bignum.cc source code [qtbase/src/3rdparty/double-conversion/bignum.cc]

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27
28	#include <double-conversion/bignum.h>
29	#include <double-conversion/utils.h>
30
31	namespace double_conversion {
32
33	Bignum::Bignum()
34	: bigits_buffer_(), bigits_(bigits_buffer_, kBigitCapacity), used_digits_(`0`), exponent_(`0`) {
35	for (int i = `0`; i < kBigitCapacity; ++i) {
36	bigits_[i] = `0`;
37	}
38	}
39
40
41	template<typename S>
42	static int BitSize(S value) {
43	(void) value; // Mark variable as used.
44	return `8` * sizeof(value);
45	}
46
47	// Guaranteed to lie in one Bigit.
48	void Bignum::AssignUInt16(uint16_t value) {
49	ASSERT(kBigitSize >= BitSize(value));
50	Zero();
51	if (value == `0`) return;
52
53	EnsureCapacity(size: `1`);
54	bigits_[`0`] = value;
55	used_digits_ = `1`;
56	}
57
58
59	void Bignum::AssignUInt64(uint64_t value) {
60	const int kUInt64Size = `64`;
61
62	Zero();
63	if (value == `0`) return;
64
65	int needed_bigits = kUInt64Size / kBigitSize + `1`;
66	EnsureCapacity(size: needed_bigits);
67	for (int i = `0`; i < needed_bigits; ++i) {
68	bigits_[i] = value & kBigitMask;
69	value = value >> kBigitSize;
70	}
71	used_digits_ = needed_bigits;
72	Clamp();
73	}
74
75
76	void Bignum::AssignBignum(const Bignum& other) {
77	exponent_ = other.exponent_;
78	for (int i = `0`; i < other.used_digits_; ++i) {
79	bigits_[i] = other.bigits_[i];
80	}
81	// Clear the excess digits (if there were any).
82	for (int i = other.used_digits_; i < used_digits_; ++i) {
83	bigits_[i] = `0`;
84	}
85	used_digits_ = other.used_digits_;
86	}
87
88
89	static uint64_t ReadUInt64(Vector<const char> buffer,
90	int from,
91	int digits_to_read) {
92	uint64_t result = `0`;
93	for (int i = from; i < from + digits_to_read; ++i) {
94	int digit = buffer [i] - `'0'`;
95	ASSERT(`0` <= digit && digit <= `9`);
96	result = result * `10` + digit;
97	}
98	return result;
99	}
100
101
102	void Bignum::AssignDecimalString(Vector<const char> value) {
103	// 2^64 = 18446744073709551616 > 10^19
104	const int kMaxUint64DecimalDigits = `19`;
105	Zero();
106	int length = value.length();
107	unsigned int pos = `0`;
108	// Let's just say that each digit needs 4 bits.
109	while (length >= kMaxUint64DecimalDigits) {
110	uint64_t digits = ReadUInt64(buffer: value, from: pos, digits_to_read: kMaxUint64DecimalDigits);
111	pos += kMaxUint64DecimalDigits;
112	length -= kMaxUint64DecimalDigits;
113	MultiplyByPowerOfTen(exponent: kMaxUint64DecimalDigits);
114	AddUInt64(operand: digits);
115	}
116	uint64_t digits = ReadUInt64(buffer: value, from: pos, digits_to_read: length);
117	MultiplyByPowerOfTen(exponent: length);
118	AddUInt64(operand: digits);
119	Clamp();
120	}
121
122
123	static int HexCharValue(char c) {
124	if (`'0'` <= c && c <= `'9'`) return c - `'0'`;
125	if (`'a'` <= c && c <= `'f'`) return `10` + c - `'a'`;
126	ASSERT(`'A'` <= c && c <= `'F'`);
127	return `10` + c - `'A'`;
128	}
129
130
131	void Bignum::AssignHexString(Vector<const char> value) {
132	Zero();
133	int length = value.length();
134
135	int needed_bigits = length * `4` / kBigitSize + `1`;
136	EnsureCapacity(size: needed_bigits);
137	int string_index = length - `1`;
138	for (int i = `0`; i < needed_bigits - `1`; ++i) {
139	// These bigits are guaranteed to be "full".
