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cmd/asm: add arm64 instructions for math optimization

Add arm64 HW instructions FMADDD, FMADDS, FMSUBD, FMSUBS, FNMADDD, FNMADDS,
FNMSUBD, FNMSUBS, VFMLA, VFMLS, VMOV (element) for math optimization.

Add check on register element index and test cases.

Change-Id: Ice07c50b1a02d488ad2cde2a4e8aea93f3e3afff
Reviewed-on: https://go-review.googlesource.com/90876
Reviewed-by: Cherry Zhang <cherryyz@google.com>
This commit is contained in:
erifan01 2018-01-26 10:18:50 +00:00 committed by Brad Fitzpatrick
parent c18ff18465
commit f5de42001d
7 changed files with 314 additions and 48 deletions

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@ -178,18 +178,39 @@ func ARM64RegisterExtension(a *obj.Addr, ext string, reg, num int16, isAmount, i
a.Reg = arm64.REG_SXTX + (reg & 31) + int16(num<<5)
a.Offset = int64(((rm & 31) << 16) | (7 << 13) | (uint32(num) << 10))
case "B8":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_8B & 15) << 5)
case "B16":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_16B & 15) << 5)
case "H4":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_4H & 15) << 5)
case "H8":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_8H & 15) << 5)
case "S2":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_2S & 15) << 5)
case "S4":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_4S & 15) << 5)
case "D2":
if isIndex {
return errors.New("invalid register extension")
}
a.Reg = arm64.REG_ARNG + (reg & 31) + ((arm64.ARNG_2D & 15) << 5)
case "B":
if !isIndex {

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@ -68,6 +68,12 @@ TEXT foo(SB), DUPOK|NOSPLIT, $-8
VADD V1, V3, V3 // 6384e15e
VSUB V12, V30, V30 // de87ec7e
VSUB V12, V20, V30 // 9e86ec7e
VFMLA V1.D2, V12.D2, V1.D2 // 81cd614e
VFMLA V1.S2, V12.S2, V1.S2 // 81cd210e
VFMLA V1.S4, V12.S4, V1.S4 // 81cd214e
VFMLS V1.D2, V12.D2, V1.D2 // 81cde14e
VFMLS V1.S2, V12.S2, V1.S2 // 81cda10e
VFMLS V1.S4, V12.S4, V1.S4 // 81cda14e
// LTYPE1 imsr ',' spreg ','
// {
@ -212,6 +218,10 @@ TEXT foo(SB), DUPOK|NOSPLIT, $-8
VMOV R22, V11.D2 // cb0e084e
VMOV V2.B16, V4.B16 // 441ca24e
VMOV V20.S[0], V20 // 9406045e
VMOV V12.D[0], V12.D[1] // 8c05186e
VMOV V10.S[0], V12.S[1] // 4c050c6e
VMOV V9.H[0], V12.H[1] // 2c05066e
VMOV V8.B[0], V12.B[1] // 0c05036e
VREV32 V5.B16, V5.B16 // a508206e
VDUP V19.S[0], V17.S4 // 7106044e
//
@ -367,6 +377,15 @@ again:
// }
// MADD R1, R2, R3, R4
FMADDS F1, F3, F2, F4 // 440c011f
FMADDD F4, F5, F4, F4 // 8414441f
FMSUBS F13, F21, F13, F19 // b3d50d1f
FMSUBD F11, F7, F15, F31 // ff9d4b1f
FNMADDS F1, F3, F2, F4 // 440c211f
FNMADDD F1, F3, F2, F4 // 440c611f
FNMSUBS F1, F3, F2, F4 // 448c211f
FNMSUBD F1, F3, F2, F4 // 448c611f
// DMB, HINT
//
// LDMB imm

