1//===----------------------------------------------------------------------===//
2//
3// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4// See https://llvm.org/LICENSE.txt for license information.
5// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6//
7//===----------------------------------------------------------------------===//
8
9// Copyright (c) Microsoft Corporation.
10// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
11
12// Copyright 2018 Ulf Adams
13// Copyright (c) Microsoft Corporation. All rights reserved.
14
15// Boost Software License - Version 1.0 - August 17th, 2003
16
17// Permission is hereby granted, free of charge, to any person or organization
18// obtaining a copy of the software and accompanying documentation covered by
19// this license (the "Software") to use, reproduce, display, distribute,
20// execute, and transmit the Software, and to prepare derivative works of the
21// Software, and to permit third-parties to whom the Software is furnished to
22// do so, all subject to the following:
23
24// The copyright notices in the Software and this entire statement, including
25// the above license grant, this restriction and the following disclaimer,
26// must be included in all copies of the Software, in whole or in part, and
27// all derivative works of the Software, unless such copies or derivative
28// works are solely in the form of machine-executable object code generated by
29// a source language processor.
30
31// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
32// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
33// FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT
34// SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE
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38
39// Avoid formatting to keep the changes with the original code minimal.
40// clang-format off
41
42#include <__assert>
43#include <__config>
44#include <charconv>
45
46#include "include/ryu/common.h"
47#include "include/ryu/d2fixed.h"
48#include "include/ryu/d2s_intrinsics.h"
49#include "include/ryu/digit_table.h"
50#include "include/ryu/f2s.h"
51#include "include/ryu/ryu.h"
52
53_LIBCPP_BEGIN_NAMESPACE_STD
54
55inline constexpr int __FLOAT_MANTISSA_BITS = 23;
56inline constexpr int __FLOAT_EXPONENT_BITS = 8;
57inline constexpr int __FLOAT_BIAS = 127;
58
59inline constexpr int __FLOAT_POW5_INV_BITCOUNT = 59;
60inline constexpr uint64_t __FLOAT_POW5_INV_SPLIT[31] = {
61 576460752303423489u, 461168601842738791u, 368934881474191033u, 295147905179352826u,
62 472236648286964522u, 377789318629571618u, 302231454903657294u, 483570327845851670u,
63 386856262276681336u, 309485009821345069u, 495176015714152110u, 396140812571321688u,
64 316912650057057351u, 507060240091291761u, 405648192073033409u, 324518553658426727u,
65 519229685853482763u, 415383748682786211u, 332306998946228969u, 531691198313966350u,
66 425352958651173080u, 340282366920938464u, 544451787073501542u, 435561429658801234u,
67 348449143727040987u, 557518629963265579u, 446014903970612463u, 356811923176489971u,
68 570899077082383953u, 456719261665907162u, 365375409332725730u
69};
70inline constexpr int __FLOAT_POW5_BITCOUNT = 61;
71inline constexpr uint64_t __FLOAT_POW5_SPLIT[47] = {
72 1152921504606846976u, 1441151880758558720u, 1801439850948198400u, 2251799813685248000u,
73 1407374883553280000u, 1759218604441600000u, 2199023255552000000u, 1374389534720000000u,
74 1717986918400000000u, 2147483648000000000u, 1342177280000000000u, 1677721600000000000u,
75 2097152000000000000u, 1310720000000000000u, 1638400000000000000u, 2048000000000000000u,
76 1280000000000000000u, 1600000000000000000u, 2000000000000000000u, 1250000000000000000u,
77 1562500000000000000u, 1953125000000000000u, 1220703125000000000u, 1525878906250000000u,
78 1907348632812500000u, 1192092895507812500u, 1490116119384765625u, 1862645149230957031u,
79 1164153218269348144u, 1455191522836685180u, 1818989403545856475u, 2273736754432320594u,
80 1421085471520200371u, 1776356839400250464u, 2220446049250313080u, 1387778780781445675u,
81 1734723475976807094u, 2168404344971008868u, 1355252715606880542u, 1694065894508600678u,
82 2117582368135750847u, 1323488980084844279u, 1654361225106055349u, 2067951531382569187u,
83 1292469707114105741u, 1615587133892632177u, 2019483917365790221u
84};
85
86[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline uint32_t __pow5Factor(uint32_t __value) {
87 uint32_t __count = 0;
88 for (;;) {
89 _LIBCPP_ASSERT_INTERNAL(__value != 0, "");
90 const uint32_t __q = __value / 5;
91 const uint32_t __r = __value % 5;
92 if (__r != 0) {
93 break;
94 }
95 __value = __q;
96 ++__count;
97 }
98 return __count;
99}
100
101// Returns true if __value is divisible by 5^__p.
