module strconv /* f32 to string Copyright (c) 2019-2021 Dario Deledda. All rights reserved. Use of this source code is governed by an MIT license that can be found in the LICENSE file. This file contains the f64 to string functions These functions are based on the work of: Publication:PLDI 2018: Proceedings of the 39th ACM SIGPLAN Conference on Programming Language Design and ImplementationJune 2018 Pages 270–282 https://doi.org/10.1145/3192366.3192369 inspired by the Go version here: https://github.com/cespare/ryu/tree/ba56a33f39e3bbbfa409095d0f9ae168a595feea */ // pow of ten table used by n_digit reduction const( ten_pow_table_64 = [ u64(1), u64(10), u64(100), u64(1000), u64(10000), u64(100000), u64(1000000), u64(10000000), u64(100000000), u64(1000000000), u64(10000000000), u64(100000000000), u64(1000000000000), u64(10000000000000), u64(100000000000000), u64(1000000000000000), u64(10000000000000000), u64(100000000000000000), u64(1000000000000000000), u64(10000000000000000000), ] ) /* Conversion Functions */ const( mantbits64 = u32(52) expbits64 = u32(11) bias64 = 1023 // f64 exponent bias maxexp64 = 2047 ) fn (d Dec64) get_string_64(neg bool, i_n_digit int, i_pad_digit int) string { mut n_digit := i_n_digit + 1 pad_digit := i_pad_digit + 1 mut out := d.m mut d_exp := d.e mut out_len := decimal_len_64(out) out_len_original := out_len mut fw_zeros := 0 if pad_digit > out_len { fw_zeros = pad_digit - out_len } mut buf := []byte{len:(out_len + 6 + 1 +1 + fw_zeros)} // sign + mant_len + . + e + e_sign + exp_len(2) + \0} mut i := 0 if neg { buf[i]=`-` i++ } mut disp := 0 if out_len <= 1 { disp = 1 } // rounding last used digit if n_digit < out_len { //println("out:[$out]") out += ten_pow_table_64[out_len - n_digit - 1] * 5 // round to up out /= ten_pow_table_64[out_len - n_digit ] //println("out1:[$out] ${d.m / ten_pow_table_64[out_len - n_digit ]}") if d.m / ten_pow_table_64[out_len - n_digit ] < out { d_exp++ n_digit++ } //println("cmp: ${d.m/ten_pow_table_64[out_len - n_digit ]} ${out/ten_pow_table_64[out_len - n_digit ]}") out_len = n_digit //println("orig: ${out_len_original} new len: ${out_len} out:[$out]") } y := i + out_len mut x := 0 for x < (out_len-disp-1) { buf[y - x] = `0` + byte(out%10) out /= 10 i++ x++ } if out_len >= 1 { buf[y - x] = `.` x++ i++ } if y-x >= 0 { buf[y - x] = `0` + byte(out%10) i++ } for fw_zeros > 0 { buf[i++] = `0` fw_zeros-- } /* x=0 for x 0 { buf[i]=`0` + byte(d0) i++ } buf[i]=`0` + byte(d1) i++ buf[i]=`0` + byte(d2) i++ buf[i]=0 /* x=0 for x mantbits64 { return d, false } shift := mantbits64 - e mant := i_mant | u64(0x0010_0000_0000_0000) // implicit 1 //mant := i_mant | (1 << mantbits64) // implicit 1 d.m = mant >> shift if (d.m << shift) != mant { return d, false } for (d.m % 10) == 0 { d.m /= 10 d.e++ } return d, true } fn f64_to_decimal(mant u64, exp u64) Dec64 { mut e2 := 0 mut m2 := u64(0) if exp == 0 { // We subtract 2 so that the bounds computation has // 2 additional bits. e2 = 1 - bias64 - int(mantbits64) - 2 m2 = mant } else { e2 = int(exp) - bias64 - int(mantbits64) - 2 m2 = (u64(1)<= 0 { // This expression is slightly faster than max(0, log10Pow2(e2) - 1). q := log10_pow2(e2) - bool_to_u32(e2 > 3) e10 = int(q) k := pow5_inv_num_bits_64 + pow5_bits(int(q)) - 1 i := -e2 + int(q) + k mul := pow5_inv_split_64[q] vr = mul_shift_64(u64(4) * m2 , mul, i) vp = mul_shift_64(u64(4) * m2 + u64(2) , mul, i) vm = mul_shift_64(u64(4) * m2 - u64(1) - mm_shift, mul, i) if q <= 21 { // This should use q <= 22, but I think 21 is also safe. // Smaller values may still be safe, but it's more // difficult to reason about them. Only one of mp, mv, // and mm can be a multiple of 5, if any. if mv%5 == 0 { vr_is_trailing_zeros = multiple_of_power_of_five_64(mv, q) } else if accept_bounds { // Same as min(e2 + (^mm & 1), pow5Factor64(mm)) >= q // <=> e2 + (^mm & 1) >= q && pow5Factor64(mm) >= q // <=> true && pow5Factor64(mm) >= q, since e2 >= q. vm_is_trailing_zeros = multiple_of_power_of_five_64(mv-1-mm_shift, q) } else if multiple_of_power_of_five_64(mv+2, q) { vp-- } } } else { // This expression is slightly faster than max(0, log10Pow5(-e2) - 1). q := log10_pow5(-e2) - bool_to_u32(-e2 > 1) e10 = int(q) + e2 i := -e2 - int(q) k := pow5_bits(i) - pow5_num_bits_64 j := int(q) - k mul := pow5_split_64[i] vr = mul_shift_64(u64(4) * m2 , mul, j) vp = mul_shift_64(u64(4) * m2 + u64(2) , mul, j) vm = mul_shift_64(u64(4) * m2 - u64(1) - mm_shift, mul, j) if q <= 1 { // {vr,vp,vm} is trailing zeros if {mv,mp,mm} has at least q trailing 0 bits. // mv = 4 * m2, so it always has at least two trailing 0 bits. vr_is_trailing_zeros = true if accept_bounds { // mm = mv - 1 - mmShift, so it has 1 trailing 0 bit iff mmShift == 1. vm_is_trailing_zeros = (mm_shift == 1) } else { // mp = mv + 2, so it always has at least one trailing 0 bit. vp-- } } else if q < 63 { // TODO(ulfjack/cespare): Use a tighter bound here. // We need to compute min(ntz(mv), pow5Factor64(mv) - e2) >= q - 1 // <=> ntz(mv) >= q - 1 && pow5Factor64(mv) - e2 >= q - 1 // <=> ntz(mv) >= q - 1 (e2 is negative and -e2 >= q) // <=> (mv & ((1 << (q - 1)) - 1)) == 0 // We also need to make sure that the left shift does not overflow. vr_is_trailing_zeros = multiple_of_power_of_two_64(mv, q - 1) } } // Step 4: Find the shortest decimal representation // in the interval of valid representations. mut removed := 0 mut last_removed_digit := byte(0) mut out := u64(0) // On average, we remove ~2 digits. if vm_is_trailing_zeros || vr_is_trailing_zeros { // General case, which happens rarely (~0.7%). for { vp_div_10 := vp / 10 vm_div_10 := vm / 10 if vp_div_10 <= vm_div_10 { break } vm_mod_10 := vm % 10 vr_div_10 := vr / 10 vr_mod_10 := vr % 10 vm_is_trailing_zeros = vm_is_trailing_zeros && vm_mod_10 == 0 vr_is_trailing_zeros = vr_is_trailing_zeros && (last_removed_digit == 0) last_removed_digit = byte(vr_mod_10) vr = vr_div_10 vp = vp_div_10 vm = vm_div_10 removed++ } if vm_is_trailing_zeros { for { vm_div_10 := vm / 10 vm_mod_10 := vm % 10 if vm_mod_10 != 0 { break } vp_div_10 := vp / 10 vr_div_10 := vr / 10 vr_mod_10 := vr % 10 vr_is_trailing_zeros = vr_is_trailing_zeros && (last_removed_digit == 0) last_removed_digit = byte(vr_mod_10) vr = vr_div_10 vp = vp_div_10 vm = vm_div_10 removed++ } } if vr_is_trailing_zeros && (last_removed_digit == 5) && (vr % 2) == 0 { // Round even if the exact number is .....50..0. last_removed_digit = 4 } out = vr // We need to take vr + 1 if vr is outside bounds // or we need to round up. if (vr == vm && (!accept_bounds || !vm_is_trailing_zeros)) || last_removed_digit >= 5 { out++ } } else { // Specialized for the common case (~99.3%). // Percentages below are relative to this. mut round_up := false for vp / 100 > vm / 100 { // Optimization: remove two digits at a time (~86.2%). round_up = (vr % 100) >= 50 vr /= 100 vp /= 100 vm /= 100 removed += 2 } // Loop iterations below (approximately), without optimization above: // 0: 0.03%, 1: 13.8%, 2: 70.6%, 3: 14.0%, 4: 1.40%, 5: 0.14%, 6+: 0.02% // Loop iterations below (approximately), with optimization above: // 0: 70.6%, 1: 27.8%, 2: 1.40%, 3: 0.14%, 4+: 0.02% for vp / 10 > vm / 10 { round_up = (vr % 10) >= 5 vr /= 10 vp /= 10 vm /= 10 removed++ } // We need to take vr + 1 if vr is outside bounds // or we need to round up. out = vr + bool_to_u64(vr == vm || round_up) } return Dec64{m: out, e: e10 + removed} } // f64_to_str return a string in scientific notation with max n_digit after the dot pub fn f64_to_str(f f64, n_digit int) string { mut u1 := Uf64{} u1.f = f u := unsafe {u1.u} neg := (u>>(mantbits64+expbits64)) != 0 mant := u & ((u64(1)<> mantbits64) & ((u64(1)<>(mantbits64+expbits64)) != 0 mant := u & ((u64(1)<> mantbits64) & ((u64(1)<