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@ -12,4 +12,42 @@ TEXT errors(SB),$0
VLD1 8(R8)(R13), [V2.B16] // ERROR "illegal combination"
ADD R1.UXTB<<5, R2, R3 // ERROR "shift amount out of range 0 to 4"
ADDS R1.UXTX<<7, R2, R3 // ERROR "shift amount out of range 0 to 4"
VMOV V8.D[2], V12.D[1] // ERROR "register element index out of range 0 to 1"
VMOV V8.S[4], V12.S[1] // ERROR "register element index out of range 0 to 3"
VMOV V8.H[8], V12.H[1] // ERROR "register element index out of range 0 to 7"
VMOV V8.B[16], V12.B[1] // ERROR "register element index out of range 0 to 15"
VMOV V8.D[0], V12.S[1] // ERROR "operand mismatch"
VMOV V8.D[0], V12.H[1] // ERROR "operand mismatch"
VMOV V8.D[0], V12.B[1] // ERROR "operand mismatch"
VMOV V8.S[0], V12.H[1] // ERROR "operand mismatch"
VMOV V8.S[0], V12.B[1] // ERROR "operand mismatch"
VMOV V8.H[0], V12.B[1] // ERROR "operand mismatch"
VMOV V8.B[16], R3 // ERROR "register element index out of range 0 to 15"
VMOV V8.H[9], R3 // ERROR "register element index out of range 0 to 7"
VMOV V8.S[4], R3 // ERROR "register element index out of range 0 to 3"
VMOV V8.D[2], R3 // ERROR "register element index out of range 0 to 1"
VDUP V8.B[16], R3.B16 // ERROR "register element index out of range 0 to 15"
VDUP V8.B[17], R3.B8 // ERROR "register element index out of range 0 to 15"
VDUP V8.H[9], R3.H4 // ERROR "register element index out of range 0 to 7"
VDUP V8.H[9], R3.H8 // ERROR "register element index out of range 0 to 7"
VDUP V8.S[4], R3.S2 // ERROR "register element index out of range 0 to 3"
VDUP V8.S[4], R3.S4 // ERROR "register element index out of range 0 to 3"
VDUP V8.D[2], R3.D2 // ERROR "register element index out of range 0 to 1"
VFMLA V1.D2, V12.D2, V3.S2 // ERROR "operand mismatch"
VFMLA V1.S2, V12.S2, V3.D2 // ERROR "operand mismatch"
VFMLA V1.S4, V12.S2, V3.D2 // ERROR "operand mismatch"
VFMLA V1.H4, V12.H4, V3.D2 // ERROR "operand mismatch"
VFMLS V1.S2, V12.S2, V3.S4 // ERROR "operand mismatch"
VFMLS V1.S2, V12.D2, V3.S4 // ERROR "operand mismatch"
VFMLS V1.S2, V12.S4, V3.D2 // ERROR "operand mismatch"
VFMLA V1.B8, V12.B8, V3.B8 // ERROR "invalid arrangement"
VFMLA V1.B16, V12.B16, V3.B16 // ERROR "invalid arrangement"
VFMLA V1.H4, V12.H4, V3.H4 // ERROR "invalid arrangement"
VFMLA V1.H8, V12.H8, V3.H8 // ERROR "invalid arrangement"
VFMLA V1.H4, V12.H4, V3.H4 // ERROR "invalid arrangement"
VFMLS V1.B8, V12.B8, V3.B8 // ERROR "invalid arrangement"
VFMLS V1.B16, V12.B16, V3.B16 // ERROR "invalid arrangement"
VFMLS V1.H4, V12.H4, V3.H4 // ERROR "invalid arrangement"
VFMLS V1.H8, V12.H8, V3.H8 // ERROR "invalid arrangement"
VFMLS V1.H4, V12.H4, V3.H4 // ERROR "invalid arrangement"
RET

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@ -766,6 +766,8 @@ const (
AVMOVI
AVUADDLV
AVSUB
AVFMLA
AVFMLS
ALAST
AB = obj.AJMP
ABL = obj.ACALL

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@ -383,5 +383,7 @@ var Anames = []string{
"VMOVI",
"VUADDLV",
"VSUB",
"VFMLA",
"VFMLS",
"LAST",
}

