#include #include #include "fpconv.h" #include "powers.h" #define fracmask 0x000FFFFFFFFFFFFFU #define expmask 0x7FF0000000000000U #define hiddenbit 0x0010000000000000U #define signmask 0x8000000000000000U #define expbias (1023 + 52) #define absv(n) ((n) < 0 ? -(n) : (n)) #define minv(a, b) ((a) < (b) ? (a) : (b)) static uint64_t tens[] = { 10000000000000000000U, 1000000000000000000U, 100000000000000000U, 10000000000000000U, 1000000000000000U, 100000000000000U, 10000000000000U, 1000000000000U, 100000000000U, 10000000000U, 1000000000U, 100000000U, 10000000U, 1000000U, 100000U, 10000U, 1000U, 100U, 10U, 1U }; static inline uint64_t get_dbits(double d) { union { double dbl; uint64_t i; } dbl_bits = { d }; return dbl_bits.i; } static Fp build_fp(double d) { uint64_t bits = get_dbits(d); Fp fp; fp.frac = bits & fracmask; fp.exp = (bits & expmask) >> 52; if(fp.exp) { fp.frac += hiddenbit; fp.exp -= expbias; } else { fp.exp = -expbias + 1; } return fp; } static void normalize(Fp* fp) { while ((fp->frac & hiddenbit) == 0) { fp->frac <<= 1; fp->exp--; } int shift = 64 - 52 - 1; fp->frac <<= shift; fp->exp -= shift; } static void get_normalized_boundaries(Fp* fp, Fp* lower, Fp* upper) { upper->frac = (fp->frac << 1) + 1; upper->exp = fp->exp - 1; while ((upper->frac & (hiddenbit << 1)) == 0) { upper->frac <<= 1; upper->exp--; } int u_shift = 64 - 52 - 2; upper->frac <<= u_shift; upper->exp = upper->exp - u_shift; int l_shift = fp->frac == hiddenbit ? 2 : 1; lower->frac = (fp->frac << l_shift) - 1; lower->exp = fp->exp - l_shift; lower->frac <<= lower->exp - upper->exp; lower->exp = upper->exp; } static Fp multiply(Fp* a, Fp* b) { const uint64_t lomask = 0x00000000FFFFFFFF; uint64_t ah_bl = (a->frac >> 32) * (b->frac & lomask); uint64_t al_bh = (a->frac & lomask) * (b->frac >> 32); uint64_t al_bl = (a->frac & lomask) * (b->frac & lomask); uint64_t ah_bh = (a->frac >> 32) * (b->frac >> 32); uint64_t tmp = (ah_bl & lomask) + (al_bh & lomask) + (al_bl >> 32); /* round up */ tmp += 1U << 31; Fp fp = { ah_bh + (ah_bl >> 32) + (al_bh >> 32) + (tmp >> 32), a->exp + b->exp + 64 }; return fp; } static void round_digit(char* digits, int ndigits, uint64_t delta, uint64_t rem, uint64_t kappa, uint64_t frac) { while (rem < frac && delta - rem >= kappa && (rem + kappa < frac || frac - rem > rem + kappa - frac)) { digits[ndigits - 1]--; rem += kappa; } } static int generate_digits(Fp* fp, Fp* upper, Fp* lower, char* digits, int* K) { uint64_t wfrac = upper->frac - fp->frac; uint64_t delta = upper->frac - lower->frac; Fp one; one.frac = 1ULL << -upper->exp; one.exp = upper->exp; uint64_t part1 = upper->frac >> -one.exp; uint64_t part2 = upper->frac & (one.frac - 1); int idx = 0, kappa = 10; uint64_t* divp; /* 1000000000 */ for(divp = tens + 10; kappa > 0; divp++) { uint64_t div = *divp; unsigned digit = part1 / div; if (digit || idx) { digits[idx++] = digit + '0'; } part1 -= digit * div; kappa--; uint64_t tmp = (part1 <<-one.exp) + part2; if (tmp <= delta) { *K += kappa; round_digit(digits, idx, delta, tmp, div << -one.exp, wfrac); return idx; } } /* 10 */ uint64_t* unit = tens + 18; while(true) { part2 *= 10; delta *= 10; kappa--; unsigned digit = part2 >> -one.exp; if (digit || idx) { digits[idx++] = digit + '0'; } part2 &= one.frac - 1; if (part2 < delta) { *K += kappa; round_digit(digits, idx, delta, part2, one.frac, wfrac * *unit); return