refactor adjtime function using adjtimex function instead of syscall

[musl] / src / internal / floatscan.c

#include <stdint.h>
#include <stdio.h>
#include <math.h>
#include <float.h>
#include <limits.h>
#include <errno.h>
#include <ctype.h>

#include "shgetc.h"
#include "floatscan.h"

#if LDBL_MANT_DIG == 53 && LDBL_MAX_EXP == 1024

#define LD_B1B_DIG 2
#define LD_B1B_MAX 9007199, 254740991
#define KMAX 128

#elif LDBL_MANT_DIG == 64 && LDBL_MAX_EXP == 16384

#define LD_B1B_DIG 3
#define LD_B1B_MAX 18, 446744073, 709551615
#define KMAX 2048

#elif LDBL_MANT_DIG == 113 && LDBL_MAX_EXP == 16384

#define LD_B1B_DIG 4
#define LD_B1B_MAX 10384593, 717069655, 257060992, 658440191
#define KMAX 2048

#else
#error Unsupported long double representation
#endif

#define MASK (KMAX-1)

#define CONCAT2(x,y) x ## y
#define CONCAT(x,y) CONCAT2(x,y)

static long long scanexp(FILE *f, int pok)
{
        int c;
        int x;
        long long y;
        int neg = 0;
        
        c = shgetc(f);
        if (c=='+' || c=='-') {
                neg = (c=='-');
                c = shgetc(f);
                if (c-'0'>=10U && pok) shunget(f);
        }
        if (c-'0'>=10U) {
                shunget(f);
                return LLONG_MIN;
        }
        for (x=0; c-'0'<10U && x<INT_MAX/10; c = shgetc(f))
                x = 10*x + c-'0';
        for (y=x; c-'0'<10U && y<LLONG_MAX/100; c = shgetc(f))
                y = 10*y + c-'0';
        for (; c-'0'<10U; c = shgetc(f));
        shunget(f);
        return neg ? -y : y;
}


static long double decfloat(FILE *f, int c, int bits, int emin, int sign, int pok)
{
        uint32_t x[KMAX];
        static const uint32_t th[] = { LD_B1B_MAX };
        int i, j, k, a, z;
        long long lrp=0, dc=0;
        long long e10=0;
        int lnz = 0;
        int gotdig = 0, gotrad = 0;
        int rp;
        int e2;
        int emax = -emin-bits+3;
        int denormal = 0;
        long double y;
        long double frac=0;
        long double bias=0;
        static const int p10s[] = { 10, 100, 1000, 10000,
                100000, 1000000, 10000000, 100000000 };

        j=0;
        k=0;

        /* Don't let leading zeros consume buffer space */
        for (; c=='0'; c = shgetc(f)) gotdig=1;
        if (c=='.') {
                gotrad = 1;
                for (c = shgetc(f); c=='0'; c = shgetc(f)) gotdig=1, lrp--;
        }

        x[0] = 0;
        for (; c-'0'<10U || c=='.'; c = shgetc(f)) {
                if (c == '.') {
                        if (gotrad) break;
                        gotrad = 1;
                        lrp = dc;
                } else if (k < KMAX-3) {
                        dc++;
                        if (c!='0') lnz = dc;
                        if (j) x[k] = x[k]*10 + c-'0';
                        else x[k] = c-'0';
                        if (++j==9) {
                                k++;
                                j=0;
                        }
                        gotdig=1;
                } else {
                        dc++;
                        if (c!='0') {
                                lnz = (KMAX-4)*9;
                                x[KMAX-4] |= 1;
                        }
                }
        }
        if (!gotrad) lrp=dc;

        if (gotdig && (c|32)=='e') {
                e10 = scanexp(f, pok);
                if (e10 == LLONG_MIN) {
                        if (pok) {
                                shunget(f);
                        } else {
                                shlim(f, 0);
                                return 0;
                        }
                        e10 = 0;
                }
                lrp += e10;
        } else if (c>=0) {
                shunget(f);
        }
        if (!gotdig) {
                errno = EINVAL;
                shlim(f, 0);
                return 0;
        }

        /* Handle zero specially to avoid nasty special cases later */
        if (!x[0]) return sign * 0.0;

        /* Optimize small integers (w/no exponent) and over/under-flow */
        if (lrp==dc && dc<10 && (bits>30 || x[0]>>bits==0))
                return sign * (long double)x[0];
        if (lrp > -emin/2) {
                errno = ERANGE;
                return sign * LDBL_MAX * LDBL_MAX;
        }
        if (lrp < emin-2*LDBL_MANT_DIG) {
                errno = ERANGE;
                return sign * LDBL_MIN * LDBL_MIN;
        }

        /* Align incomplete final B1B digit */
        if (j) {
                for (; j<9; j++) x[k]*=10;
                k++;
                j=0;
        }

        a = 0;
        z = k;
        e2 = 0;
        rp = lrp;

        /* Optimize small to mid-size integers (even in exp. notation) */
        if (lnz<9 && lnz<=rp && rp < 18) {
                if (rp == 9) return sign * (long double)x[0];
                if (rp < 9) return sign * (long double)x[0] / p10s[8-rp];
                int bitlim = bits-3*(int)(rp-9);
                if (bitlim>30 || x[0]>>bitlim==0)
                        return sign * (long double)x[0] * p10s[rp-10];
        }

