c - 接收浮点数的序列化(花车,双打)
https://stackoverflow.com/questions/1786137
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21-09-2019 - |
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如何将浮点数转换成一个字节序列,以便它可以在一个文件中被持久?这样的算法必须快速和高度便携。它也必须允许相反的操作,反序列化。如果只需要非常小的过量每值(持久空间)位的这将是很好。
解决方案
假设你使用主流的编译器,漂浮在C和C点的值++服从IEEE标准,并且当写入二进制形式的文件可以在任何其他平台被回收,只要你写,并使用相同的字节字节顺序读。所以我的建议是:选择一个字节序的选择,并且在写之前或者如果字节顺序是一样的,在目前的平台上阅读,检查后;如果没有,只是交换字节。
其他提示
您可以随时转换为IEEE-754格式在一个固定的字节顺序(无论是小端或大端)。对于大多数的机器,这将需要在所有存在或是一个简单的字节交换序列化和反序列化。不支持IEEE-754机器本身需要一个转换器写的,但这样做有ldexp和frexp(斯塔纳德C库函数)和位洗牌是不是太老了。
这可能给你一个良好的开端。 - 它包一个浮点值转换成int和long long对,其可以然后串行化处理以通常的方式
#define FRAC_MAX 9223372036854775807LL /* 2**63 - 1 */
struct dbl_packed
{
int exp;
long long frac;
};
void pack(double x, struct dbl_packed *r)
{
double xf = fabs(frexp(x, &r->exp)) - 0.5;
if (xf < 0.0)
{
r->frac = 0;
return;
}
r->frac = 1 + (long long)(xf * 2.0 * (FRAC_MAX - 1));
if (x < 0.0)
r->frac = -r->frac;
}
double unpack(const struct dbl_packed *p)
{
double xf, x;
if (p->frac == 0)
return 0.0;
xf = ((double)(llabs(p->frac) - 1) / (FRAC_MAX - 1)) / 2.0;
x = ldexp(xf + 0.5, p->exp);
if (p->frac < 0)
x = -x;
return x;
}
你是什么意思, “便携式”?
有关的便携性,记住保持在标准中定义的范围内的数字:使用这些限度之外的单数,并有去所有便携向下漏极
double planck_time = 5.39124E-44; /* second */
浮点类型中
的5.2.4.2.2特征
[...]
10 The values given in the following list shall be replaced by constant
expressions with implementation-defined values [...]
11 The values given in the following list shall be replaced by constant
expressions with implementation-defined values [...]
12 The values given in the following list shall be replaced by constant
expressions with implementation-defined (positive) values [...]
[...]
请注意的实现定义在所有这些条款。
转换为ASCII码表示是最简单的,但如果你需要处理花车的巨大数量,那么你当然应该去二进制文件。但是,如果你关心可移植性这可能是一个棘手的问题。浮点数在不同的机器不同的表示。
如果你不想使用罐装库,那么你的浮动二进制串行器/解串器将只需要对其中的每一位土地和它所代表的“合同”。
下面是一个有趣的网站,与帮助:链接
的sprintf,fprintf中?你没有得到比这更便于携带。
你需要什么级别的便携性?如果该文件是要与相同的操作系统的计算机上阅读,它产生的,比你使用的二进制文件,只是保存和恢复的位模式应该工作。否则,如boytheo说,ASCII是你的朋友。
此版本具有超过每一个浮点值只有一个字节,以指示端序。但我认为,它仍然不是非常便携不过。
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <ctype.h>
#define LITEND 'L'
#define BIGEND 'B'
typedef short INT16;
typedef int INT32;
typedef double vec1_t;
typedef struct {
FILE *fp;
} WFILE, RFILE;
#define w_byte(c, p) putc((c), (p)->fp)
#define r_byte(p) getc((p)->fp)
static void w_vec1(vec1_t v1_Val, WFILE *p)
{
INT32 i;
char *pc_Val;
pc_Val = (char *)&v1_Val;
w_byte(LITEND, p);
for (i = 0; i<sizeof(vec1_t); i++)
{
w_byte(pc_Val[i], p);
}
}
static vec1_t r_vec1(RFILE *p)
{
INT32 i;
vec1_t v1_Val;
char c_Type,
*pc_Val;
pc_Val = (char *)&v1_Val;
c_Type = r_byte(p);
if (c_Type==LITEND)
{
for (i = 0; i<sizeof(vec1_t); i++)
{
