1 == nil {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tbranch; FAILURE\n")
			}
			return false
		}

		if gc.Uniqp(r1) == nil {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tmerge; FAILURE\n")
			}
			return false
		}

		p1 = r1.Prog
		if gc.Debug['P'] != 0 {
			fmt.Printf("\n%v", p1)
		}
		switch copyu(p1, &p.To, nil) {
		case 0: /* not used or set */
			if (p.From.Type == obj.TYPE_REG && copyu(p1, &p.From, nil) > 1) || (a.Type == obj.TYPE_REG && copyu(p1, &a, nil) > 1) {
				if gc.Debug['P'] != 0 {
					fmt.Printf("\targs modified; FAILURE\n")
				}
				return false
			}

			continue
		case 3: /* set, not used */
			{
				if gc.Debug['P'] != 0 {
					fmt.Printf("\tBOTCH: noref; FAILURE\n")
				}
				return false
			}
		}

		break
	}

	/* check whether substitution can be done */
	switch p1.As {
	default:
		if gc.Debug['P'] != 0 {
			fmt.Printf("\tnon-dpi; FAILURE\n")
		}
		return false

	case arm.AAND,
		arm.AEOR,
		arm.AADD,
		arm.AADC,
		arm.AORR,
		arm.ASUB,
		arm.ASBC,
		arm.ARSB,
		arm.ARSC:
		if int(p1.Reg) == n || (p1.Reg == 0 && p1.To.Type == obj.TYPE_REG && int(p1.To.Reg) == n) {
			if p1.From.Type != obj.TYPE_REG {
				if gc.Debug['P'] != 0 {
					fmt.Printf("\tcan't swap; FAILURE\n")
				}
				return false
			}

			p1.Reg = p1.From.Reg
			p1.From.Reg = int16(n)
			switch p1.As {
			case arm.ASUB:
				p1.As = arm.ARSB

			case arm.ARSB:
				p1.As = arm.ASUB

			case arm.ASBC:
				p1.As = arm.ARSC

			case arm.ARSC:
				p1.As = arm.ASBC
			}

			if gc.Debug['P'] != 0 {
				fmt.Printf("\t=>%v", p1)
			}
		}
		fallthrough

	case arm.ABIC,
		arm.ATST,
		arm.ACMP,
		arm.ACMN:
		if int(p1.Reg) == n {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tcan't swap; FAILURE\n")
			}
			return false
		}

		if p1.Reg == 0 && int(p1.To.Reg) == n {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tshift result used twice; FAILURE\n")
			}
			return false
		}

		//	case AMVN:
		if p1.From.Type == obj.TYPE_SHIFT {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tshift result used in shift; FAILURE\n")
			}
			return false
		}

		if p1.From.Type != obj.TYPE_REG || int(p1.From.Reg) != n {
			if gc.Debug['P'] != 0 {
				fmt.Printf("\tBOTCH: where is it used?; FAILURE\n")
			}
			return false
		}
	}

	/* check whether shift result is used subsequently */
	p2 := (*obj.Prog)(p1)

	if int(p1.To.Reg) != n {
		var p1 *obj.Prog
		for {
			r1 = gc.Uniqs(r1)
			if r1 == nil {
				if gc.Debug['P'] != 0 {
					fmt.Printf("\tinconclusive; FAILURE\n")
				}
				return false
			}

			p1 = r1.Prog
			if gc.Debug['P'] != 0 {
				fmt.Printf("\n%v", p1)
			}
			switch copyu(p1, &p.To, nil) {
			case 0: /* not used or set */
				continue

			case 3: /* set, not used */
				break

			default: /* used */
				if gc.Debug['P'] != 0 {
					fmt.Printf("\treused; FAILURE\n")
				}
				return false
			}

			break
		}
	}

	/* make the substitution */
	p2.From.Reg = 0

	o := int(int(p.Reg))
	if o == 0 {
		o = int(p.To.Reg)
	}
	o &= 15

	switch p.From.Type {
	case obj.TYPE_CONST:
		o |= int((p.From.Offset & 0x1f) << 7)