        /* Drop trailing zeros */
        for (; !x[z-1]; z--);

        /* Align radix point to B1B digit boundary */
        if (rp % 9) {
                int rpm9 = rp>=0 ? rp%9 : rp%9+9;
                int p10 = p10s[8-rpm9];
                uint32_t carry = 0;
                for (k=a; k!=z; k++) {
                        uint32_t tmp = x[k] % p10;
                        x[k] = x[k]/p10 + carry;
                        carry = 1000000000/p10 * tmp;
                        if (k==a && !x[k]) {
                                a = (a+1 & MASK);
                                rp -= 9;
                        }
                }
                if (carry) x[z++] = carry;
                rp += 9-rpm9;
        }

        /* Upscale until desired number of bits are left of radix point */
        while (rp < 9*LD_B1B_DIG || (rp == 9*LD_B1B_DIG && x[a]<th[0])) {
                uint32_t carry = 0;
                e2 -= 29;
                for (k=(z-1 & MASK); ; k=(k-1 & MASK)) {
                        uint64_t tmp = ((uint64_t)x[k] << 29) + carry;
                        if (tmp > 1000000000) {
                                carry = tmp / 1000000000;
                                x[k] = tmp % 1000000000;
                        } else {
                                carry = 0;
                                x[k] = tmp;
                        }
                        if (k==(z-1 & MASK) && k!=a && !x[k]) z = k;
                        if (k==a) break;
                }
                if (carry) {
                        rp += 9;
                        a = (a-1 & MASK);
                        if (a == z) {
                                z = (z-1 & MASK);
                                x[z-1 & MASK] |= x[z];
                        }
                        x[a] = carry;
                }
        }

        /* Downscale until exactly number of bits are left of radix point */
        for (;;) {
                uint32_t carry = 0;
                int sh = 1;
                for (i=0; i<LD_B1B_DIG; i++) {
                        k = (a+i & MASK);
                        if (k == z || x[k] < th[i]) {
                                i=LD_B1B_DIG;
                                break;
                        }
                        if (x[a+i & MASK] > th[i]) break;
                }
                if (i==LD_B1B_DIG && rp==9*LD_B1B_DIG) break;
                /* FIXME: find a way to compute optimal sh */
                if (rp > 9+9*LD_B1B_DIG) sh = 9;
                e2 += sh;
                for (k=a; k!=z; k=(k+1 & MASK)) {
                        uint32_t tmp = x[k] & (1<<sh)-1;
                        x[k] = (x[k]>>sh) + carry;
                        carry = (1000000000>>sh) * tmp;
                        if (k==a && !x[k]) {
                                a = (a+1 & MASK);
                                i--;
                                rp -= 9;
                        }
                }
                if (carry) {
                        if ((z+1 & MASK) != a) {
                                x[z] = carry;
                                z = (z+1 & MASK);
                        } else x[z-1 & MASK] |= 1;
                }
        }

        /* Assemble desired bits into floating point variable */
        for (y=i=0; i<LD_B1B_DIG; i++) {
                if ((a+i & MASK)==z) x[(z=(z+1 & MASK))-1] = 0;
                y = 1000000000.0L * y + x[a+i & MASK];
        }

        y *= sign;

        /* Limit precision for denormal results */
        if (bits > LDBL_MANT_DIG+e2-emin) {
                bits = LDBL_MANT_DIG+e2-emin;
                if (bits<0) bits=0;
                denormal = 1;
        }

        /* Calculate bias term to force rounding, move out lower bits */
        if (bits < LDBL_MANT_DIG) {
                bias = copysignl(scalbn(1, 2*LDBL_MANT_DIG-bits-1), y);
                frac = fmodl(y, scalbn(1, LDBL_MANT_DIG-bits));
                y -= frac;
                y += bias;
        }

        /* Process tail of decimal input so it can affect rounding */
        if ((a+i & MASK) != z) {
                uint32_t t = x[a+i & MASK];
                if (t < 500000000 && (t || (a+i+1 & MASK) != z))
                        frac += 0.25*sign;
                else if (t > 500000000)
                        frac += 0.75*sign;
                else if (t == 500000000) {
                        if ((a+i+1 & MASK) == z)
                                frac += 0.5*sign;
                        else
                                frac += 0.75*sign;
                }
                if (LDBL_MANT_DIG-bits >= 2 && !fmodl(frac, 1))
                        frac++;
        }

        y += frac;
        y -= bias;

        if ((e2+LDBL_MANT_DIG & INT_MAX) > emax-5) {
                if (fabs(y) >= CONCAT(0x1p, LDBL_MANT_DIG)) {
                        if (denormal && bits==LDBL_MANT_DIG+e2-emin)
                                denormal = 0;
                        y *= 0.5;
                        e2++;
                }
                if (e2+LDBL_MANT_DIG>emax || (denormal && frac))
                        errno = ERANGE;
        }

        return scalbnl(y, e2);
}

static long double hexfloat(FILE *f, int bits, int emin, int sign, int pok)
{
        uint32_t x = 0;
        long double y = 0;
        long double scale = 1;
        long double bias = 0;
        int gottail = 0, gotrad = 0, gotdig = 0;
        long long rp = 0;
        long long dc = 0;
        long long e2 = 0;
        int d;
        int c;

        c = shgetc(f);