pc_Val[i] = r_byte(p);
}
}
return v1_Val;
}
int main(void)
{
WFILE x_FileW,
*px_FileW = &x_FileW;
RFILE x_FileR,
*px_FileR = &x_FileR;
vec1_t v1_Val;
INT32 l_Val;
char *pc_Val = (char *)&v1_Val;
INT32 i;
px_FileW->fp = fopen("test.bin", "w");
v1_Val = 1234567890.0987654321;
printf("v1_Val before write = %.20f \n", v1_Val);
w_vec1(v1_Val, px_FileW);
fclose(px_FileW->fp);
px_FileR->fp = fopen("test.bin", "r");
v1_Val = r_vec1(px_FileR);
printf("v1_Val after read = %.20f \n", v1_Val);
fclose(px_FileR->fp);
return 0;
}
在这里,我们走了。
便携式IEEE 754串行化/ deserialisation应该 无论工作机器的内部浮点 表示。
https://github.com/MalcolmMcLean/ieee754
/*
* read a double from a stream in ieee754 format regardless of host
* encoding.
* fp - the stream
* bigendian - set to if big bytes first, clear for little bytes
* first
*
*/
double freadieee754(FILE *fp, int bigendian)
{
unsigned char buff[8];
int i;
double fnorm = 0.0;
unsigned char temp;
int sign;
int exponent;
double bitval;
int maski, mask;
int expbits = 11;
int significandbits = 52;
int shift;
double answer;
/* read the data */
for (i = 0; i < 8; i++)
buff[i] = fgetc(fp);
/* just reverse if not big-endian*/
if (!bigendian)
{
for (i = 0; i < 4; i++)
{
temp = buff[i];
buff[i] = buff[8 - i - 1];
buff[8 - i - 1] = temp;
}
}
sign = buff[0] & 0x80 ? -1 : 1;
/* exponet in raw format*/
exponent = ((buff[0] & 0x7F) << 4) | ((buff[1] & 0xF0) >> 4);
/* read inthe mantissa. Top bit is 0.5, the successive bits half*/
bitval = 0.5;
maski = 1;
mask = 0x08;
for (i = 0; i < significandbits; i++)
{
if (buff[maski] & mask)
fnorm += bitval;
bitval /= 2.0;
mask >>= 1;
if (mask == 0)
{
mask = 0x80;
maski++;
}
}
/* handle zero specially */
if (exponent == 0 && fnorm == 0)
return 0.0;
shift = exponent - ((1 << (expbits - 1)) - 1); /* exponent = shift + bias */
/* nans have exp 1024 and non-zero mantissa */
if (shift == 1024 && fnorm != 0)
return sqrt(-1.0);
/*infinity*/
if (shift == 1024 && fnorm == 0)
{
#ifdef INFINITY
return sign == 1 ? INFINITY : -INFINITY;
#endif
return (sign * 1.0) / 0.0;
}
if (shift > -1023)
{
answer = ldexp(fnorm + 1.0, shift);
return answer * sign;
}
else
{
/* denormalised numbers */
if (fnorm == 0.0)
return 0.0;
shift = -1022;
while (fnorm < 1.0)
{
fnorm *= 2;
shift--;
}
answer = ldexp(fnorm, shift);
return answer * sign;
}
}
/*
* write a double to a stream in ieee754 format regardless of host
* encoding.
* x - number to write
* fp - the stream
* bigendian - set to write big bytes first, elee write litle bytes
* first
* Returns: 0 or EOF on error
* Notes: different NaN types and negative zero not preserved.
* if the number is too big to represent it will become infinity
* if it is too small to represent it will become zero.
