我需要在不使用类型的情况下重写日志函数(base 2或base10无关紧要)float,但是我需要获得小数点后几位十进制数字的精度。(像是在整数类型中float * 100获取2小数,例如:如果1.4352将是结果,则我的函数应返回类似143(inttype)的值,并且我知道最后两个数字是小数。
2
10
float
float * 100
1.4352
143
int
但它们全部返回int精度(避免使用小数点)。
我不知道如何解决这个问题,所以问题是:
如何编码(和/或更改)整数log实现以支持十进制结果?
log
为此,您需要使用 定点 精度/算术/数学。这意味着您使用整数类型变量,但某些位在小数点后。
例如,假设8个十进制位,则操作如下所示:
a = number1*256 b = number2*256 c=a+b // + c=a-b // - c=(a*b)>>8 // * c=(a/b)<<8 // /
这是log2在 C ++中 通过二进制搜索的简单定点示例:
log2
//--------------------------------------------------------------------------- const DWORD _fx32_bits =32; // all bits count const DWORD _fx32_fract_bits= 8; // fractional bits count const DWORD _fx32_integ_bits=_fx32_bits-_fx32_fract_bits; // integer bits count //--------------------------------------------------------------------------- const DWORD _fx32_one =1<<_fx32_fract_bits; // constant=1.0 (fixed point) const DWORD _fx32_fract_mask=_fx32_one-1; // fractional bits mask const DWORD _fx32_integ_mask=0xFFFFFFFF-_fx32_fract_mask; // integer bits mask const DWORD _fx32_MSB_mask=1<<(_fx32_bits-1); // max unsigned bit mask //--------------------------------------------------------------------------- DWORD bits(DWORD p) // count how many bits is p { DWORD m=0x80000000; DWORD b=32; for (;m;m>>=1,b--) if (p>=m) break; return b; } //--------------------------------------------------------------------------- DWORD fx32_mul(DWORD x,DWORD y) { // this should be done in asm with 64 bit result !!! DWORD a=x,b=y; // asm has access only to local variables asm { // compute (a*b)>>_fx32_fract mov eax,a // eax=a mov ebx,b // ebx=b mul eax,ebx // (edx,eax)=eax*ebx mov ebx,_fx32_one div ebx // eax=(edx,eax)>>_fx32_fract mov a,eax; } return a; // you can also do this instead but unless done on 64bit variable will overflow return (x*y)>>_fx32_fract_bits; } //--------------------------------------------------------------------------- DWORD fx32_sqrt(const DWORD &x) // unsigned fixed point sqrt { DWORD m,a; if (!x) return 0; m=bits(x); // integer bits if (m>_fx32_fract_bits) m-=_fx32_fract_bits; else m=0; m>>=1; // sqrt integer result is half of x integer bits m=_fx32_one<<m; // MSB of result mask for (a=0;m;m>>=1) // test bits from MSB to 0 { a|=m; // bit set if (fx32_mul(a,a)>x) // if result is too big a^=m; // bit clear } return a; } //--------------------------------------------------------------------------- DWORD fx32_exp2(DWORD y) // 2^y { // handle special cases if (!y) return _fx32_one; // 2^0 = 1 if (y==_fx32_one) return 2; // 2^1 = 2 DWORD m,a,b,_y; // handle the signs _y=y&_fx32_fract_mask; // _y fractional part of exponent y=y&_fx32_integ_mask; // y integer part of exponent a=_fx32_one; // ini result // powering by squaring x^y if (y) { for (m=_fx32_MSB_mask;(m>_fx32_one)&&(m>y);m>>=1); // find mask of highest bit of exponent for (;m>=_fx32_one;m>>=1) { a=fx32_mul(a,a); if (DWORD(y&m)) a<<=1; // a*=2 } } // powering by rooting x^_y if (_y) { for (b=2<<_fx32_fract_bits,m=_fx32_one>>1;m;m>>=1) // use only fractional part { b=fx32_sqrt(b); if (DWORD(_y&m)) a=fx32_mul(a,b); } } return a; } //--------------------------------------------------------------------------- DWORD fx32_log2(DWORD x) // = log2(x) { DWORD y,m; // binary search from highest possible integer power of 2 to avoid overflows (log2(integer bits)-1) for (y=0,m=_fx32_one<<(bits(_fx32_integ_bits)-1);m;m>>=1) { y|=m; // set bit if (fx32_exp2(y)>x) y^=m; // clear bit if result too big } return y; } //---------------------------------------------------------------------------