140	Chunk current_bigit = `0`;
141	for (int j = `0`; j < kBigitSize / `4`; j++) {
142	current_bigit += HexCharValue(c: value [string_index--]) << (j * `4`);
143	}
144	bigits_[i] = current_bigit;
145	}
146	used_digits_ = needed_bigits - `1`;
147
148	Chunk most_significant_bigit = `0`; // Could be = 0;
149	for (int j = `0`; j <= string_index; ++j) {
150	most_significant_bigit <<= `4`;
151	most_significant_bigit += HexCharValue(c: value [j]);
152	}
153	if (most_significant_bigit != `0`) {
154	bigits_[used_digits_] = most_significant_bigit;
155	used_digits_++;
156	}
157	Clamp();
158	}
159
160
161	void Bignum::AddUInt64(uint64_t operand) {
162	if (operand == `0`) return;
163	Bignum other;
164	other.AssignUInt64(value: operand);
165	AddBignum(other);
166	}
167
168
169	void Bignum::AddBignum(const Bignum& other) {
170	ASSERT(IsClamped());
171	ASSERT(other.IsClamped());
172
173	// If this has a greater exponent than other append zero-bigits to this.
174	// After this call exponent_ <= other.exponent_.
175	Align(other);
176
177	// There are two possibilities:
178	// aaaaaaaaaaa 0000 (where the 0s represent a's exponent)
179	// bbbbb 00000000
180	// ----------------
181	// ccccccccccc 0000
182	// or
183	// aaaaaaaaaa 0000
184	// bbbbbbbbb 0000000
185	// -----------------
186	// cccccccccccc 0000
187	// In both cases we might need a carry bigit.
188
189	EnsureCapacity(size: `1` + Max(a: BigitLength(), b: other.BigitLength()) - exponent_);
190	Chunk carry = `0`;
191	int bigit_pos = other.exponent_ - exponent_;
192	ASSERT(bigit_pos >= `0`);
193	for (int i = `0`; i < other.used_digits_; ++i) {
194	Chunk sum = bigits_[bigit_pos] + other.bigits_[i] + carry;
195	bigits_[bigit_pos] = sum & kBigitMask;
196	carry = sum >> kBigitSize;
197	bigit_pos++;
198	}
199
200	while (carry != `0`) {
201	Chunk sum = bigits_[bigit_pos] + carry;
202	bigits_[bigit_pos] = sum & kBigitMask;
203	carry = sum >> kBigitSize;
204	bigit_pos++;
205	}
206	used_digits_ = Max(a: bigit_pos, b: used_digits_);
207	ASSERT(IsClamped());
208	}
209
210
211	void Bignum::SubtractBignum(const Bignum& other) {
212	ASSERT(IsClamped());
213	ASSERT(other.IsClamped());
214	// We require this to be bigger than other.
215	ASSERT(LessEqual(other, *this));
216
217	Align(other);
218
219	int offset = other.exponent_ - exponent_;
220	Chunk borrow = `0`;
221	int i;
222	for (i = `0`; i < other.used_digits_; ++i) {
223	ASSERT((borrow == `0`) \|\| (borrow == `1`));
224	Chunk difference = bigits_[i + offset] - other.bigits_[i] - borrow;
225	bigits_[i + offset] = difference & kBigitMask;
226	borrow = difference >> (kChunkSize - `1`);
227	}
228	while (borrow != `0`) {
229	Chunk difference = bigits_[i + offset] - borrow;
230	bigits_[i + offset] = difference & kBigitMask;
231	borrow = difference >> (kChunkSize - `1`);
232	++i;
233	}
234	Clamp();
235	}
236
237
238	void Bignum::ShiftLeft(int shift_amount) {
239	if (used_digits_ == `0`) return;
240	exponent_ += shift_amount / kBigitSize;
241	int local_shift = shift_amount % kBigitSize;
242	EnsureCapacity(size: used_digits_ + `1`);
243	BigitsShiftLeft(shift_amount: local_shift);
244	}
245
246
247	void Bignum::MultiplyByUInt32(uint32_t factor) {
248	if (factor == `1`) return;
249	if (factor == `0`) {
250	Zero();
251	return;
252	}
253	if (used_digits_ == `0`) return;
254
255	// The product of a bigit with the factor is of size kBigitSize + 32.