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@ -146,6 +146,10 @@ func FPOP2S(m uint32, s uint32, type_ uint32, op uint32) uint32 {
return m<<31 | s<<29 | 0x1E<<24 | type_<<22 | 1<<21 | op<<12 | 2<<10
}
func FPOP3S(m uint32, s uint32, type_ uint32, op uint32, op2 uint32) uint32 {
return m<<31 | s<<29 | 0x1F<<24 | type_<<22 | op<<21 | op2<<15
}
func FPCVTI(sf uint32, s uint32, type_ uint32, rmode uint32, op uint32) uint32 {
return sf<<31 | s<<29 | 0x1E<<24 | type_<<22 | 1<<21 | rmode<<19 | op<<16 | 0<<10
}
@ -539,6 +543,7 @@ var optab = []Optab{
{AFADDS, C_FREG, C_FREG, C_FREG, 54, 4, 0, 0, 0},
{AFADDS, C_FCON, C_NONE, C_FREG, 54, 4, 0, 0, 0},
{AFADDS, C_FCON, C_FREG, C_FREG, 54, 4, 0, 0, 0},
{AFMSUBD, C_FREG, C_FREG, C_FREG, 15, 4, 0, 0, 0},
{AFMOVS, C_FCON, C_NONE, C_FREG, 54, 4, 0, 0, 0},
{AFMOVS, C_FREG, C_NONE, C_FREG, 54, 4, 0, 0, 0},
{AFMOVD, C_FCON, C_NONE, C_FREG, 54, 4, 0, 0, 0},
@ -589,6 +594,7 @@ var optab = []Optab{
{AVLD1, C_ROFF, C_NONE, C_LIST, 81, 4, 0, 0, C_XPOST},
{AVMOV, C_ELEM, C_NONE, C_REG, 73, 4, 0, 0, 0},
{AVMOV, C_REG, C_NONE, C_ARNG, 82, 4, 0, 0, 0},
{AVMOV, C_ELEM, C_NONE, C_ELEM, 92, 4, 0, 0, 0},
{AVMOV, C_ARNG, C_NONE, C_ARNG, 83, 4, 0, 0, 0},
{AVMOV, C_REG, C_NONE, C_ELEM, 78, 4, 0, 0, 0},
{AVMOV, C_ELEM, C_NONE, C_VREG, 80, 4, 0, 0, 0},
@ -600,6 +606,7 @@ var optab = []Optab{
{AVADDV, C_ARNG, C_NONE, C_VREG, 85, 4, 0, 0, 0},
{AVCNT, C_ARNG, C_NONE, C_ARNG, 29, 4, 0, 0, 0},
{AVMOVI, C_ADDCON, C_NONE, C_ARNG, 86, 4, 0, 0, 0},
{AVFMLA, C_ARNG, C_ARNG, C_ARNG, 72, 4, 0, 0, 0},
{obj.AUNDEF, C_NONE, C_NONE, C_NONE, 90, 4, 0, 0, 0},
{obj.APCDATA, C_VCON, C_NONE, C_VCON, 0, 0, 0, 0, 0},
@ -1987,6 +1994,15 @@ func buildop(ctxt *obj.Link) {
oprangeset(AFMINNMS, t)
oprangeset(AFDIVD, t)
case AFMSUBD:
oprangeset(AFMSUBS, t)
oprangeset(AFMADDS, t)
oprangeset(AFMADDD, t)
oprangeset(AFNMSUBS, t)
oprangeset(AFNMSUBD, t)
oprangeset(AFNMADDS, t)
oprangeset(AFNMADDD, t)
case AFCVTSD:
oprangeset(AFCVTDS, t)
oprangeset(AFABSD, t)
@ -2126,6 +2142,9 @@ func buildop(ctxt *obj.Link) {
case AVADDV:
oprangeset(AVUADDLV, t)
case AVFMLA:
oprangeset(AVFMLS, t)
case ASHA1H,
AVCNT,
AVMOV,
@ -2189,6 +2208,13 @@ func SYSARG4(op1 int, Cn int, Cm int, op2 int) int {
return SYSARG5(0, op1, Cn, Cm, op2)
}
/* checkindex checks if index >= 0 && index <= maxindex */
func (c *ctxt7) checkindex(p *obj.Prog, index, maxindex int) {
if index < 0 || index > maxindex {
c.ctxt.Diag("register element index out of range 0 to %d: %v", maxindex, p)
}
}
func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
o1 := uint32(0)
o2 := uint32(0)
@ -2420,7 +2446,7 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
o1 = 0
}
case 15: /* mul/mneg/umulh/umull r,[r,]r; madd/msub Rm,Ra,Rn,Rd */
case 15: /* mul/mneg/umulh/umull r,[r,]r; madd/msub/fmadd/fmsub/fnmadd/fnmsub Rm,Ra,Rn,Rd */
o1 = c.oprrr(p, p.As)
rf := int(p.From.Reg)
@ -3283,12 +3309,13 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
rel.Add = 0
rel.Type = objabi.R_ARM64_GOTPCREL
case 72: /* vaddp/vand/vcmeq/vorr/vadd/veor Vm.<T>, Vn.<T>, Vd.<T> */
case 72: /* vaddp/vand/vcmeq/vorr/vadd/veor/vfmla/vfmls Vm.<T>, Vn.<T>, Vd.<T> */
af := int((p.From.Reg >> 5) & 15)
af3 := int((p.Reg >> 5) & 15)
at := int((p.To.Reg >> 5) & 15)
