func dotaddable(n *gc.Node, n1 *gc.Node) bool { if n.Op != gc.ODOT { return false } var oary [10]int64 var nn *gc.Node o := gc.Dotoffset(n, oary[:], &nn) if nn != nil && nn.Addable && o == 1 && oary[0] >= 0 { *n1 = *nn n1.Type = n.Type n1.Xoffset += oary[0] return true } return false }
/* * generate code to compute address of n, * a reference to a (perhaps nested) field inside * an array or struct. * return 0 on failure, 1 on success. * on success, leaves usable address in a. * * caller is responsible for calling sudoclean * after successful sudoaddable, * to release the register used for a. */ func sudoaddable(as obj.As, n *gc.Node, a *obj.Addr) bool { if n.Type == nil { return false } *a = obj.Addr{} switch n.Op { case gc.OLITERAL: if !gc.Isconst(n, gc.CTINT) { break } v := n.Int64() if v >= 32000 || v <= -32000 { break } switch as { default: return false case arm.AADD, arm.ASUB, arm.AAND, arm.AORR, arm.AEOR, arm.AMOVB, arm.AMOVBS, arm.AMOVBU, arm.AMOVH, arm.AMOVHS, arm.AMOVHU, arm.AMOVW: break } cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY gc.Naddr(a, n) return true case gc.ODOT, gc.ODOTPTR: cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY var nn *gc.Node var oary [10]int64 o := gc.Dotoffset(n, oary[:], &nn) if nn == nil { sudoclean() return false } if nn.Addable && o == 1 && oary[0] >= 0 { // directly addressable set of DOTs n1 := *nn n1.Type = n.Type n1.Xoffset += oary[0] gc.Naddr(a, &n1) return true } gc.Regalloc(reg, gc.Types[gc.Tptr], nil) n1 := *reg n1.Op = gc.OINDREG if oary[0] >= 0 { gc.Agen(nn, reg) n1.Xoffset = oary[0] } else { gc.Cgen(nn, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[0] + 1) } for i := 1; i < o; i++ { if oary[i] >= 0 { gc.Fatalf("can't happen") } gins(arm.AMOVW, &n1, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[i] + 1) } a.Type = obj.TYPE_NONE a.Name = obj.NAME_NONE n1.Type = n.Type gc.Naddr(a, &n1) return true case gc.OINDEX: return false } return false }
/* * generate code to compute address of n, * a reference to a (perhaps nested) field inside * an array or struct. * return 0 on failure, 1 on success. * on success, leaves usable address in a. * * caller is responsible for calling sudoclean * after successful sudoaddable, * to release the register used for a. */ func sudoaddable(as obj.As, n *gc.Node, a *obj.Addr) bool { if n.Type == nil { return false } *a = obj.Addr{} switch n.Op { case gc.OLITERAL: if !gc.Isconst(n, gc.CTINT) { break } v := n.Int64() if v >= 32000 || v <= -32000 { break } switch as { default: return false case x86.AADDB, x86.AADDW, x86.AADDL, x86.AADDQ, x86.ASUBB, x86.ASUBW, x86.ASUBL, x86.ASUBQ, x86.AANDB, x86.AANDW, x86.AANDL, x86.AANDQ, x86.AORB, x86.AORW, x86.AORL, x86.AORQ, x86.AXORB, x86.AXORW, x86.AXORL, x86.AXORQ, x86.AINCB, x86.AINCW, x86.AINCL, x86.AINCQ, x86.ADECB, x86.ADECW, x86.ADECL, x86.ADECQ, x86.AMOVB, x86.AMOVW, x86.AMOVL, x86.AMOVQ: break } cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY gc.Naddr(a, n) return true case gc.ODOT, gc.ODOTPTR: cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY var nn *gc.Node var oary [10]int64 o := gc.Dotoffset(n, oary[:], &nn) if nn == nil { sudoclean() return false } if