256	// Assert that this number + 1 (for the carry) fits into double chunk.
257	ASSERT(kDoubleChunkSize >= kBigitSize + `32` + `1`);
258	DoubleChunk carry = `0`;
259	for (int i = `0`; i < used_digits_; ++i) {
260	DoubleChunk product = static_cast<DoubleChunk>(factor) * bigits_[i] + carry;
261	bigits_[i] = static_cast<Chunk>(product & kBigitMask);
262	carry = (product >> kBigitSize);
263	}
264	while (carry != `0`) {
265	EnsureCapacity(size: used_digits_ + `1`);
266	bigits_[used_digits_] = carry & kBigitMask;
267	used_digits_++;
268	carry >>= kBigitSize;
269	}
270	}
271
272
273	void Bignum::MultiplyByUInt64(uint64_t factor) {
274	if (factor == `1`) return;
275	if (factor == `0`) {
276	Zero();
277	return;
278	}
279	ASSERT(kBigitSize < `32`);
280	uint64_t carry = `0`;
281	uint64_t low = factor & `0xFFFFFFFF`;
282	uint64_t high = factor >> `32`;
283	for (int i = `0`; i < used_digits_; ++i) {
284	uint64_t product_low = low * bigits_[i];
285	uint64_t product_high = high * bigits_[i];
286	uint64_t tmp = (carry & kBigitMask) + product_low;
287	bigits_[i] = tmp & kBigitMask;
288	carry = (carry >> kBigitSize) + (tmp >> kBigitSize) +
289	(product_high << (`32` - kBigitSize));
290	}
291	while (carry != `0`) {
292	EnsureCapacity(size: used_digits_ + `1`);
293	bigits_[used_digits_] = carry & kBigitMask;
294	used_digits_++;
295	carry >>= kBigitSize;
296	}
297	}
298
299
300	void Bignum::MultiplyByPowerOfTen(int exponent) {
301	const uint64_t kFive27 = UINT64_2PART_C(`0x6765c793`, fa10079d);
302	const uint16_t kFive1 = `5`;
303	const uint16_t kFive2 = kFive1 * `5`;
304	const uint16_t kFive3 = kFive2 * `5`;
305	const uint16_t kFive4 = kFive3 * `5`;
306	const uint16_t kFive5 = kFive4 * `5`;
307	const uint16_t kFive6 = kFive5 * `5`;
308	const uint32_t kFive7 = kFive6 * `5`;
309	const uint32_t kFive8 = kFive7 * `5`;
310	const uint32_t kFive9 = kFive8 * `5`;
311	const uint32_t kFive10 = kFive9 * `5`;
312	const uint32_t kFive11 = kFive10 * `5`;
313	const uint32_t kFive12 = kFive11 * `5`;
314	const uint32_t kFive13 = kFive12 * `5`;
315	const uint32_t kFive1_to_12[] =
316	{ kFive1, kFive2, kFive3, kFive4, kFive5, kFive6,
317	kFive7, kFive8, kFive9, kFive10, kFive11, kFive12 };
318
319	ASSERT(exponent >= `0`);
320	if (exponent == `0`) return;
321	if (used_digits_ == `0`) return;
322
323	// We shift by exponent at the end just before returning.
324	int remaining_exponent = exponent;
325	while (remaining_exponent >= `27`) {
326	MultiplyByUInt64(factor: kFive27);
327	remaining_exponent -= `27`;
328	}
329	while (remaining_exponent >= `13`) {
330	MultiplyByUInt32(factor: kFive13);
331	remaining_exponent -= `13`;
332	}
333	if (remaining_exponent > `0`) {
334	MultiplyByUInt32(factor: kFive1_to_12[remaining_exponent - `1`]);
335	}
336	ShiftLeft(shift_amount: exponent);
337	}
338
339
340	void Bignum::Square() {
341	ASSERT(IsClamped());
342	int product_length = `2` * used_digits_;
343	EnsureCapacity(size: product_length);
344
345	// Comba multiplication: compute each column separately.