	case obj.TYPE_REG:
		o |= 1<<4 | (int(p.From.Reg)&15)<<8
	}

	switch p.As {
	case arm.ASLL:
		o |= 0 << 5

	case arm.ASRL:
		o |= 1 << 5

	case arm.ASRA:
		o |= 2 << 5
	}

	p2.From = obj.Addr{}
	p2.From.Type = obj.TYPE_SHIFT
	p2.From.Offset = int64(o)
	if gc.Debug['P'] != 0 {
		fmt.Printf("\t=>%v\tSUCCEED\n", p2)
	}
	return true
}
Beispiel #9
0
/*
 * the idea is to substitute
 * one register for another
 * from one MOV to another
 *	MOV	a, R0
 *	ADD	b, R0	/ no use of R1
 *	MOV	R0, R1
 * would be converted to
 *	MOV	a, R1
 *	ADD	b, R1
 *	MOV	R1, R0
 * hopefully, then the former or latter MOV
 * will be eliminated by copy propagation.
 */
func subprop(r0 *gc.Flow) bool {
	p := (*obj.Prog)(r0.Prog)
	v1 := (*obj.Addr)(&p.From)
	if !regtyp(v1) {
		return false
	}
	v2 := (*obj.Addr)(&p.To)
	if !regtyp(v2) {
		return false
	}
	for r := gc.Uniqp(r0); r != nil; r = gc.Uniqp(r) {
		if gc.Uniqs(r) == nil {
			break
		}
		p = r.Prog
		if p.As == obj.AVARDEF || p.As == obj.AVARKILL {
			continue
		}
		if p.Info.Flags&gc.Call != 0 {
			return false
		}

		// TODO(rsc): Whatever invalidated the info should have done this call.
		proginfo(p)

		if (p.Info.Flags&gc.CanRegRead != 0) && p.To.Type == obj.TYPE_REG {
			p.Info.Flags |= gc.RegRead
			p.Info.Flags &^= (gc.CanRegRead | gc.RightRead)
			p.Reg = p.To.Reg
		}

		switch p.As {
		case arm.AMULLU,
			arm.AMULA,
			arm.AMVN:
			return false
		}

		if p.Info.Flags&(gc.RightRead|gc.RightWrite) == gc.RightWrite {
			if p.To.Type == v1.Type {
				if p.To.Reg == v1.Reg {
					if p.Scond == arm.C_SCOND_NONE {
						copysub(&p.To, v1, v2, 1)
						if gc.Debug['P'] != 0 {
							fmt.Printf("gotit: %v->%v\n%v", gc.Ctxt.Dconv(v1), gc.Ctxt.Dconv(v2), r.Prog)
							if p.From.Type == v2.Type {
								fmt.Printf(" excise")
							}
							fmt.Printf("\n")
						}

						for r = gc.Uniqs(r); r != r0; r = gc.Uniqs(r) {
							p = r.Prog
							copysub(&p.From, v1, v2, 1)
							copysub1(p, v1, v2, 1)
							copysub(&p.To, v1, v2, 1)
							if gc.Debug['P'] != 0 {
								fmt.Printf("%v\n", r.Prog)
							}
						}

						t := int(int(v1.Reg))
						v1.Reg = v2.Reg
						v2.Reg = int16(t)
						if gc.Debug['P'] != 0 {
							fmt.Printf("%v last\n", r.Prog)
						}
						return true
					}
				}
			}
		}

		if copyau(&p.From, v2) || copyau1(p, v2) || copyau(&p.To, v2) {
			break
		}
		if copysub(&p.From, v1, v2, 0) != 0 || copysub1(p, v1, v2, 0) != 0 || copysub(&p.To, v1, v2, 0) != 0 {
			break
		}
	}