102[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline bool __multipleOfPowerOf5(const uint32_t __value, const uint32_t __p) {
103 return __pow5Factor(__value) >= __p;
104}
105
106// Returns true if __value is divisible by 2^__p.
107[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline bool __multipleOfPowerOf2(const uint32_t __value, const uint32_t __p) {
108 _LIBCPP_ASSERT_INTERNAL(__value != 0, "");
109 _LIBCPP_ASSERT_INTERNAL(__p < 32, "");
110 // __builtin_ctz doesn't appear to be faster here.
111 return (__value & ((1u << __p) - 1)) == 0;
112}
113
114[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline uint32_t __mulShift(const uint32_t __m, const uint64_t __factor, const int32_t __shift) {
115 _LIBCPP_ASSERT_INTERNAL(__shift > 32, "");
116
117 // The casts here help MSVC to avoid calls to the __allmul library
118 // function.
119 const uint32_t __factorLo = static_cast<uint32_t>(__factor);
120 const uint32_t __factorHi = static_cast<uint32_t>(__factor >> 32);
121 const uint64_t __bits0 = static_cast<uint64_t>(__m) * __factorLo;
122 const uint64_t __bits1 = static_cast<uint64_t>(__m) * __factorHi;
123
124#ifndef _LIBCPP_64_BIT
125 // On 32-bit platforms we can avoid a 64-bit shift-right since we only
126 // need the upper 32 bits of the result and the shift value is > 32.
127 const uint32_t __bits0Hi = static_cast<uint32_t>(__bits0 >> 32);
128 uint32_t __bits1Lo = static_cast<uint32_t>(__bits1);
129 uint32_t __bits1Hi = static_cast<uint32_t>(__bits1 >> 32);
130 __bits1Lo += __bits0Hi;
131 __bits1Hi += (__bits1Lo < __bits0Hi);
132 const int32_t __s = __shift - 32;
133 return (__bits1Hi << (32 - __s)) | (__bits1Lo >> __s);
134#else // ^^^ 32-bit ^^^ / vvv 64-bit vvv
135 const uint64_t __sum = (__bits0 >> 32) + __bits1;
136 const uint64_t __shiftedSum = __sum >> (__shift - 32);
137 _LIBCPP_ASSERT_INTERNAL(__shiftedSum <= UINT32_MAX, "");
138 return static_cast<uint32_t>(__shiftedSum);
139#endif // ^^^ 64-bit ^^^
140}
141
142[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline uint32_t __mulPow5InvDivPow2(const uint32_t __m, const uint32_t __q, const int32_t __j) {
143 return __mulShift(__m, __FLOAT_POW5_INV_SPLIT[__q], __j);
144}
145
146[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline uint32_t __mulPow5divPow2(const uint32_t __m, const uint32_t __i, const int32_t __j) {
147 return __mulShift(__m, __FLOAT_POW5_SPLIT[__i], __j);
148}
149
150// A floating decimal representing m * 10^e.
151struct __floating_decimal_32 {
152 uint32_t __mantissa;
153 int32_t __exponent;
154};
155
156[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline __floating_decimal_32 __f2d(const uint32_t __ieeeMantissa, const uint32_t __ieeeExponent) {
157 int32_t __e2;
158 uint32_t __m2;
159 if (__ieeeExponent == 0) {
160 // We subtract 2 so that the bounds computation has 2 additional bits.
161 __e2 = 1 - __FLOAT_BIAS - __FLOAT_MANTISSA_BITS - 2;
162 __m2 = __ieeeMantissa;
163 } else {
164 __e2 = static_cast<int32_t>(__ieeeExponent) - __FLOAT_BIAS - __FLOAT_MANTISSA_BITS - 2;
165 __m2 = (1u << __FLOAT_MANTISSA_BITS) | __ieeeMantissa;
166 }
167 const bool __even = (__m2 & 1) == 0;
168 const bool __acceptBounds = __even;
169
170 // Step 2: Determine the interval of valid decimal representations.
171 const uint32_t __mv = 4 * __m2;
172 const uint32_t __mp = 4 * __m2 + 2;
173 // Implicit bool -> int conversion. True is 1, false is 0.
174 const uint32_t __mmShift = __ieeeMantissa != 0 || __ieeeExponent <= 1;
175 const uint32_t __mm = 4 * __m2 - 1 - __mmShift;
176
177 // Step 3: Convert to a decimal power base using 64-bit arithmetic.