        /* Skip leading zeros */
        for (; c=='0'; c = shgetc(f)) gotdig = 1;

        if (c=='.') {
                gotrad = 1;
                c = shgetc(f);
                /* Count zeros after the radix point before significand */
                for (rp=0; c=='0'; c = shgetc(f), rp--) gotdig = 1;
        }

        for (; c-'0'<10U || (c|32)-'a'<6U || c=='.'; c = shgetc(f)) {
                if (c=='.') {
                        if (gotrad) break;
                        rp = dc;
                        gotrad = 1;
                } else {
                        gotdig = 1;
                        if (c > '9') d = (c|32)+10-'a';
                        else d = c-'0';
                        if (dc<8) {
                                x = x*16 + d;
                        } else if (dc < LDBL_MANT_DIG/4+1) {
                                y += d*(scale/=16);
                        } else if (d && !gottail) {
                                y += 0.5*scale;
                                gottail = 1;
                        }
                        dc++;
                }
        }
        if (!gotdig) {
                shunget(f);
                if (pok) {
                        shunget(f);
                        if (gotrad) shunget(f);
                } else {
                        shlim(f, 0);
                }
                return sign * 0.0;
        }
        if (!gotrad) rp = dc;
        while (dc<8) x *= 16, dc++;
        if ((c|32)=='p') {
                e2 = scanexp(f, pok);
                if (e2 == LLONG_MIN) {
                        if (pok) {
                                shunget(f);
                        } else {
                                shlim(f, 0);
                                return 0;
                        }
                        e2 = 0;
                }
        } else {
                shunget(f);
        }
        e2 += 4*rp - 32;

        if (!x) return sign * 0.0;
        if (e2 > -emin) {
                errno = ERANGE;
                return sign * LDBL_MAX * LDBL_MAX;
        }
        if (e2 < emin-2*LDBL_MANT_DIG) {
                errno = ERANGE;
                return sign * LDBL_MIN * LDBL_MIN;
        }

        while (x < 0x80000000) {
                if (y>=0.5) {
                        x += x + 1;
                        y += y - 1;
                } else {
                        x += x;
                        y += y;
                }
                e2--;
        }

        if (bits > 32+e2-emin) {
                bits = 32+e2-emin;
                if (bits<0) bits=0;
        }

        if (bits < LDBL_MANT_DIG)
                bias = copysignl(scalbn(1, 32+LDBL_MANT_DIG-bits-1), sign);

        if (bits<32 && y && !(x&1)) x++, y=0;

        y = bias + sign*(long double)x + sign*y;
        y -= bias;

        if (!y) errno = ERANGE;

        return scalbnl(y, e2);
}

long double __floatscan(FILE *f, int prec, int pok)
{
        int sign = 1;
        size_t i;
        int bits;
        int emin;
        int c;

        switch (prec) {
        case 0:
                bits = FLT_MANT_DIG;
                emin = FLT_MIN_EXP-bits;
                break;
        case 1:
                bits = DBL_MANT_DIG;
                emin = DBL_MIN_EXP-bits;
                break;
        case 2:
                bits = LDBL_MANT_DIG;
                emin = LDBL_MIN_EXP-bits;
                break;
        default:
                return 0;
        }

        while (isspace((c=shgetc(f))));

        if (c=='+' || c=='-') {
                sign -= 2*(c=='-');
                c = shgetc(f);
        }

        for (i=0; i<8 && (c|32)=="infinity"[i]; i++)
                if (i<7) c = shgetc(f);
        if (i==3 || i==8 || (i>3 && pok)) {
                if (i!=8) {
                        shunget(f);
                        if (pok) for (; i>3; i--) shunget(f);
                }
                return sign * INFINITY;
        }
        if (!i) for (i=0; i<3 && (c|32)=="nan"[i]; i++)
                if (i<2) c = shgetc(f);
        if (i==3) {
                if (shgetc(f) != '(') {
                        shunget(f);
                        return NAN;
                }
                for (i=1; ; i++) {
                        c = shgetc(f);
                        if (c-'0'<10U || c-'A'<26U || c-'a'<26U || c=='_')
                                continue;
                        if (c==')') return NAN;
                        shunget(f);
                        if (!pok) {
                                errno = EINVAL;
                                shlim(f, 0);
                                return 0;
                        }
                        while (i--) shunget(f);
                        return NAN;
                }
                return NAN;
        }

        if (i) {
                shunget(f);
                errno = EINVAL;
                shlim(f, 0);
                return 0;
        }

        if (c=='0') {
                c = shgetc(f);
                if ((c|32) == 'x')
                        return hexfloat(f, bits, emin, sign, pok);
                shunget(f);
                c = '0';
        }

        return decfloat(f, c, bits, emin, sign, pok);
}