	return false
}
Beispiel #10
0
/*
 * the idea is to substitute
 * one register for another
 * from one MOV to another
 *	MOV	a, R0
 *	ADD	b, R0	/ no use of R1
 *	MOV	R0, R1
 * would be converted to
 *	MOV	a, R1
 *	ADD	b, R1
 *	MOV	R1, R0
 * hopefully, then the former or latter MOV
 * will be eliminated by copy propagation.
 */
func subprop(r0 *gc.Flow) bool {
	if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
		fmt.Printf("subprop %v\n", r0.Prog)
	}
	p := (*obj.Prog)(r0.Prog)
	v1 := (*obj.Addr)(&p.From)
	if !regtyp(v1) {
		if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
			fmt.Printf("\tnot regtype %v; return 0\n", gc.Ctxt.Dconv(v1))
		}
		return false
	}

	v2 := (*obj.Addr)(&p.To)
	if !regtyp(v2) {
		if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
			fmt.Printf("\tnot regtype %v; return 0\n", gc.Ctxt.Dconv(v2))
		}
		return false
	}

	for r := gc.Uniqp(r0); r != nil; r = gc.Uniqp(r) {
		if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
			fmt.Printf("\t? %v\n", r.Prog)
		}
		if gc.Uniqs(r) == nil {
			if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
				fmt.Printf("\tno unique successor\n")
			}
			break
		}

		p = r.Prog
		if p.As == obj.AVARDEF || p.As == obj.AVARKILL {
			continue
		}
		if p.Info.Flags&gc.Call != 0 {
			if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
				fmt.Printf("\tfound %v; return 0\n", p)
			}
			return false
		}

		if p.Info.Reguse|p.Info.Regset != 0 {
			if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
				fmt.Printf("\tfound %v; return 0\n", p)
			}
			return false
		}

		if (p.Info.Flags&gc.Move != 0) && (p.Info.Flags&(gc.SizeL|gc.SizeQ|gc.SizeF|gc.SizeD) != 0) && p.To.Type == v1.Type && p.To.Reg == v1.Reg {
			copysub(&p.To, v1, v2, 1)
			if gc.Debug['P'] != 0 {
				fmt.Printf("gotit: %v->%v\n%v", gc.Ctxt.Dconv(v1), gc.Ctxt.Dconv(v2), r.Prog)
				if p.From.Type == v2.Type && p.From.Reg == v2.Reg {
					fmt.Printf(" excise")
				}
				fmt.Printf("\n")
			}

			for r = gc.Uniqs(r); r != r0; r = gc.Uniqs(r) {
				p = r.Prog
				copysub(&p.From, v1, v2, 1)
				copysub(&p.To, v1, v2, 1)
				if gc.Debug['P'] != 0 {
					fmt.Printf("%v\n", r.Prog)
				}
			}

			t := int(int(v1.Reg))
			v1.Reg = v2.Reg
			v2.Reg = int16(t)
			if gc.Debug['P'] != 0 {
				fmt.Printf("%v last\n", r.Prog)
			}
			return true
		}

		if copyau(&p.From, v2) || copyau(&p.To, v2) {
			if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
				fmt.Printf("\tcopyau %v failed\n", gc.Ctxt.Dconv(v2))
			}
			break
		}

		if copysub(&p.From, v1, v2, 0) != 0 || copysub(&p.To, v1, v2, 0) != 0 {
			if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
				fmt.Printf("\tcopysub failed\n")
			}
			break
		}
	}

	if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
		fmt.Printf("\tran off end; return 0\n")
	}
	return false
}
Beispiel #11
0
func pushback(r0 *gc.Flow) {
	var r *gc.Flow
	var p *obj.Prog

	var b *gc.Flow
	p0 := (*obj.Prog)(r0.Prog)
	for r = gc.Uniqp(r0); r != nil && gc.Uniqs(r) != nil; r = gc.Uniqp(r) {
		p = r.Prog
		if p.As != obj.ANOP {
			if !regconsttyp(&p.From) || !regtyp(&p.To) {
				break
			}
			if copyu(p, &p0.To, nil) != 0 || copyu(p0, &p.To, nil) != 0 {
				break
			}
		}

		if p.As == obj.ACALL {
			break
		}
		b = r
	}

	if b == nil {
		if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
			fmt.Printf("no pushback: %v\n", r0.Prog)
			if r != nil {
				fmt.Printf("\t%v [%v]\n", r.Prog, gc.Uniqs(r) != nil)
			}
		}