178 uint32_t __vr, __vp, __vm;
179 int32_t __e10;
180 bool __vmIsTrailingZeros = false;
181 bool __vrIsTrailingZeros = false;
182 uint8_t __lastRemovedDigit = 0;
183 if (__e2 >= 0) {
184 const uint32_t __q = __log10Pow2(__e2);
185 __e10 = static_cast<int32_t>(__q);
186 const int32_t __k = __FLOAT_POW5_INV_BITCOUNT + __pow5bits(static_cast<int32_t>(__q)) - 1;
187 const int32_t __i = -__e2 + static_cast<int32_t>(__q) + __k;
188 __vr = __mulPow5InvDivPow2(__mv, __q, __i);
189 __vp = __mulPow5InvDivPow2(__mp, __q, __i);
190 __vm = __mulPow5InvDivPow2(__mm, __q, __i);
191 if (__q != 0 && (__vp - 1) / 10 <= __vm / 10) {
192 // We need to know one removed digit even if we are not going to loop below. We could use
193 // __q = X - 1 above, except that would require 33 bits for the result, and we've found that
194 // 32-bit arithmetic is faster even on 64-bit machines.
195 const int32_t __l = __FLOAT_POW5_INV_BITCOUNT + __pow5bits(static_cast<int32_t>(__q - 1)) - 1;
196 __lastRemovedDigit = static_cast<uint8_t>(__mulPow5InvDivPow2(__mv, __q - 1,
197 -__e2 + static_cast<int32_t>(__q) - 1 + __l) % 10);
198 }
199 if (__q <= 9) {
200 // The largest power of 5 that fits in 24 bits is 5^10, but __q <= 9 seems to be safe as well.
201 // Only one of __mp, __mv, and __mm can be a multiple of 5, if any.
202 if (__mv % 5 == 0) {
203 __vrIsTrailingZeros = __multipleOfPowerOf5(__mv, __q);
204 } else if (__acceptBounds) {
205 __vmIsTrailingZeros = __multipleOfPowerOf5(__mm, __q);
206 } else {
207 __vp -= __multipleOfPowerOf5(__mp, __q);
208 }
209 }
210 } else {
211 const uint32_t __q = __log10Pow5(-__e2);
212 __e10 = static_cast<int32_t>(__q) + __e2;
213 const int32_t __i = -__e2 - static_cast<int32_t>(__q);
214 const int32_t __k = __pow5bits(__i) - __FLOAT_POW5_BITCOUNT;
215 int32_t __j = static_cast<int32_t>(__q) - __k;
216 __vr = __mulPow5divPow2(__mv, static_cast<uint32_t>(__i), __j);
217 __vp = __mulPow5divPow2(__mp, static_cast<uint32_t>(__i), __j);
218 __vm = __mulPow5divPow2(__mm, static_cast<uint32_t>(__i), __j);
219 if (__q != 0 && (__vp - 1) / 10 <= __vm / 10) {
220 __j = static_cast<int32_t>(__q) - 1 - (__pow5bits(__i + 1) - __FLOAT_POW5_BITCOUNT);
221 __lastRemovedDigit = static_cast<uint8_t>(__mulPow5divPow2(__mv, static_cast<uint32_t>(__i + 1), __j) % 10);
222 }
223 if (__q <= 1) {
224 // {__vr,__vp,__vm} is trailing zeros if {__mv,__mp,__mm} has at least __q trailing 0 bits.
225 // __mv = 4 * __m2, so it always has at least two trailing 0 bits.
226 __vrIsTrailingZeros = true;
227 if (__acceptBounds) {
228 // __mm = __mv - 1 - __mmShift, so it has 1 trailing 0 bit iff __mmShift == 1.
229 __vmIsTrailingZeros = __mmShift == 1;
230 } else {
231 // __mp = __mv + 2, so it always has at least one trailing 0 bit.
232 --__vp;
233 }
234 } else if (__q < 31) { // TRANSITION(ulfjack): Use a tighter bound here.
235 __vrIsTrailingZeros = __multipleOfPowerOf2(__mv, __q - 1);
236 }
237 }
238
239 // Step 4: Find the shortest decimal representation in the interval of valid representations.
240 int32_t __removed = 0;
241 uint32_t _Output;
242 if (__vmIsTrailingZeros || __vrIsTrailingZeros) {
243 // General case, which happens rarely (~4.0%).
244 while (__vp / 10 > __vm / 10) {
245#ifdef __clang__ // TRANSITION, LLVM-23106
246 __vmIsTrailingZeros &= __vm - (__vm / 10) * 10 == 0;
247#else
248 __vmIsTrailingZeros &= __vm % 10 == 0;
249#endif
250 __vrIsTrailingZeros &= __lastRemovedDigit == 0;
251 __lastRemovedDigit = static_cast<uint8_t>(__vr % 10);
252 __vr /= 10;
253 __vp /= 10;
254 __vm /= 10;
255 ++__removed;
256 }
257 if (__vmIsTrailingZeros) {
258 while (__vm % 10 == 0) {
259 __vrIsTrailingZeros &= __lastRemovedDigit == 0;
260 __lastRemovedDigit = static_cast<uint8_t>(__vr % 10);
261 __vr /= 10;
262 __vp /= 10;
263 __vm /= 10;
264 ++__removed;
265 }
266 }
267 if (__vrIsTrailingZeros && __lastRemovedDigit == 5 && __vr % 2 == 0) {
268 // Round even if the exact number is .....50..0.