这里是简单的测试(使用浮点数仅用于加载和打印,您也可以处理整数值的展位,也可以使用编译器评估的常量):
float(fx32_log2(float(125.67*float(_fx32_one)))) / float(_fx32_one)
评估结果:log2(125.67) = 6.98828125我的获胜计算返回6.97349648值非常接近。更精确的结果是您需要使用更多的小数位。Int和编译时间评估浮点示例:
log2(125.67) = 6.98828125
6.97349648
(100*fx32_log2(125.67*_fx32_one))>>_fx32_fract_bits
返回698,这意味着6.98我们乘以100。您还可以编写自己的加载和打印功能,以直接在 定点 和 字符串 之间转换。
698
6.98
100
要更改精度,只需玩_fx32_fract_bits常量即可。无论如何,如果您的 C ++ 不知道DWORD它仅仅是32bit unsigned int。如果您使用其他类型(如like 16或64bit),则只需相应地更改常量。
_fx32_fract_bits
DWORD
unsigned int
16
64
有关更多信息,请查看:
[Edit2]fx32_mul不带asm底数的32位算术2^16 O(n^2)
fx32_mul
asm
2^16 O(n^2)
DWORD fx32_mul(DWORD x,DWORD y) { const int _h=1; // this is MSW,LSW order platform dependent So swap 0,1 if your platform is different const int _l=0; union _u { DWORD u32; WORD u16[2]; }u; DWORD al,ah,bl,bh; DWORD c0,c1,c2,c3; // separate 2^16 base digits u.u32=x; al=u.u16[_l]; ah=u.u16[_h]; u.u32=y; bl=u.u16[_l]; bh=u.u16[_h]; // multiplication (al+ah<<1)*(bl+bh<<1) = al*bl + al*bh<<1 + ah*bl<<1 + ah*bh<<2 c0=(al*bl); c1=(al*bh)+(ah*bl); c2=(ah*bh); c3= 0; // propagate 2^16 overflows (backward to avoid overflow) c3+=c2>>16; c2&=0x0000FFFF; c2+=c1>>16; c1&=0x0000FFFF; c1+=c0>>16; c0&=0x0000FFFF; // propagate 2^16 overflows (normaly to recover from secondary overflow) c2+=c1>>16; c1&=0x0000FFFF; c3+=c2>>16; c2&=0x0000FFFF; // (c3,c2,c1,c0) >> _fx32_fract_bits u.u16[_l]=c0; u.u16[_h]=c1; c0=u.u32; u.u16[_l]=c2; u.u16[_h]=c3; c1=u.u32; c0 =(c0&_fx32_integ_mask)>>_fx32_fract_bits; c0|=(c1&_fx32_fract_mask)<<_fx32_integ_bits; return c0; }
如果您没有WORD,DWORD将此添加到代码开头
WORD,DWORD
typedef unsigned __int32 DWORD; typedef unsigned __int16 WORD;
或这个:
typedef uint32_t DWORD; typedef uint16_t WORD;
[Edit3] fx32_mul调试信息
让我们调用并跟踪/断点(15个小数位):
fx32_mul(0x00123400,0x00230056);
这是:
0x00123400/32768 * 0x00230056/32768 = 36 * 70.00262451171875 = 2520.094482421875
所以:
DWORD fx32_mul(DWORD x,DWORD y) // x=0x00123400 y=0x00230056 { const int _h=1; const int _l=0; union _u { DWORD u32; WORD u16[2]; }u; DWORD al,ah,bl,bh; DWORD c0,c1,c2,c3; // separate 2^16 base digits u.u32=x; al=u.u16[_l]; ah=u.u16[_h]; // al=0x3400 ah=0x0012 u.u32=y; bl=u.u16[_l]; bh=u.u16[_h]; // bl=0x0056 bh=0x0023 // multiplication (al+ah<<1)*(bl+bh<<1) = al*bl + al*bh<<1 + ah*bl<<1 + ah*bh<<2 c0=(al*bl); // c0=0x00117800 c1=(al*bh)+(ah*bl);// c1=0x0007220C c2=(ah*bh); // c2=0x00000276 c3= 0; // c3=0x00000000 // propagate 2^16 overflows (backward to avoid overflow) c3+=c2>>16; c2&=0x0000FFFF; // c3=0x00000000 c2=0x00000276 c2+=c1>>16; c1&=0x0000FFFF; // c2=0x0000027D c1=0x0000220C c1+=c0>>16; c0&=0x0000FFFF; // c1=0x0000221D c0=0x00007800 // propagate 2^16 overflows (normaly to recover from secondary overflow) c2+=c1>>16; c1&=0x0000FFFF; // c2=0x0000027D c1=0x0000221D c3+=c2>>16; c2&=0x0000FFFF; // c3=0x00000000 c2=0x0000027D // (c3,c2,c1,c0) >> _fx32_fract_bits u.u16[_l]=c0; u.u16[_h]=c1; c0=u.u32; // c0=0x221D7800 u.u16[_l]=c2; u.u16[_h]=c3; c1=u.u32; // c1=0x0000027D c0 =(c0&_fx32_integ_mask)>>_fx32_fract_bits; // c0=0x0000443A c0|=(c1&_fx32_fract_mask)<<_fx32_integ_bits; // c0=0x04FA443A return c0; // 0x04FA443A -> 83510330/32768 = 2548.53302001953125 }