if af != af3 || af != at {
c.ctxt.Diag("invalid arrangement: %v\n", p)
c.ctxt.Diag("operand mismatch: %v", p)
break
}
o1 = c.oprrr(p, p.As)
rf := int((p.From.Reg) & 31)
@ -3320,16 +3347,25 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
Q = 1
size = 1
default:
c.ctxt.Diag("invalid arrangement: %v\n", p)
c.ctxt.Diag("invalid arrangement: %v", p)
}
if (p.As == AVORR || p.As == AVAND || p.As == AVEOR) &&
(af != ARNG_16B && af != ARNG_8B) {
c.ctxt.Diag("invalid arrangement on op %v", p.As)
c.ctxt.Diag("invalid arrangement: %v", p)
} else if (p.As == AVFMLA || p.As == AVFMLS) &&
(af != ARNG_2D && af != ARNG_2S && af != ARNG_4S) {
c.ctxt.Diag("invalid arrangement: %v", p)
} else if p.As == AVORR {
size = 2
} else if p.As == AVAND || p.As == AVEOR {
size = 0
} else if (p.As == AVFMLA || p.As == AVFMLS) {
if af == ARNG_2D {
size = 1
} else {
size = 0
}
}
o1 |= (uint32(Q&1) << 30) | (uint32(size&3) << 22) | (uint32(rf&31) << 16) | (uint32(r&31) << 5) | uint32(rt&31)
@ -3339,22 +3375,27 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
rt := int(p.To.Reg)
imm5 := 0
o1 = 7<<25 | 0xf<<10
index := int(p.From.Index)
switch (p.From.Reg >> 5) & 15 {
case ARNG_B:
c.checkindex(p, index, 15)
imm5 |= 1
imm5 |= int(p.From.Index) << 1
imm5 |= index << 1
case ARNG_H:
c.checkindex(p, index, 7)
imm5 |= 2
imm5 |= int(p.From.Index) << 2
imm5 |= index << 2
case ARNG_S:
c.checkindex(p, index, 3)
imm5 |= 4
imm5 |= int(p.From.Index) << 3
imm5 |= index << 3
case ARNG_D:
c.checkindex(p, index, 1)
imm5 |= 8
imm5 |= int(p.From.Index) << 4
imm5 |= index << 4
o1 |= 1 << 30
default:
c.ctxt.Diag("invalid arrangement on op V.<T>[index], R: %v\n", p)
c.ctxt.Diag("invalid arrangement: %v", p)
}
o1 |= (uint32(imm5&0x1f) << 16) | (uint32(rf&31) << 5) | uint32(rt&31)
@ -3471,21 +3512,26 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
rt := int(p.To.Reg)
imm5 := 0
o1 = 1<<30 | 7<<25 | 7<<10
index :=int(p.From.Index)
switch (p.To.Reg >> 5) & 15 {
case ARNG_B:
c.checkindex(p, index, 15)
imm5 |= 1
imm5 |= int(p.From.Index) << 1
imm5 |= index << 1
case ARNG_H:
c.checkindex(p, index, 7)
imm5 |= 2
imm5 |= int(p.From.Index) << 2
imm5 |= index << 2
case ARNG_S:
c.checkindex(p, index, 3)
imm5 |= 4
imm5 |= int(p.From.Index) << 3
imm5 |= index << 3
case ARNG_D:
c.checkindex(p, index, 1)
imm5 |= 8
imm5 |= int(p.From.Index) << 4
imm5 |= index << 4
default:
c.ctxt.Diag("invalid arrangement on op R, V.<T>[index]: %v\n", p)
c.ctxt.Diag("invalid arrangement: %v", p)
}
o1 |= (uint32(imm5&0x1f) << 16) | (uint32(rf&31) << 5) | uint32(rt&31)
@ -3493,38 +3539,46 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
rf := int(p.From.Reg)
rt := int(p.To.Reg)
o1 = 7<<25 | 1<<10
var imm5, Q uint32
var imm5, Q int
index := int(p.From.Index)
switch (p.To.Reg >> 5) & 15 {
case ARNG_16B:
c.checkindex(p, index, 15)
Q = 1
imm5 = 1
imm5 |= uint32(p.From.Index) << 1
imm5 |= index << 1
case ARNG_2D:
c.checkindex(p, index, 1)
Q = 1
imm5 = 8
imm5 |= uint32(p.From.Index) << 4
imm5 |= index << 4
case ARNG_2S:
c.checkindex(p, index, 3)
Q = 0
imm5 = 4
imm5 |= uint32(p.From.Index) << 3
imm5 |= index << 3
case ARNG_4H:
c.checkindex(p, index, 7)
Q = 0
imm5 = 2
imm5 |= uint32(p.From.Index) << 2
imm5 |= index << 2
case ARNG_4S:
c.checkindex(p, index, 3)
Q = 1
imm5 = 4
imm5 |= uint32(p.From.Index) << 3
imm5 |= index << 3
case ARNG_8B:
c.checkindex(p, index, 15)
Q = 0
imm5 = 1
imm5 |= uint32(p.From.Index) << 1
imm5 |= index << 1
case ARNG_8H:
c.checkindex(p, index, 7)
Q = 1
imm5 = 2
imm5 |= uint32(p.From.Index) << 2
imm5 |= index << 2
default:
c.ctxt.Diag("invalid arrangement on VDUP Vn.<T>[index], Vd.<T>: %v\n", p)
c.ctxt.Diag("invalid arrangement: %v", p)
}
o1 |= (uint32(Q&1) << 30) | (uint32(imm5&0x1f) << 16)
o1 |= (uint32(rf&31) << 5) | uint32(rt&31)
@ -3533,24 +3587,29 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
rf := int(p.From.Reg)
rt := int(p.To.Reg)
imm5 := 0
index := int(p.From.Index)
switch p.As {
case AVMOV:
o1 = 1<<30 | 15<<25 | 1<<10
switch (p.From.Reg >> 5) & 15 {
case ARNG_B:
c.checkindex(p, index, 15)
imm5 |= 1
imm5 |= int(p.From.Index) << 1
imm5 |= index << 1
case ARNG_H:
c.checkindex(p, index, 7)
imm5 |= 2
imm5 |= int(p.From.Index) << 2
imm5 |= index << 2
case ARNG_S:
c.checkindex(p, index, 3)
imm5 |= 4
imm5 |= int(p.From.Index) << 3
imm5 |= index << 3
case ARNG_D:
c.checkindex(p, index, 1)
imm5 |= 8
imm5 |= int(p.From.Index) << 4
imm5 |= index << 4
default:
c.ctxt.Diag("invalid arrangement on op V.<T>[index], Vn: %v\n", p)
c.ctxt.Diag("invalid arrangement: %v", p)
}
default:
c.ctxt.Diag("unsupported op %v", p.As)
@ -3759,6 +3818,47 @@ func (c *ctxt7) asmout(p *obj.Prog, o *Optab, out []uint32) {
case 90:
o1 = 0xbea71700
case 92: /* vmov Vn.<T>[index], Vd.<T>[index] */
rf := int(p.From.Reg)
rt := int(p.To.Reg)
imm4 := 0
imm5 := 0
o1 = 3<<29 | 7<<25 | 1<<10
index1 := int(p.To.Index)
index2 := int(p.From.Index)
if ((p.To.Reg >> 5) & 15) != ((p.From.Reg >> 5) & 15) {
c.ctxt.Diag("operand mismatch: %v", p)
}
switch (p.To.Reg >> 5) & 15 {
case ARNG_B:
c.checkindex(p, index1, 15)
c.checkindex(p, index2, 15)
imm5 |= 1
imm5 |= index1 << 1
imm4 |= index2
case ARNG_H:
c.checkindex(p, index1, 7)
c.checkindex(p, index2, 7)
imm5 |= 2
imm5 |= index1 << 2
imm4 |= index2 << 1
case ARNG_S:
c.checkindex(p, index1, 3)
c.checkindex(p, index2, 3)
imm5 |= 4
imm5 |= index1 << 3
imm4 |= index2 << 2
case ARNG_D:
c.checkindex(p, index1, 1)
c.checkindex(p, index2, 1)
imm5 |= 8
imm5 |= index1 << 4
imm4 |= index2 << 3
default:
c.ctxt.Diag("invalid arrangement: %v", p)
}
o1 |= (uint32(imm5&0x1f) << 16) | (uint32(imm4&0xf) << 16) | (uint32(rf&31) << 5) | uint32(rt&31)
break
case 91: /* prfm imm(Rn), <prfop | $imm5> */
@ -4157,6 +4257,30 @@ func (c *ctxt7) oprrr(p *obj.Prog, a obj.As) uint32 {
case AFSUBD:
return FPOP2S(0, 0, 1, 3)
case AFMADDD:
return FPOP3S(0, 0, 1, 0, 0)
case AFMADDS:
return FPOP3S(0, 0, 0, 0, 0)
case AFMSUBD:
return FPOP3S(0, 0, 1, 0, 1)
case AFMSUBS:
return FPOP3S(0, 0, 0, 0, 1)
case AFNMADDD:
return FPOP3S(0, 0, 1, 1, 0)
case AFNMADDS:
return FPOP3S(0, 0, 0, 1, 0)
case AFNMSUBD:
return FPOP3S(0, 0, 1, 1, 1)
case AFNMSUBS:
return FPOP3S(0, 0, 0, 1, 1)
case AFMULS:
return FPOP2S(0, 0, 0, 0)
@ -4345,6 +4469,12 @@ func (c *ctxt7) oprrr(p *obj.Prog, a obj.As) uint32 {
case AVUADDLV:
return 1<<29 | 7<<25 | 3<<20 | 7<<11
case AVFMLA:
return 7<<25 | 0<<23 | 1<<21 | 3<<14 | 3<<10
case AVFMLS:
return 7<<25 | 1<<23 | 1<<21 | 3<<14 | 3<<10
}
c.ctxt.Diag("%v: bad rrr %d %v", p, a, a)