269 __lastRemovedDigit = 4;
270 }
271 // We need to take __vr + 1 if __vr is outside bounds or we need to round up.
272 _Output = __vr + ((__vr == __vm && (!__acceptBounds || !__vmIsTrailingZeros)) || __lastRemovedDigit >= 5);
273 } else {
274 // Specialized for the common case (~96.0%). Percentages below are relative to this.
275 // Loop iterations below (approximately):
276 // 0: 13.6%, 1: 70.7%, 2: 14.1%, 3: 1.39%, 4: 0.14%, 5+: 0.01%
277 while (__vp / 10 > __vm / 10) {
278 __lastRemovedDigit = static_cast<uint8_t>(__vr % 10);
279 __vr /= 10;
280 __vp /= 10;
281 __vm /= 10;
282 ++__removed;
283 }
284 // We need to take __vr + 1 if __vr is outside bounds or we need to round up.
285 _Output = __vr + (__vr == __vm || __lastRemovedDigit >= 5);
286 }
287 const int32_t __exp = __e10 + __removed;
288
289 __floating_decimal_32 __fd;
290 __fd.__exponent = __exp;
291 __fd.__mantissa = _Output;
292 return __fd;
293}
294
295[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline to_chars_result _Large_integer_to_chars(char* const _First, char* const _Last,
296 const uint32_t _Mantissa2, const int32_t _Exponent2) {
297
298 // Print the integer _Mantissa2 * 2^_Exponent2 exactly.
299
300 // For nonzero integers, _Exponent2 >= -23. (The minimum value occurs when _Mantissa2 * 2^_Exponent2 is 1.
301 // In that case, _Mantissa2 is the implicit 1 bit followed by 23 zeros, so _Exponent2 is -23 to shift away
302 // the zeros.) The dense range of exactly representable integers has negative or zero exponents
303 // (as positive exponents make the range non-dense). For that dense range, Ryu will always be used:
304 // every digit is necessary to uniquely identify the value, so Ryu must print them all.
305
306 // Positive exponents are the non-dense range of exactly representable integers.
307 // This contains all of the values for which Ryu can't be used (and a few Ryu-friendly values).
308
309 // Performance note: Long division appears to be faster than losslessly widening float to double and calling
310 // __d2fixed_buffered_n(). If __f2fixed_buffered_n() is implemented, it might be faster than long division.
311
312 _LIBCPP_ASSERT_INTERNAL(_Exponent2 > 0, "");
313 _LIBCPP_ASSERT_INTERNAL(_Exponent2 <= 104, ""); // because __ieeeExponent <= 254
314
315 // Manually represent _Mantissa2 * 2^_Exponent2 as a large integer. _Mantissa2 is always 24 bits
316 // (due to the implicit bit), while _Exponent2 indicates a shift of at most 104 bits.
317 // 24 + 104 equals 128 equals 4 * 32, so we need exactly 4 32-bit elements.
318 // We use a little-endian representation, visualized like this:
319
320 // << left shift <<
321 // most significant
322 // _Data[3] _Data[2] _Data[1] _Data[0]
323 // least significant
324 // >> right shift >>
325
326 constexpr uint32_t _Data_size = 4;
327 uint32_t _Data[_Data_size]{};
328
329 // _Maxidx is the index of the most significant nonzero element.
330 uint32_t _Maxidx = ((24 + static_cast<uint32_t>(_Exponent2) + 31) / 32) - 1;
331 _LIBCPP_ASSERT_INTERNAL(_Maxidx < _Data_size, "");
332
333 const uint32_t _Bit_shift = static_cast<uint32_t>(_Exponent2) % 32;
334 if (_Bit_shift <= 8) { // _Mantissa2's 24 bits don't cross an element boundary
335 _Data[_Maxidx] = _Mantissa2 << _Bit_shift;
336 } else { // _Mantissa2's 24 bits cross an element boundary
337 _Data[_Maxidx - 1] = _Mantissa2 << _Bit_shift;
338 _Data[_Maxidx] = _Mantissa2 >> (32 - _Bit_shift);
339 }
340
341 // If Ryu hasn't determined the total output length, we need to buffer the digits generated from right to left
342 // by long division. The largest possible float is: 340'282346638'528859811'704183484'516925440
343 uint32_t _Blocks[4];
344 int32_t _Filled_blocks = 0;
345 // From left to right, we're going to print:
346 // _Data[0] will be [1, 10] digits.
