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Text file src/math/log_amd64.s

Documentation: math

     1// Copyright 2010 The Go Authors. All rights reserved.
     2// Use of this source code is governed by a BSD-style
     3// license that can be found in the LICENSE file.
     4
     5#include "textflag.h"
     6
     7#define HSqrt2 7.07106781186547524401e-01 // sqrt(2)/2
     8#define Ln2Hi  6.93147180369123816490e-01 // 0x3fe62e42fee00000
     9#define Ln2Lo  1.90821492927058770002e-10 // 0x3dea39ef35793c76
    10#define L1     6.666666666666735130e-01   // 0x3FE5555555555593
    11#define L2     3.999999999940941908e-01   // 0x3FD999999997FA04
    12#define L3     2.857142874366239149e-01   // 0x3FD2492494229359
    13#define L4     2.222219843214978396e-01   // 0x3FCC71C51D8E78AF
    14#define L5     1.818357216161805012e-01   // 0x3FC7466496CB03DE
    15#define L6     1.531383769920937332e-01   // 0x3FC39A09D078C69F
    16#define L7     1.479819860511658591e-01   // 0x3FC2F112DF3E5244
    17#define NaN    0x7FF8000000000001
    18#define NegInf 0xFFF0000000000000
    19#define PosInf 0x7FF0000000000000
    20
    21// func Log(x float64) float64
    22TEXT ·archLog(SB),NOSPLIT,$0
    23	// test bits for special cases
    24	MOVQ    x+0(FP), BX
    25	MOVQ    $~(1<<63), AX // sign bit mask
    26	ANDQ    BX, AX
    27	JEQ     isZero
    28	MOVQ    $0, AX
    29	CMPQ    AX, BX
    30	JGT     isNegative
    31	MOVQ    $PosInf, AX
    32	CMPQ    AX, BX
    33	JLE     isInfOrNaN
    34	// f1, ki := math.Frexp(x); k := float64(ki)
    35	MOVQ    BX, X0
    36	MOVQ    $0x000FFFFFFFFFFFFF, AX
    37	MOVQ    AX, X2
    38	ANDPD   X0, X2
    39	MOVSD   $0.5, X0 // 0x3FE0000000000000
    40	ORPD    X0, X2 // X2= f1
    41	SHRQ    $52, BX
    42	ANDL    $0x7FF, BX
    43	SUBL    $0x3FE, BX
    44	XORPS   X1, X1 // break dependency for CVTSL2SD
    45	CVTSL2SD BX, X1 // x1= k, x2= f1
    46	// if f1 < math.Sqrt2/2 { k -= 1; f1 *= 2 }
    47	MOVSD   $HSqrt2, X0 // x0= 0.7071, x1= k, x2= f1
    48	CMPSD   X2, X0, 5 // cmpnlt; x0= 0 or ^0, x1= k, x2 = f1
    49	MOVSD   $1.0, X3 // x0= 0 or ^0, x1= k, x2 = f1, x3= 1
    50	ANDPD   X0, X3 // x0= 0 or ^0, x1= k, x2 = f1, x3= 0 or 1
    51	SUBSD   X3, X1 // x0= 0 or ^0, x1= k, x2 = f1, x3= 0 or 1
    52	MOVSD   $1.0, X0 // x0= 1, x1= k, x2= f1, x3= 0 or 1
    53	ADDSD   X0, X3 // x0= 1, x1= k, x2= f1, x3= 1 or 2
    54	MULSD   X3, X2 // x0= 1, x1= k, x2= f1
    55	// f := f1 - 1
    56	SUBSD   X0, X2 // x1= k, x2= f
    57	// s := f / (2 + f)
    58	MOVSD   $2.0, X0
    59	ADDSD   X2, X0
    60	MOVAPD  X2, X3
    61	DIVSD   X0, X3 // x1=k, x2= f, x3= s
    62	// s2 := s * s
    63	MOVAPD  X3, X4 // x1= k, x2= f, x3= s
    64	MULSD   X4, X4 // x1= k, x2= f, x3= s, x4= s2
    65	// s4 := s2 * s2
    66	MOVAPD  X4, X5 // x1= k, x2= f, x3= s, x4= s2
    67	MULSD   X5, X5 // x1= k, x2= f, x3= s, x4= s2, x5= s4
    68	// t1 := s2 * (L1 + s4*(L3+s4*(L5+s4*L7)))
    69	MOVSD   $L7, X6
    70	MULSD   X5, X6
    71	ADDSD   $L5, X6
    72	MULSD   X5, X6
    73	ADDSD   $L3, X6
    74	MULSD   X5, X6
    75	ADDSD   $L1, X6
    76	MULSD   X6, X4 // x1= k, x2= f, x3= s, x4= t1, x5= s4
    77	// t2 := s4 * (L2 + s4*(L4+s4*L6))
    78	MOVSD   $L6, X6
    79	MULSD   X5, X6
    80	ADDSD   $L4, X6
    81	MULSD   X5, X6
    82	ADDSD   $L2, X6
    83	MULSD   X6, X5 // x1= k, x2= f, x3= s, x4= t1, x5= t2
    84	// R := t1 + t2
    85	ADDSD   X5, X4 // x1= k, x2= f, x3= s, x4= R
    86	// hfsq := 0.5 * f * f
    87	MOVSD   $0.5, X0
    88	MULSD   X2, X0
    89	MULSD   X2, X0 // x0= hfsq, x1= k, x2= f, x3= s, x4= R
    90	// return k*Ln2Hi - ((hfsq - (s*(hfsq+R) + k*Ln2Lo)) - f)
    91	ADDSD   X0, X4 // x0= hfsq, x1= k, x2= f, x3= s, x4= hfsq+R
    92	MULSD   X4, X3 // x0= hfsq, x1= k, x2= f, x3= s*(hfsq+R)
    93	MOVSD   $Ln2Lo, X4
    94	MULSD   X1, X4 // x4= k*Ln2Lo
    95	ADDSD   X4, X3 // x0= hfsq, x1= k, x2= f, x3= s*(hfsq+R)+k*Ln2Lo
    96	SUBSD   X3, X0 // x0= hfsq-(s*(hfsq+R)+k*Ln2Lo), x1= k, x2= f
    97	SUBSD   X2, X0 // x0= (hfsq-(s*(hfsq+R)+k*Ln2Lo))-f, x1= k
    98	MULSD   $Ln2Hi, X1 // x0= (hfsq-(s*(hfsq+R)+k*Ln2Lo))-f, x1= k*Ln2Hi
    99	SUBSD   X0, X1 // x1= k*Ln2Hi-((hfsq-(s*(hfsq+R)+k*Ln2Lo))-f)
   100	MOVSD   X1, ret+8(FP)
   101	RET
   102isInfOrNaN:
   103	MOVQ    BX, ret+8(FP) // +Inf or NaN, return x
   104	RET
   105isNegative:
   106	MOVQ    $NaN, AX
   107	MOVQ    AX, ret+8(FP) // return NaN
   108	RET
   109isZero:
   110	MOVQ    $NegInf, AX
   111	MOVQ    AX, ret+8(FP) // return -Inf
   112	RET

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