346	// Example: r = a2a1a0 b2b1b0.*
347	// r = 1 a0b0 +*
348	// 10 (a1b0 + a0b1) +*
349	// 100 (a2b0 + a1b1 + a0b2) +*
350	// 1000 (a2b1 + a1b2) +*
351	// 10000 a2b2*
352	//
353	// In the worst case we have to accumulate nb-digits products of digitdigit.*
354	//
355	// Assert that the additional number of bits in a DoubleChunk are enough to
356	// sum up used_digits of BigitBigit.*
357	if ((`1` << (`2` * (kChunkSize - kBigitSize))) <= used_digits_) {
358	UNIMPLEMENTED();
359	}
360	DoubleChunk accumulator = `0`;
361	// First shift the digits so we don't overwrite them.
362	int copy_offset = used_digits_;
363	for (int i = `0`; i < used_digits_; ++i) {
364	bigits_[copy_offset + i] = bigits_[i];
365	}
366	// We have two loops to avoid some 'if's in the loop.
367	for (int i = `0`; i < used_digits_; ++i) {
368	// Process temporary digit i with power i.
369	// The sum of the two indices must be equal to i.
370	int bigit_index1 = i;
371	int bigit_index2 = `0`;
372	// Sum all of the sub-products.
373	while (bigit_index1 >= `0`) {
374	Chunk chunk1 = bigits_[copy_offset + bigit_index1];
375	Chunk chunk2 = bigits_[copy_offset + bigit_index2];
376	accumulator += static_cast<DoubleChunk>(chunk1) * chunk2;
377	bigit_index1--;
378	bigit_index2++;
379	}
380	bigits_[i] = static_cast<Chunk>(accumulator) & kBigitMask;
381	accumulator >>= kBigitSize;
382	}
383	for (int i = used_digits_; i < product_length; ++i) {
384	int bigit_index1 = used_digits_ - `1`;
385	int bigit_index2 = i - bigit_index1;
386	// Invariant: sum of both indices is again equal to i.
387	// Inner loop runs 0 times on last iteration, emptying accumulator.
388	while (bigit_index2 < used_digits_) {
389	Chunk chunk1 = bigits_[copy_offset + bigit_index1];
390	Chunk chunk2 = bigits_[copy_offset + bigit_index2];
391	accumulator += static_cast<DoubleChunk>(chunk1) * chunk2;
392	bigit_index1--;
393	bigit_index2++;
394	}
395	// The overwritten bigits_[i] will never be read in further loop iterations,
396	// because bigit_index1 and bigit_index2 are always greater
397	// than i - used_digits_.
398	bigits_[i] = static_cast<Chunk>(accumulator) & kBigitMask;
399	accumulator >>= kBigitSize;
400	}
401	// Since the result was guaranteed to lie inside the number the
402	// accumulator must be 0 now.
403	ASSERT(accumulator == `0`);
404
405	// Don't forget to update the used_digits and the exponent.
406	used_digits_ = product_length;
407	exponent_ *= `2`;
408	Clamp();
409	}
410
411
412	void Bignum::AssignPowerUInt16(uint16_t base, int power_exponent) {
413	ASSERT(base != `0`);
414	ASSERT(power_exponent >= `0`);
415	if (power_exponent == `0`) {
416	AssignUInt16(value: `1`);
417	return;
418	}
419	Zero();
420	int shifts = `0`;
421	// We expect base to be in range 2-32, and most often to be 10.
422	// It does not make much sense to implement different algorithms for counting
423	// the bits.
424	while ((base & `1`) == `0`) {
425	base >>= `1`;
426	shifts++;
427	}
428	int bit_size = `0`;
429	int tmp_base = base;
430	while (tmp_base != `0`) {
431	tmp_base >>= `1`;
432	bit_size++;
433	}
434	int final_size = bit_size * power_exponent;
435	// 1 extra bigit for the shifting, and one for rounded final_size.
436	EnsureCapacity(size: final_size / kBigitSize + `2`);
437
438	// Left to Right exponentiation.
439	int mask = `1`;
440	while (power_exponent >= mask) mask <<= `1`;
441
442	// The mask is now pointing to the bit above the most significant 1-bit of
443	// power_exponent.
444	// Get rid of first 1-bit;
445	mask >>= `2`;
446	uint64_t this_value = base;
447
448	bool delayed_multiplication = false;
449	const uint64_t max_32bits = `0xFFFFFFFF`;
450	while (mask != `0` && this_value <= max_32bits) {
451	this_value = this_value * this_value;
452	// Verify that there is enough space in this_value to perform the
453	// multiplication. The first bit_size bits must be 0.