347 // Then if _Filled_blocks > 0:
348 // _Blocks[_Filled_blocks - 1], ..., _Blocks[0] will be 0-filled 9-digit blocks.
349
350 if (_Maxidx != 0) { // If the integer is actually large, perform long division.
351 // Otherwise, skip to printing _Data[0].
352 for (;;) {
353 // Loop invariant: _Maxidx != 0 (i.e. the integer is actually large)
354
355 const uint32_t _Most_significant_elem = _Data[_Maxidx];
356 const uint32_t _Initial_remainder = _Most_significant_elem % 1000000000;
357 const uint32_t _Initial_quotient = _Most_significant_elem / 1000000000;
358 _Data[_Maxidx] = _Initial_quotient;
359 uint64_t _Remainder = _Initial_remainder;
360
361 // Process less significant elements.
362 uint32_t _Idx = _Maxidx;
363 do {
364 --_Idx; // Initially, _Remainder is at most 10^9 - 1.
365
366 // Now, _Remainder is at most (10^9 - 1) * 2^32 + 2^32 - 1, simplified to 10^9 * 2^32 - 1.
367 _Remainder = (_Remainder << 32) | _Data[_Idx];
368
369 // floor((10^9 * 2^32 - 1) / 10^9) == 2^32 - 1, so uint32_t _Quotient is lossless.
370 const uint32_t _Quotient = static_cast<uint32_t>(__div1e9(_Remainder));
371
372 // _Remainder is at most 10^9 - 1 again.
373 // For uint32_t truncation, see the __mod1e9() comment in d2s_intrinsics.h.
374 _Remainder = static_cast<uint32_t>(_Remainder) - 1000000000u * _Quotient;
375
376 _Data[_Idx] = _Quotient;
377 } while (_Idx != 0);
378
379 // Store a 0-filled 9-digit block.
380 _Blocks[_Filled_blocks++] = static_cast<uint32_t>(_Remainder);
381
382 if (_Initial_quotient == 0) { // Is the large integer shrinking?
383 --_Maxidx; // log2(10^9) is 29.9, so we can't shrink by more than one element.
384 if (_Maxidx == 0) {
385 break; // We've finished long division. Now we need to print _Data[0].
386 }
387 }
388 }
389 }
390
391 _LIBCPP_ASSERT_INTERNAL(_Data[0] != 0, "");
392 for (uint32_t _Idx = 1; _Idx < _Data_size; ++_Idx) {
393 _LIBCPP_ASSERT_INTERNAL(_Data[_Idx] == 0, "");
394 }
395
396 const uint32_t _Data_olength = _Data[0] >= 1000000000 ? 10 : __decimalLength9(_Data[0]);
397 const uint32_t _Total_fixed_length = _Data_olength + 9 * _Filled_blocks;
398
399 if (_Last - _First < static_cast<ptrdiff_t>(_Total_fixed_length)) {
400 return { _Last, errc::value_too_large };
401 }
402
403 char* _Result = _First;
404
405 // Print _Data[0]. While it's up to 10 digits,
406 // which is more than Ryu generates, the code below can handle this.
407 __append_n_digits(_Data_olength, _Data[0], _Result);
408 _Result += _Data_olength;
409
410 // Print 0-filled 9-digit blocks.
411 for (int32_t _Idx = _Filled_blocks - 1; _Idx >= 0; --_Idx) {
412 __append_nine_digits(_Blocks[_Idx], _Result);
413 _Result += 9;
414 }
415
416 return { _Result, errc{} };
417}
418
419[[nodiscard]] _LIBCPP_HIDE_FROM_ABI inline to_chars_result __to_chars(char* const _First, char* const _Last, const __floating_decimal_32 __v,
420 chars_format _Fmt, const uint32_t __ieeeMantissa, const uint32_t __ieeeExponent) {
421 // Step 5: Print the decimal representation.