*/
int fwriteieee754(double x, FILE *fp, int bigendian)
{
int shift;
unsigned long sign, exp, hibits, hilong, lowlong;
double fnorm, significand;
int expbits = 11;
int significandbits = 52;
/* zero (can't handle signed zero) */
if (x == 0)
{
hilong = 0;
lowlong = 0;
goto writedata;
}
/* infinity */
if (x > DBL_MAX)
{
hilong = 1024 + ((1 << (expbits - 1)) - 1);
hilong <<= (31 - expbits);
lowlong = 0;
goto writedata;
}
/* -infinity */
if (x < -DBL_MAX)
{
hilong = 1024 + ((1 << (expbits - 1)) - 1);
hilong <<= (31 - expbits);
hilong |= (1 << 31);
lowlong = 0;
goto writedata;
}
/* NaN - dodgy because many compilers optimise out this test, but
*there is no portable isnan() */
if (x != x)
{
hilong = 1024 + ((1 << (expbits - 1)) - 1);
hilong <<= (31 - expbits);
lowlong = 1234;
goto writedata;
}
/* get the sign */
if (x < 0) { sign = 1; fnorm = -x; }
else { sign = 0; fnorm = x; }
/* get the normalized form of f and track the exponent */
shift = 0;
while (fnorm >= 2.0) { fnorm /= 2.0; shift++; }
while (fnorm < 1.0) { fnorm *= 2.0; shift--; }
/* check for denormalized numbers */
if (shift < -1022)
{
while (shift < -1022) { fnorm /= 2.0; shift++; }
shift = -1023;
}
/* out of range. Set to infinity */
else if (shift > 1023)
{
hilong = 1024 + ((1 << (expbits - 1)) - 1);
hilong <<= (31 - expbits);
hilong |= (sign << 31);
lowlong = 0;
goto writedata;
}
else
fnorm = fnorm - 1.0; /* take the significant bit off mantissa */
/* calculate the integer form of the significand */
/* hold it in a double for now */
significand = fnorm * ((1LL << significandbits) + 0.5f);
/* get the biased exponent */
exp = shift + ((1 << (expbits - 1)) - 1); /* shift + bias */
/* put the data into two longs (for convenience) */
hibits = (long)(significand / 4294967296);
hilong = (sign << 31) | (exp << (31 - expbits)) | hibits;
x = significand - hibits * 4294967296;
lowlong = (unsigned long)(significand - hibits * 4294967296);
writedata:
/* write the bytes out to the stream */
if (bigendian)
{
fputc((hilong >> 24) & 0xFF, fp);
fputc((hilong >> 16) & 0xFF, fp);
fputc((hilong >> 8) & 0xFF, fp);
fputc(hilong & 0xFF, fp);
fputc((lowlong >> 24) & 0xFF, fp);
fputc((lowlong >> 16) & 0xFF, fp);
fputc((lowlong >> 8) & 0xFF, fp);
fputc(lowlong & 0xFF, fp);
}
else
{
fputc(lowlong & 0xFF, fp);
fputc((lowlong >> 8) & 0xFF, fp);
fputc((lowlong >> 16) & 0xFF, fp);
fputc((lowlong >> 24) & 0xFF, fp);
fputc(hilong & 0xFF, fp);
fputc((hilong >> 8) & 0xFF, fp);
fputc((hilong >> 16) & 0xFF, fp);
fputc((hilong >> 24) & 0xFF, fp);
}
return ferror(fp);
}
的fwrite(),的fread()?你可能会希望二进制,你不能打包字节的任何严格的,除非你想牺牲精度,你会做的程序,然后fwrite()将FREAD()反正;浮起;双B; α=(浮点)B;的fwrite(&A,1,的sizeof(a)中,FP);
如果您携带不同的浮点格式围绕他们可能不在一条直线二进制转换感,所以你可能要挑分开位和执行运算,这对电力是加上这等IEEE 754是一个可怕的标准来使用,但普遍,因此会最小化的努力。
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