nn.Addable && o == 1 && oary[0] >= 0 { // directly addressable set of DOTs n1 := *nn n1.Type = n.Type n1.Xoffset += oary[0] gc.Naddr(a, &n1) return true } gc.Regalloc(reg, gc.Types[gc.Tptr], nil) n1 := *reg n1.Op = gc.OINDREG if oary[0] >= 0 { gc.Agen(nn, reg) n1.Xoffset = oary[0] } else { gc.Cgen(nn, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[0] + 1) } for i := 1; i < o; i++ { if oary[i] >= 0 { gc.Fatalf("can't happen") } gins(movptr, &n1, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[i] + 1) } a.Type = obj.TYPE_NONE a.Index = x86.REG_NONE gc.Fixlargeoffset(&n1) gc.Naddr(a, &n1) return true case gc.OINDEX: return false } return false }
/* * generate code to compute address of n, * a reference to a (perhaps nested) field inside * an array or struct. * return 0 on failure, 1 on success. * on success, leaves usable address in a. * * caller is responsible for calling sudoclean * after successful sudoaddable, * to release the register used for a. */ func sudoaddable(as obj.As, n *gc.Node, a *obj.Addr) bool { if n.Type == nil { return false } *a = obj.Addr{} switch n.Op { case gc.OLITERAL: if !gc.Isconst(n, gc.CTINT) { return false } v := n.Int64() switch as { default: return false // operations that can cope with a 32-bit immediate // TODO(mundaym): logical operations can work on high bits case s390x.AADD, s390x.AADDC, s390x.ASUB, s390x.AMULLW, s390x.AAND, s390x.AOR, s390x.AXOR, s390x.ASLD, s390x.ASLW, s390x.ASRAW, s390x.ASRAD, s390x.ASRW, s390x.ASRD, s390x.AMOVB, s390x.AMOVBZ, s390x.AMOVH, s390x.AMOVHZ, s390x.AMOVW, s390x.AMOVWZ, s390x.AMOVD: if int64(int32(v)) != v { return false } // for comparisons avoid immediates unless they can // fit into a int8/uint8 // this favours combined compare and branch instructions case s390x.ACMP: if int64(int8(v)) != v { return false } case s390x.ACMPU: if int64(uint8(v)) != v { return false } } cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY gc.Naddr(a, n) return true case gc.ODOT, gc.ODOTPTR: cleani += 2 reg := &clean[cleani-1] reg1 := &clean[cleani-2] reg.Op = gc.OEMPTY reg1.Op = gc.OEMPTY var nn *gc.Node var oary [10]int64 o := gc.Dotoffset(n, oary[:], &nn) if nn == nil { sudoclean() return false } if nn.Addable && o == 1 && oary[0] >= 0 { // directly addressable set of DOTs n1 := *nn n1.Type = n.Type n1.Xoffset += oary[0] // check that the offset fits into a 12-bit displacement if n1.Xoffset < 0 || n1.Xoffset >= (1<<12)-8 { sudoclean() return false } gc.Naddr(a, &n1) return true } gc.Regalloc(reg, gc.Types[gc.Tptr], nil) n1 := *reg n1.Op = gc.OINDREG if oary[0] >= 0 { gc.Agen(nn, reg) n1.Xoffset = oary[0] } else { gc.Cgen(nn, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[0] + 1) } for i := 1; i < o; i++ { if oary[i] >= 0 { gc.Fatalf("can't happen") } gins(s390x.AMOVD, &n1, reg) gc.Cgen_checknil(reg) n1.Xoffset = -(oary[i] + 1) } a.Type = obj.TYPE_NONE a.Index = 0 // check that the offset fits into a 12-bit displacement if n1.Xoffset < 0 || n1.Xoffset >= (1<<12)-8 { tmp := n1 tmp.Op = gc.OREGISTER tmp.Type = gc.Types[gc.Tptr] tmp.Xoffset = 0 gc.Cgen_checknil(&tmp) ginscon(s390x.AADD, n1.Xoffset, &tmp) n1.Xoffset = 0 } gc.Naddr(a, &n1) return true } return false }