422 uint32_t _Output = __v.__mantissa;
423 int32_t _Ryu_exponent = __v.__exponent;
424 const uint32_t __olength = __decimalLength9(_Output);
425 int32_t _Scientific_exponent = _Ryu_exponent + static_cast<int32_t>(__olength) - 1;
426
427 if (_Fmt == chars_format{}) {
428 int32_t _Lower;
429 int32_t _Upper;
430
431 if (__olength == 1) {
432 // Value | Fixed | Scientific
433 // 1e-3 | "0.001" | "1e-03"
434 // 1e4 | "10000" | "1e+04"
435 _Lower = -3;
436 _Upper = 4;
437 } else {
438 // Value | Fixed | Scientific
439 // 1234e-7 | "0.0001234" | "1.234e-04"
440 // 1234e5 | "123400000" | "1.234e+08"
441 _Lower = -static_cast<int32_t>(__olength + 3);
442 _Upper = 5;
443 }
444
445 if (_Lower <= _Ryu_exponent && _Ryu_exponent <= _Upper) {
446 _Fmt = chars_format::fixed;
447 } else {
448 _Fmt = chars_format::scientific;
449 }
450 } else if (_Fmt == chars_format::general) {
451 // C11 7.21.6.1 "The fprintf function"/8:
452 // "Let P equal [...] 6 if the precision is omitted [...].
453 // Then, if a conversion with style E would have an exponent of X:
454 // - if P > X >= -4, the conversion is with style f [...].
455 // - otherwise, the conversion is with style e [...]."
456 if (-4 <= _Scientific_exponent && _Scientific_exponent < 6) {
457 _Fmt = chars_format::fixed;
458 } else {
459 _Fmt = chars_format::scientific;
460 }
461 }
462
463 if (_Fmt == chars_format::fixed) {
464 // Example: _Output == 1729, __olength == 4
465
466 // _Ryu_exponent | Printed | _Whole_digits | _Total_fixed_length | Notes
467 // --------------|----------|---------------|----------------------|---------------------------------------
468 // 2 | 172900 | 6 | _Whole_digits | Ryu can't be used for printing
469 // 1 | 17290 | 5 | (sometimes adjusted) | when the trimmed digits are nonzero.
470 // --------------|----------|---------------|----------------------|---------------------------------------
471 // 0 | 1729 | 4 | _Whole_digits | Unified length cases.
472 // --------------|----------|---------------|----------------------|---------------------------------------
473 // -1 | 172.9 | 3 | __olength + 1 | This case can't happen for
474 // -2 | 17.29 | 2 | | __olength == 1, but no additional
475 // -3 | 1.729 | 1 | | code is needed to avoid it.
476 // --------------|----------|---------------|----------------------|---------------------------------------
477 // -4 | 0.1729 | 0 | 2 - _Ryu_exponent | C11 7.21.6.1 "The fprintf function"/8:
478 // -5 | 0.01729 | -1 | | "If a decimal-point character appears,
479 // -6 | 0.001729 | -2 | | at least one digit appears before it."
480
481 const int32_t _Whole_digits = static_cast<int32_t>(__olength) + _Ryu_exponent;
482
483 uint32_t _Total_fixed_length;
484 if (_Ryu_exponent >= 0) { // cases "172900" and "1729"
485 _Total_fixed_length = static_cast<uint32_t>(_Whole_digits);
486 if (_Output == 1) {
487 // Rounding can affect the number of digits.
488 // For example, 1e11f is exactly "99999997952" which is 11 digits instead of 12.
489 // We can use a lookup table to detect this and adjust the total length.
490 static constexpr uint8_t _Adjustment[39] = {
491 0,0,0,0,0,0,0,0,0,0,0,1,1,1,0,1,0,1,1,1,0,0,1,1,0,1,0,1,1,0,0,1,0,1,1,0,1,1,1 };
492 _Total_fixed_length -= _Adjustment[_Ryu_exponent];
493 // _Whole_digits doesn't need to be adjusted because these cases won't refer to it later.
494 }
495 } else if (_Whole_digits > 0) { // case "17.29"
496 _Total_fixed_length = __olength + 1;
497 } else { // case "0.001729"
498 _Total_fixed_length = static_cast<uint32_t>(2 - _Ryu_exponent);
499 }
500
501 if (_Last - _First < static_cast<ptrdiff_t>(_Total_fixed_length)) {
502 return { _Last, errc::value_too_large };
503 }
504
505 char* _Mid;
506 if (_Ryu_exponent > 0) { // case "172900"
507 bool _Can_use_ryu;
508
509 if (_Ryu_exponent > 10) { // 10^10 is the largest power of 10 that's exactly representable as a float.
510 _Can_use_ryu = false;
511 } else {
512 // Ryu generated X: __v.__mantissa * 10^_Ryu_exponent
513 // __v.__mantissa == 2^_Trailing_zero_bits * (__v.__mantissa >> _Trailing_zero_bits)
514 // 10^_Ryu_exponent == 2^_Ryu_exponent * 5^_Ryu_exponent
515
516 // _Trailing_zero_bits is [0, 29] (aside: because 2^29 is the largest power of 2
517 // with 9 decimal digits, which is float's round-trip limit.)
518 // _Ryu_exponent is [1, 10].
519 // Normalization adds [2, 23] (aside: at least 2 because the pre-normalized mantissa is at least 5).
520 // This adds up to [3, 62], which is well below float's maximum binary exponent 127.
521
522 // Therefore, we just need to consider (__v.__mantissa >> _Trailing_zero_bits) * 5^_Ryu_exponent.
523
524 // If that product would exceed 24 bits, then X can't be exactly represented as a float.
525 // (That's not a problem for round-tripping, because X is close enough to the original float,
526 // but X isn't mathematically equal to the original float.) This requires a high-precision fallback.
527
528 // If the product is 24 bits or smaller, then X can be exactly represented as a float (and we don't
529 // need to re-synthesize it; the original float must have been X, because Ryu wouldn't produce the
530 // same output for two different floats X and Y). This allows Ryu's output to be used (zero-filled).
531
532 // (2^24 - 1) / 5^0 (for indexing), (2^24 - 1) / 5^1, ..., (2^24 - 1) / 5^10
533 static constexpr uint32_t _Max_shifted_mantissa[11] = {
534 16777215, 3355443, 671088, 134217, 26843, 5368, 1073, 214, 42, 8, 1 };
535
536 unsigned long _Trailing_zero_bits;
537 (void) _BitScanForward(&_Trailing_zero_bits, __v.__mantissa); // __v.__mantissa is guaranteed nonzero
538 const uint32_t _Shifted_mantissa = __v.__mantissa >> _Trailing_zero_bits;
539 _Can_use_ryu = _Shifted_mantissa <= _Max_shifted_mantissa[_Ryu_exponent];
540 }
541
542 if (!_Can_use_ryu) {
543 const uint32_t _Mantissa2 = __ieeeMantissa | (1u << __FLOAT_MANTISSA_BITS); // restore implicit bit
544 const int32_t _Exponent2 = static_cast<int32_t>(__ieeeExponent)
545 - __FLOAT_BIAS - __FLOAT_MANTISSA_BITS; // bias and normalization
546
547 // Performance note: We've already called Ryu, so this will redundantly perform buffering and bounds checking.
548 return _Large_integer_to_chars(_First, _Last, _Mantissa2, _Exponent2);
549 }
550
551 // _Can_use_ryu
552 // Print the decimal digits, left-aligned within [_First, _First + _Total_fixed_length).
553 _Mid = _First + __olength;
554 } else { // cases "1729", "17.29", and "0.001729"
555 // Print the decimal digits, right-aligned within [_First, _First + _Total_fixed_length).
556 _Mid = _First + _Total_fixed_length;
557 }
558
559 while (_Output >= 10000) {
560#ifdef __clang__ // TRANSITION, LLVM-38217
561 const uint32_t __c = _Output - 10000 * (_Output / 10000);
562#else
563 const uint32_t __c = _Output % 10000;
564#endif
565 _Output /= 10000;
566 const uint32_t __c0 = (__c % 100) << 1;
567 const uint32_t __c1 = (__c / 100) << 1;
568 std::memcpy(_Mid -= 2, __DIGIT_TABLE + __c0, 2);
569 std::memcpy(_Mid -= 2, __DIGIT_TABLE + __c1, 2);
570 }
571 if (_Output >= 100) {
572 const uint32_t __c = (_Output % 100) << 1;
573 _Output /= 100;
574 std::memcpy(_Mid -= 2, __DIGIT_TABLE + __c, 2);
575 }
576 if (_Output >= 10) {
577 const uint32_t __c = _Output << 1;
578 std::memcpy(_Mid -= 2, __DIGIT_TABLE + __c, 2);
579 } else {
580 *--_Mid = static_cast<char>('0' + _Output);
581 }
582
583 if (_Ryu_exponent > 0) { // case "172900" with _Can_use_ryu
584 // Performance note: it might be more efficient to do this immediately after setting _Mid.
585 std::memset(_First + __olength, '0', static_cast<size_t>(_Ryu_exponent));
586 } else if (_Ryu_exponent == 0) { // case "1729"
587 // Done!
588 } else if (_Whole_digits > 0) { // case "17.29"
589 // Performance note: moving digits might not be optimal.
590 std::memmove(_First, _First + 1, static_cast<size_t>(_Whole_digits));
591 _First[_Whole_digits] = '.';
592 } else { // case "0.001729"
593 // Performance note: a larger memset() followed by overwriting '.' might be more efficient.
594 _First[0] = '0';
595 _First[1] = '.';
596 std::memset(_First + 2, '0', static_cast<size_t>(-_Whole_digits));
597 }
598
599 return { _First + _Total_fixed_length, errc{} };
600 }
601
602 const uint32_t _Total_scientific_length =
603 __olength + (__olength > 1) + 4; // digits + possible decimal point + scientific exponent
604 if (_Last - _First < static_cast<ptrdiff_t>(_Total_scientific_length)) {
605 return { _Last, errc::value_too_large };
606 }
607 char* const __result = _First;
608
609 // Print the decimal digits.