454	if ((power_exponent & mask) != `0`) {
455	ASSERT(bit_size > `0`);
456	uint64_t base_bits_mask =
457	~((static_cast<uint64_t>(`1`) << (`64` - bit_size)) - `1`);
458	bool high_bits_zero = (this_value & base_bits_mask) == `0`;
459	if (high_bits_zero) {
460	this_value *= base;
461	} else {
462	delayed_multiplication = true;
463	}
464	}
465	mask >>= `1`;
466	}
467	AssignUInt64(value: this_value);
468	if (delayed_multiplication) {
469	MultiplyByUInt32(factor: base);
470	}
471
472	// Now do the same thing as a bignum.
473	while (mask != `0`) {
474	Square();
475	if ((power_exponent & mask) != `0`) {
476	MultiplyByUInt32(factor: base);
477	}
478	mask >>= `1`;
479	}
480
481	// And finally add the saved shifts.
482	ShiftLeft(shift_amount: shifts * power_exponent);
483	}
484
485
486	// Precondition: this/other < 16bit.
487	uint16_t Bignum::DivideModuloIntBignum(const Bignum& other) {
488	ASSERT(IsClamped());
489	ASSERT(other.IsClamped());
490	ASSERT(other.used_digits_ > `0`);
491
492	// Easy case: if we have less digits than the divisor than the result is 0.
493	// Note: this handles the case where this == 0, too.
494	if (BigitLength() < other.BigitLength()) {
495	return `0`;
496	}
497
498	Align(other);
499
500	uint16_t result = `0`;
501
502	// Start by removing multiples of 'other' until both numbers have the same
503	// number of digits.
504	while (BigitLength() > other.BigitLength()) {
505	// This naive approach is extremely inefficient if `this` divided by other
506	// is big. This function is implemented for doubleToString where
507	// the result should be small (less than 10).
508	ASSERT(other.bigits_[other.used_digits_ - `1`] >= ((`1` << kBigitSize) / `16`));
509	ASSERT(bigits_[used_digits_ - `1`] < `0x10000`);
510	// Remove the multiples of the first digit.
511	// Example this = 23 and other equals 9. -> Remove 2 multiples.
512	result += static_cast<uint16_t>(bigits_[used_digits_ - `1`]);
513	SubtractTimes(other, factor: bigits_[used_digits_ - `1`]);
514	}
515
516	ASSERT(BigitLength() == other.BigitLength());
517
518	// Both bignums are at the same length now.
519	// Since other has more than 0 digits we know that the access to
520	// bigits_[used_digits_ - 1] is safe.
521	Chunk this_bigit = bigits_[used_digits_ - `1`];
522	Chunk other_bigit = other.bigits_[other.used_digits_ - `1`];
523
524	if (other.used_digits_ == `1`) {
525	// Shortcut for easy (and common) case.
526	int quotient = this_bigit / other_bigit;
527	bigits_[used_digits_ - `1`] = this_bigit - other_bigit * quotient;
528	ASSERT(quotient < `0x10000`);
529	result += static_cast<uint16_t>(quotient);
530	Clamp();
531	return result;
532	}
533
534	int division_estimate = this_bigit / (other_bigit + `1`);
535	ASSERT(division_estimate < `0x10000`);
536	result += static_cast<uint16_t>(division_estimate);
537	SubtractTimes(other, factor: division_estimate);
538
539	if (other_bigit * (division_estimate + `1`) > this_bigit) {
540	// No need to even try to subtract. Even if other's remaining digits were 0
541	// another subtraction would be too much.
542	return result;
543	}
544
545	while (LessEqual(a: other, b: *this)) {
546	SubtractBignum(other);
547	result++;
548	}
549	return result;
550	}
551
552
553	template<typename S>
554	static int SizeInHexChars(S number) {
555	ASSERT(number > `0`);
556	int result = `0`;
557	while (number != `0`) {
558	number >>= `4`;
559	result++;
560	}
561	return result;
562	}
563
564
565	static char HexCharOfValue(int value) {
566	ASSERT(`0` <= value && value <= `16`);
567	if (value < `10`) return static_cast<char>(value + `'0'`);
568	return static_cast<char>(value - `10` + `'A'`);
569	}
570
571
572	bool Bignum::ToHexString(char* buffer, int buffer_size) const {
573	ASSERT(IsClamped());
574	// Each bigit must be printable as separate hex-character.