		return
	}

	if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
		fmt.Printf("pushback\n")
		for r := (*gc.Flow)(b); ; r = r.Link {
			fmt.Printf("\t%v\n", r.Prog)
			if r == r0 {
				break
			}
		}
	}

	t := obj.Prog(*r0.Prog)
	for r = gc.Uniqp(r0); ; r = gc.Uniqp(r) {
		p0 = r.Link.Prog
		p = r.Prog
		p0.As = p.As
		p0.Lineno = p.Lineno
		p0.From = p.From
		p0.To = p.To

		if r == b {
			break
		}
	}

	p0 = r.Prog
	p0.As = t.As
	p0.Lineno = t.Lineno
	p0.From = t.From
	p0.To = t.To

	if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
		fmt.Printf("\tafter\n")
		for r := (*gc.Flow)(b); ; r = r.Link {
			fmt.Printf("\t%v\n", r.Prog)
			if r == r0 {
				break
			}
		}
	}
}
Beispiel #12
0
/*
 * the idea is to substitute
 * one register for another
 * from one MOV to another
 *	MOV	a, R0
 *	ADD	b, R0	/ no use of R1
 *	MOV	R0, R1
 * would be converted to
 *	MOV	a, R1
 *	ADD	b, R1
 *	MOV	R1, R0
 * hopefully, then the former or latter MOV
 * will be eliminated by copy propagation.
 */
func subprop(r0 *gc.Flow) bool {
	p := r0.Prog
	v1 := &p.From
	if !regtyp(v1) {
		return false
	}
	v2 := &p.To
	if !regtyp(v2) {
		return false
	}
	for r := gc.Uniqp(r0); r != nil; r = gc.Uniqp(r) {
		if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
			fmt.Printf("\t? %v\n", r.Prog)
		}
		if gc.Uniqs(r) == nil {
			break
		}
		p = r.Prog
		if p.As == obj.AVARDEF || p.As == obj.AVARKILL {
			continue
		}
		if p.Info.Flags&gc.Call != 0 {
			return false
		}

		if p.Info.Reguse|p.Info.Regset != 0 {
			return false
		}

		if (p.Info.Flags&gc.Move != 0) && (p.Info.Flags&(gc.SizeL|gc.SizeQ|gc.SizeF|gc.SizeD) != 0) && p.To.Type == v1.Type && p.To.Reg == v1.Reg {
			copysub(&p.To, v1, v2, 1)
			if gc.Debug['P'] != 0 {
				fmt.Printf("gotit: %v->%v\n%v", gc.Ctxt.Dconv(v1), gc.Ctxt.Dconv(v2), r.Prog)
				if p.From.Type == v2.Type && p.From.Reg == v2.Reg {
					fmt.Printf(" excise")
				}
				fmt.Printf("\n")
			}

			for r = gc.Uniqs(r); r != r0; r = gc.Uniqs(r) {
				p = r.Prog
				copysub(&p.From, v1, v2, 1)
				copysub(&p.To, v1, v2, 1)
				if gc.Debug['P'] != 0 {
					fmt.Printf("%v\n", r.Prog)
				}
			}

			t := int(v1.Reg)
			v1.Reg = v2.Reg
			v2.Reg = int16(t)
			if gc.Debug['P'] != 0 {
				fmt.Printf("%v last\n", r.Prog)
			}
			return true
		}

		if copyau(&p.From, v2) || copyau(&p.To, v2) {
			break
		}
		if copysub(&p.From, v1, v2, 0) != 0 || copysub(&p.To, v1, v2, 0) != 0 {
			break
		}
	}

	return false
}
Beispiel #13
0
func peep(firstp *obj.Prog) {
	g := (*gc.Graph)(gc.Flowstart(firstp, nil))
	if g == nil {
		return
	}
	gactive = 0

	var p *obj.Prog
	var r *gc.Flow
	var t int
loop1:
	if gc.Debug['P'] != 0 && gc.Debug['v'] != 0 {
		gc.Dumpit("loop1", g.Start, 0)
	}

	t = 0
	for r = g.Start; r != nil; r = r.Link {
		p = r.Prog

		// TODO(austin) Handle smaller moves.  arm and amd64
		// distinguish between moves that moves that *must*
		// sign/zero extend and moves that don't care so they
		// can eliminate moves that don't care without
		// breaking moves that do care.  This might let us
		// simplify or remove the next peep loop, too.
		if p.As == ppc64.AMOVD || p.As == ppc64.AFMOVD {
			if regtyp(&p.To) {
				// Try to eliminate reg->reg moves
				if regtyp(&p.From) {
					if p.From.Type == p.To.Type {
						if copyprop(r) {
							excise(r)
							t++
						} else if subprop(r) && copyprop(r) {
							excise(r)
							t++
						}
					}
				}

				// Convert uses to $0 to uses of R0 and
				// propagate R0
				if regzer(&p.From) != 0 {
					if p.To.Type == obj.TYPE_REG {
						p.From.Type = obj.TYPE_REG
						p.From.Reg = ppc64.REGZERO
						if copyprop(r) {
							excise(r)
							t++
						} else if subprop(r) && copyprop(r) {
							excise(r)
							t++
						}
					}
				}
			}
		}
	}

	if t != 0 {
		goto loop1
	}

	/*
	 * look for MOVB x,R; MOVB R,R (for small MOVs not handled above)
	 */
	var p1 *obj.Prog
	var r1 *gc.Flow
	for r := (*gc.Flow)(g.Start); r != nil; r = r.Link {
		p = r.Prog
		switch p.As {
		default:
			continue

		case ppc64.AMOVH,
			ppc64.AMOVHZ,
			ppc64.AMOVB,
			ppc64.AMOVBZ,
			ppc64.AMOVW,
			ppc64.AMOVWZ:
			if p.To.Type != obj.TYPE_REG {
				continue
			}
		}

		r1 = r.Link
		if r1 == nil {
			continue
		}
		p1 = r1.Prog
		if p1.As != p.As {
			continue
		}
		if p1.From.Type != obj.TYPE_REG || p1.From.Reg != p.To.Reg {
			continue
		}
		if p1.To.Type != obj.TYPE_REG || p1.To.Reg != p.To.Reg {
			continue
		}
		excise(r1)
	}

	if gc.Debug['D'] > 1 {
		goto ret /* allow following code improvement to be suppressed */
	}

	/*
	 * look for OP x,y,R; CMP R, $0 -> OPCC x,y,R
	 * when OP can set condition codes correctly
	 */
	for r := (*gc.Flow)(g.Start); r != nil; r = r.Link {
		p = r.Prog
		switch p.As {
		case ppc64.ACMP,
			ppc64.ACMPW: /* always safe? */
			if regzer(&p.To) == 0 {
				continue
			}
			r1 = r.S1
			if r1 == nil {
				continue
			}
			switch r1.Prog.As {
			default:
				continue

				/* the conditions can be complex and these are currently little used */
			case ppc64.ABCL,
				ppc64.ABC:
				continue

			case ppc64.ABEQ,
				ppc64.ABGE,
				ppc64.ABGT,
				ppc64.ABLE,
				ppc64.ABLT,
				ppc64.ABNE,
				ppc64.ABVC,
				ppc64.ABVS:
				break
			}

			r1 = r
			for {
				r1 = gc.Uniqp(r1)
				if r1 == nil || r1.Prog.As != obj.ANOP {
					break
				}
			}

			if r1 == nil {
				continue
			}
			p1 = r1.Prog
			if p1.To.Type != obj.TYPE_REG || p1.To.Reg != p.From.Reg {
				continue
			}
			switch p1.As {
			/* irregular instructions */
			case ppc64.ASUB,
				ppc64.AADD,
				ppc64.AXOR,
				ppc64.AOR:
				if p1.From.Type == obj.TYPE_CONST || p1.From.Type == obj.TYPE_ADDR {
					continue
				}
			}