610 uint32_t __i = 0;
611 while (_Output >= 10000) {
612#ifdef __clang__ // TRANSITION, LLVM-38217
613 const uint32_t __c = _Output - 10000 * (_Output / 10000);
614#else
615 const uint32_t __c = _Output % 10000;
616#endif
617 _Output /= 10000;
618 const uint32_t __c0 = (__c % 100) << 1;
619 const uint32_t __c1 = (__c / 100) << 1;
620 std::memcpy(__result + __olength - __i - 1, __DIGIT_TABLE + __c0, 2);
621 std::memcpy(__result + __olength - __i - 3, __DIGIT_TABLE + __c1, 2);
622 __i += 4;
623 }
624 if (_Output >= 100) {
625 const uint32_t __c = (_Output % 100) << 1;
626 _Output /= 100;
627 std::memcpy(__result + __olength - __i - 1, __DIGIT_TABLE + __c, 2);
628 __i += 2;
629 }
630 if (_Output >= 10) {
631 const uint32_t __c = _Output << 1;
632 // We can't use memcpy here: the decimal dot goes between these two digits.
633 __result[2] = __DIGIT_TABLE[__c + 1];
634 __result[0] = __DIGIT_TABLE[__c];
635 } else {
636 __result[0] = static_cast<char>('0' + _Output);
637 }
638
639 // Print decimal point if needed.
640 uint32_t __index;
641 if (__olength > 1) {
642 __result[1] = '.';
643 __index = __olength + 1;
644 } else {
645 __index = 1;
646 }
647
648 // Print the exponent.
649 __result[__index++] = 'e';
650 if (_Scientific_exponent < 0) {
651 __result[__index++] = '-';
652 _Scientific_exponent = -_Scientific_exponent;
653 } else {
654 __result[__index++] = '+';
655 }
656
657 std::memcpy(__result + __index, __DIGIT_TABLE + 2 * _Scientific_exponent, 2);
658 __index += 2;
659
660 return { _First + _Total_scientific_length, errc{} };
661}
662
663[[nodiscard]] to_chars_result __f2s_buffered_n(char* const _First, char* const _Last, const float __f,
664 const chars_format _Fmt) {
665
666 // Step 1: Decode the floating-point number, and unify normalized and subnormal cases.
667 const uint32_t __bits = __float_to_bits(__f);
668
669 // Case distinction; exit early for the easy cases.
670 if (__bits == 0) {
671 if (_Fmt == chars_format::scientific) {
672 if (_Last - _First < 5) {
673 return { _Last, errc::value_too_large };
674 }
675
676 std::memcpy(_First, "0e+00", 5);
677
678 return { _First + 5, errc{} };
679 }
680
681 // Print "0" for chars_format::fixed, chars_format::general, and chars_format{}.
682 if (_First == _Last) {
683 return { _Last, errc::value_too_large };
684 }
685
686 *_First = '0';
687
688 return { _First + 1, errc{} };
689 }
690
691 // Decode __bits into mantissa and exponent.
692 const uint32_t __ieeeMantissa = __bits & ((1u << __FLOAT_MANTISSA_BITS) - 1);
693 const uint32_t __ieeeExponent = __bits >> __FLOAT_MANTISSA_BITS;
694
695 // When _Fmt == chars_format::fixed and the floating-point number is a large integer,
696 // it's faster to skip Ryu and immediately print the integer exactly.
697 if (_Fmt == chars_format::fixed) {
698 const uint32_t _Mantissa2 = __ieeeMantissa | (1u << __FLOAT_MANTISSA_BITS); // restore implicit bit
699 const int32_t _Exponent2 = static_cast<int32_t>(__ieeeExponent)
700 - __FLOAT_BIAS - __FLOAT_MANTISSA_BITS; // bias and normalization
701
702 // Normal values are equal to _Mantissa2 * 2^_Exponent2.
703 // (Subnormals are different, but they'll be rejected by the _Exponent2 test here, so they can be ignored.)
704
705 if (_Exponent2 > 0) {
706 return _Large_integer_to_chars(_First, _Last, _Mantissa2, _Exponent2);
707 }
708 }
709
710 const __floating_decimal_32 __v = __f2d(__ieeeMantissa, __ieeeExponent);
711 return __to_chars(_First, _Last, __v, _Fmt, __ieeeMantissa, __ieeeExponent);
712}
713
714_LIBCPP_END_NAMESPACE_STD
715
716// clang-format on
717