idx; } unit--; } } static int grisu2(double d, char* digits, int* K) { Fp w = build_fp(d); Fp lower, upper; get_normalized_boundaries(&w, &lower, &upper); normalize(&w); int k; Fp cp = find_cachedpow10(upper.exp, &k); w = multiply(&w, &cp); upper = multiply(&upper, &cp); lower = multiply(&lower, &cp); lower.frac++; upper.frac--; *K = -k; return generate_digits(&w, &upper, &lower, digits, K); } static int emit_digits(char* digits, int ndigits, char* dest, int K, bool neg, bool is_decimal) { int exp = absv(K + ndigits - 1); /* write plain integer */ if(K >= 0 && (exp < (ndigits + 7))) { memcpy(dest, digits, ndigits); memset(dest + ndigits, '0', K); return ndigits + K; } /* write decimal w/o scientific notation */ /* Or force decimal format if desired * even though it's longer than the scientific notation output */ if(K < 0 && ((K > -7 || exp < 4) || is_decimal)) { int offset = ndigits - absv(K); /* fp < 1.0 -> write leading zero(s) */ if(offset <= 0) { /* Pathological case of practically all zeroes */ /* NB this can lead to the result being '-0' */ if ( exp > (21-(int)neg) ) { memset(dest, '0', 1); return 1; } offset = -offset; dest[0] = '0'; dest[1] = '.'; memset(dest + 2, '0', offset); /* Now having potentially written a bunch of zeros, * ensure copying only as many digits that fit into the rest of the buffer * hence this is just truncation * but as this is along way down in the precision with a 24 char buffer * it's not of concern for our intended usage * (e.g 0.00...01919 -> 0.00...001 rather than 0.00...002 */ int n = ndigits; if ( (offset + ndigits) > (21-(int)neg) ) { n = 21-(int)neg - offset; } memcpy(dest + offset + 2, digits, n); return n + 2 + offset; /* fp > 1.0 */ } else { memcpy(dest, digits, offset); dest[offset] = '.'; memcpy(dest + offset + 1, digits + offset, ndigits - offset); return ndigits + 1; } } /* Force decimal format if desired * even though it's longer than the scientific notation output */ if(is_decimal) { memcpy(dest, digits, ndigits); memset(dest + ndigits, '0', K); return ndigits + K; } /* write decimal w/ scientific notation */ ndigits = minv(ndigits, 18 - neg); int idx = 0; dest[idx++] = digits[0]; if(ndigits > 1) { dest[idx++] = '.'; memcpy(dest + idx, digits + 1, ndigits - 1); idx += ndigits - 1; } dest[idx++] = 'e'; char sign = K + ndigits - 1 < 0 ? '-' : '+'; dest[idx++] = sign; int cent = 0; if(exp > 99) { cent = exp / 100; dest[idx++] = cent + '0'; exp -= cent * 100; } if(exp > 9) { int dec = exp / 10; dest[idx++] = dec + '0'; exp -= dec * 10; } else if(cent) { dest[idx++] = '0'; } dest[idx++] = exp % 10 + '0'; return idx; } static int filter_special(double fp, char* dest) { if(fp == 0.0) { dest[0] = '0'; return 1; } uint64_t bits = get_dbits(fp); bool nan = (bits & expmask) == expmask; if(!nan) { return 0; } if(bits & fracmask) { dest[0] = 'n'; dest[1] = 'a'; dest[2] = 'n'; } else { dest[0] = 'i'; dest[1] = 'n'; dest[2] = 'f'; } return 3; } int fpconv_dtoa(double d, char dest[24], int is_decimal) { char digits[18]; int str_len = 0; bool neg = false; bool decimal = (is_decimal != 0); if(get_dbits(d) & signmask) { dest[0] = '-'; str_len++; neg = true; } int spec = filter_special(d, dest + str_len); if(spec) { return str_len + spec; } int K = 0; int ndigits = grisu2(d, digits, &K); str_len += emit_digits(digits, ndigits, dest + str_len, K, neg, decimal); return str_len; }