			switch p1.As {
			default:
				continue

			case ppc64.AMOVW,
				ppc64.AMOVD:
				if p1.From.Type != obj.TYPE_REG {
					continue
				}
				continue

			case ppc64.AANDCC,
				ppc64.AANDNCC,
				ppc64.AORCC,
				ppc64.AORNCC,
				ppc64.AXORCC,
				ppc64.ASUBCC,
				ppc64.ASUBECC,
				ppc64.ASUBMECC,
				ppc64.ASUBZECC,
				ppc64.AADDCC,
				ppc64.AADDCCC,
				ppc64.AADDECC,
				ppc64.AADDMECC,
				ppc64.AADDZECC,
				ppc64.ARLWMICC,
				ppc64.ARLWNMCC,
				/* don't deal with floating point instructions for now */
				/*
					case AFABS:
					case AFADD:
					case AFADDS:
					case AFCTIW:
					case AFCTIWZ:
					case AFDIV:
					case AFDIVS:
					case AFMADD:
					case AFMADDS:
					case AFMOVD:
					case AFMSUB:
					case AFMSUBS:
					case AFMUL:
					case AFMULS:
					case AFNABS:
					case AFNEG:
					case AFNMADD:
					case AFNMADDS:
					case AFNMSUB:
					case AFNMSUBS:
					case AFRSP:
					case AFSUB:
					case AFSUBS:
					case ACNTLZW:
					case AMTFSB0:
					case AMTFSB1:
				*/
				ppc64.AADD,
				ppc64.AADDV,
				ppc64.AADDC,
				ppc64.AADDCV,
				ppc64.AADDME,
				ppc64.AADDMEV,
				ppc64.AADDE,
				ppc64.AADDEV,
				ppc64.AADDZE,
				ppc64.AADDZEV,
				ppc64.AAND,
				ppc64.AANDN,
				ppc64.ADIVW,
				ppc64.ADIVWV,
				ppc64.ADIVWU,
				ppc64.ADIVWUV,
				ppc64.ADIVD,
				ppc64.ADIVDV,
				ppc64.ADIVDU,
				ppc64.ADIVDUV,
				ppc64.AEQV,
				ppc64.AEXTSB,
				ppc64.AEXTSH,
				ppc64.AEXTSW,
				ppc64.AMULHW,
				ppc64.AMULHWU,
				ppc64.AMULLW,
				ppc64.AMULLWV,
				ppc64.AMULHD,
				ppc64.AMULHDU,
				ppc64.AMULLD,
				ppc64.AMULLDV,
				ppc64.ANAND,
				ppc64.ANEG,
				ppc64.ANEGV,
				ppc64.ANOR,
				ppc64.AOR,
				ppc64.AORN,
				ppc64.AREM,
				ppc64.AREMV,
				ppc64.AREMU,
				ppc64.AREMUV,
				ppc64.AREMD,
				ppc64.AREMDV,
				ppc64.AREMDU,
				ppc64.AREMDUV,
				ppc64.ARLWMI,
				ppc64.ARLWNM,
				ppc64.ASLW,
				ppc64.ASRAW,
				ppc64.ASRW,
				ppc64.ASLD,
				ppc64.ASRAD,
				ppc64.ASRD,
				ppc64.ASUB,
				ppc64.ASUBV,
				ppc64.ASUBC,
				ppc64.ASUBCV,
				ppc64.ASUBME,
				ppc64.ASUBMEV,
				ppc64.ASUBE,
				ppc64.ASUBEV,
				ppc64.ASUBZE,
				ppc64.ASUBZEV,
				ppc64.AXOR:
				t = variant2as(int(p1.As), as2variant(int(p1.As))|V_CC)
			}

			if gc.Debug['D'] != 0 {
				fmt.Printf("cmp %v; %v -> ", p1, p)
			}
			p1.As = int16(t)
			if gc.Debug['D'] != 0 {
				fmt.Printf("%v\n", p1)
			}
			excise(r)
			continue
		}
	}

ret:
	gc.Flowend(g)
}