575	ASSERT(kBigitSize % `4` == `0`);
576	const int kHexCharsPerBigit = kBigitSize / `4`;
577
578	if (used_digits_ == `0`) {
579	if (buffer_size < `2`) return false;
580	buffer[`0`] = `'0'`;
581	buffer[`1`] = `'\0'`;
582	return true;
583	}
584	// We add 1 for the terminating '\0' character.
585	int needed_chars = (BigitLength() - `1`) * kHexCharsPerBigit +
586	SizeInHexChars(number: bigits_[used_digits_ - `1`]) + `1`;
587	if (needed_chars > buffer_size) return false;
588	int string_index = needed_chars - `1`;
589	buffer[string_index--] = `'\0'`;
590	for (int i = `0`; i < exponent_; ++i) {
591	for (int j = `0`; j < kHexCharsPerBigit; ++j) {
592	buffer[string_index--] = `'0'`;
593	}
594	}
595	for (int i = `0`; i < used_digits_ - `1`; ++i) {
596	Chunk current_bigit = bigits_[i];
597	for (int j = `0`; j < kHexCharsPerBigit; ++j) {
598	buffer[string_index--] = HexCharOfValue(value: current_bigit & `0xF`);
599	current_bigit >>= `4`;
600	}
601	}
602	// And finally the last bigit.
603	Chunk most_significant_bigit = bigits_[used_digits_ - `1`];
604	while (most_significant_bigit != `0`) {
605	buffer[string_index--] = HexCharOfValue(value: most_significant_bigit & `0xF`);
606	most_significant_bigit >>= `4`;
607	}
608	return true;
609	}
610
611
612	Bignum::Chunk Bignum::BigitAt(int index) const {
613	if (index >= BigitLength()) return `0`;
614	if (index < exponent_) return `0`;
615	return bigits_[index - exponent_];
616	}
617
618
619	int Bignum::Compare(const Bignum& a, const Bignum& b) {
620	ASSERT(a.IsClamped());
621	ASSERT(b.IsClamped());
622	int bigit_length_a = a.BigitLength();
623	int bigit_length_b = b.BigitLength();
624	if (bigit_length_a < bigit_length_b) return -`1`;
625	if (bigit_length_a > bigit_length_b) return +`1`;
626	for (int i = bigit_length_a - `1`; i >= Min(a: a.exponent_, b: b.exponent_); --i) {
627	Chunk bigit_a = a.BigitAt(index: i);
628	Chunk bigit_b = b.BigitAt(index: i);
629	if (bigit_a < bigit_b) return -`1`;
630	if (bigit_a > bigit_b) return +`1`;
631	// Otherwise they are equal up to this digit. Try the next digit.
632	}
633	return `0`;
634	}
635
636
637	int Bignum::PlusCompare(const Bignum& a, const Bignum& b, const Bignum& c) {
638	ASSERT(a.IsClamped());
639	ASSERT(b.IsClamped());
640	ASSERT(c.IsClamped());
641	if (a.BigitLength() < b.BigitLength()) {
642	return PlusCompare(a: b, b: a, c);
643	}
644	if (a.BigitLength() + `1` < c.BigitLength()) return -`1`;
645	if (a.BigitLength() > c.BigitLength()) return +`1`;
646	// The exponent encodes 0-bigits. So if there are more 0-digits in 'a' than
647	// 'b' has digits, then the bigit-length of 'a'+'b' must be equal to the one
648	// of 'a'.
649	if (a.exponent_ >= b.BigitLength() && a.BigitLength() < c.BigitLength()) {
650	return -`1`;
651	}
652
653	Chunk borrow = `0`;
654	// Starting at min_exponent all digits are == 0. So no need to compare them.
655	int min_exponent = Min(a: Min(a: a.exponent_, b: b.exponent_), b: c.exponent_);
656	for (int i = c.BigitLength() - `1`; i >= min_exponent; --i) {
657	Chunk chunk_a = a.BigitAt(index: i);
658	Chunk chunk_b = b.BigitAt(index: i);
659	Chunk chunk_c = c.BigitAt(index: i);
660	Chunk sum = chunk_a + chunk_b;
661	if (sum > chunk_c + borrow) {
662	return +`1`;
663	} else {
664	borrow = chunk_c + borrow - sum;
665	if (borrow > `1`) return -`1`;
666	borrow <<= kBigitSize;
667	}
668	}
669	if (borrow == `0`) return `0`;
670	return -`1`;
671	}
672
673
674	void Bignum::Clamp() {
675	while (used_digits_ > `0` && bigits_[used_digits_ - `1`] == `0`) {
676	used_digits_--;
677	}
678	if (used_digits_ == `0`) {
679	// Zero.
680	exponent_ = `0`;
681	}
682	}
683
684
685	bool Bignum::IsClamped() const {
686	return used_digits_ == `0` \|\| bigits_[used_digits_ - `1`] != `0`;
687	}
688
689
690	void Bignum::Zero() {
691	for (int i = `0`; i < used_digits_; ++i) {
692	bigits_[i] = `0`;
693	}
694	used_digits_ = `0`;
695	exponent_ = `0`;
696	}
697
698
699	void Bignum::Align(const Bignum& other) {
700	if (exponent_ > other.exponent_) {
701	// If "X" represents a "hidden" digit (by the exponent) then we are in the
702	// following case (a == this, b == other):
703	// a: aaaaaaXXXX or a: aaaaaXXX
704	// b: bbbbbbX b: bbbbbbbbXX
705	// We replace some of the hidden digits (X) of a with 0 digits.
706	// a: aaaaaa000X or a: aaaaa0XX
707	int zero_digits = exponent_ - other.exponent_;
708	EnsureCapacity(size: used_digits_ + zero_digits);
709	for (int i = used_digits_ - `1`; i >= `0`; --i) {
710	bigits_[i + zero_digits] = bigits_[i];
711	}
712	for (int i = `0`; i < zero_digits; ++i) {
713	bigits_[i] = `0`;
714	}
715	used_digits_ += zero_digits;
716	exponent_ -= zero_digits;
717	ASSERT(used_digits_ >= `0`);
718	ASSERT(exponent_ >= `0`);
719	}
720	}
721
722
723	void Bignum::BigitsShiftLeft(int shift_amount) {
724	ASSERT(shift_amount < kBigitSize);
725	ASSERT(shift_amount >= `0`);
726	Chunk carry = `0`;
727	for (int i = `0`; i < used_digits_; ++i) {
728	Chunk new_carry = bigits_[i] >> (kBigitSize - shift_amount);
729	bigits_[i] = ((bigits_[i] << shift_amount) + carry) & kBigitMask;
730	carry = new_carry;
731	}
732	if (carry != `0`) {
733	bigits_[used_digits_] = carry;
734	used_digits_++;
735	}
736	}
737
738
739	void Bignum::SubtractTimes(const Bignum& other, int factor) {
740	ASSERT(exponent_ <= other.exponent_);
741	if (factor < `3`) {
742	for (int i = `0`; i < factor; ++i) {
743	SubtractBignum(other);
744	}
745	return;
746	}
747	Chunk borrow = `0`;
748	int exponent_diff = other.exponent_ - exponent_;
749	for (int i = `0`; i < other.used_digits_; ++i) {
750	DoubleChunk product = static_cast<DoubleChunk>(factor) * other.bigits_[i];
751	DoubleChunk remove = borrow + product;
752	Chunk difference = bigits_[i + exponent_diff] - (remove & kBigitMask);
753	bigits_[i + exponent_diff] = difference & kBigitMask;
754	borrow = static_cast<Chunk>((difference >> (kChunkSize - `1`)) +
755	(remove >> kBigitSize));
756	}
757	for (int i = other.used_digits_ + exponent_diff; i < used_digits_; ++i) {
758	if (borrow == `0`) return;
759	Chunk difference = bigits_[i] - borrow;
760	bigits_[i] = difference & kBigitMask;
761	borrow = difference >> (kChunkSize - `1`);
762	}
763	Clamp();
764	}
765
766
767	} // namespace double_conversion
768

source code of qtbase/src/3rdparty/double-conversion/bignum.cc