View File

@ -22,6 +22,46 @@ Go Assembly for ARM64 Reference Manual
2. Alphabetical list of float-point instructions
// TODO
FMADDD: 64-bit floating-point fused Multiply-Add
FMADDD <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>,
adds the product to <Fa>, and writes the result to <Fd>.
FMADDS: 32-bit floating-point fused Multiply-Add
FMADDS <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>,
adds the product to <Fa>, and writes the result to <Fd>.
FMSUBD: 64-bit floating-point fused Multiply-Subtract
FMSUBD <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>, negates the product,
adds the product to <Fa>, and writes the result to <Fd>.
FMSUBS: 32-bit floating-point fused Multiply-Subtract
FMSUBS <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>, negates the product,
adds the product to <Fa>, and writes the result to <Fd>.
FNMADDD: 64-bit floating-point negated fused Multiply-Add
FNMADDD <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>, negates the product,
subtracts the value of <Fa>, and writes the result to <Fd>.
FNMADDS: 32-bit floating-point negated fused Multiply-Add
FNMADDS <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>, negates the product,
subtracts the value of <Fa>, and writes the result to <Fd>.
FNMSUBD: 64-bit floating-point negated fused Multiply-Subtract
FNMSUBD <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>,
subtracts the value of <Fa>, and writes the result to <Fd>.
FNMSUBS: 32-bit floating-point negated fused Multiply-Subtract
FNMSUBS <Fm>, <Fa>, <Fn>, <Fd>
Multiplies the values of <Fm> and <Fn>,
subtracts the value of <Fa>, and writes the result to <Fd>.
3. Alphabetical list of SIMD instructions
VADD: Add (scalar)
VADD <Vm>, <Vn>, <Vd>
@ -65,6 +105,16 @@ Go Assembly for ARM64 Reference Manual
<T> Is an arrangement specifier and can have the following values:
B8, B16
VFMLA: Floating-point fused Multiply-Add to accumulator (vector)
VFMLA <Vm>.<T>, <Vn>.<T>, <Vd>.<T>
<T> Is an arrangement specifier and can have the following values:
S2, S4, D2
VFMLS: Floating-point fused Multiply-Subtract from accumulator (vector)
VFMLS <Vm>.<T>, <Vn>.<T>, <Vd>.<T>
<T> Is an arrangement specifier and can have the following values:
S2, S4, D2
VLD1: Load multiple single-element structures
VLD1 (Rn), [<Vt>.<T>, <Vt2>.<T> ...] // no offset
VLD1.P imm(Rn), [<Vt>.<T>, <Vt2>.<T> ...] // immediate offset variant
@ -96,6 +146,10 @@ Go Assembly for ARM64 Reference Manual
<T> Is an element size specifier and can have the following values:
B, H, S, D
VMOV <Vn>.<T>[index], <Vd>.<T>[index] // Move vector element to another vector element.
<T> Is an element size specifier and can have the following values:
B, H, S, D
VMOVI: Move Immediate (vector).
VMOVI $imm8, <Vd>.<T>
<T> is an arrangement specifier and can have the following values: