qmath.h source code [qtbase/src/corelib/kernel/qmath.h]

1	// Copyright (C) 2021 The Qt Company Ltd.
2	// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR LGPL-3.0-only OR GPL-2.0-only OR GPL-3.0-only
3
4	#ifndef QMATH_H
5	#define QMATH_H
6
7	#if 0
8	#pragma qt_class(QtMath)
9	#endif
10
11	#include <QtCore/qglobal.h>
12	#include <QtCore/qalgorithms.h>
13
14	#if __has_include(<bit>) && __cplusplus > 201703L
15	#include <bit>
16	#endif
17
18	#ifndef _USE_MATH_DEFINES
19	# define _USE_MATH_DEFINES
20	# define undef_USE_MATH_DEFINES
21	#endif
22
23	#include <cmath>
24
25	#ifdef undef_USE_MATH_DEFINES
26	# undef _USE_MATH_DEFINES
27	# undef undef_USE_MATH_DEFINES
28	#endif
29
30	QT_BEGIN_NAMESPACE
31
32	#define QT_SINE_TABLE_SIZE 256
33
34	extern Q_CORE_EXPORT const qreal qt_sine_table[QT_SINE_TABLE_SIZE];
35
36	template <typename T> int qCeil(T v)
37	{
38	using std::ceil;
39	return int(ceil(v));
40	}
41
42	template <typename T> int qFloor(T v)
43	{
44	using std::floor;
45	return int(floor(v));
46	}
47
48	template <typename T> auto qFabs(T v)
49	{
50	using std::fabs;
51	return fabs(v);
52	}
53
54	template <typename T> auto qSin(T v)
55	{
56	using std::sin;
57	return sin(v);
58	}
59
60	template <typename T> auto qCos(T v)
61	{
62	using std::cos;
63	return cos(v);
64	}
65
66	template <typename T> auto qTan(T v)
67	{
68	using std::tan;
69	return tan(v);
70	}
71
72	template <typename T> auto qAcos(T v)
73	{
74	using std::acos;
75	return acos(v);
76	}
77
78	template <typename T> auto qAsin(T v)
79	{
80	using std::asin;
81	return asin(v);
82	}
83
84	template <typename T> auto qAtan(T v)
85	{
86	using std::atan;
87	return atan(v);
88	}
89
90	template <typename T1, typename T2> auto qAtan2(T1 y, T2 x)
91	{
92	using std::atan2;
93	return atan2(y, x);
94	}
95
96	template <typename T> auto qSqrt(T v)
97	{
98	using std::sqrt;
99	return sqrt(v);
100	}
101
102	namespace QtPrivate {
103	template <typename R, typename F> // For qfloat16 to specialize
104	struct QHypotType { using type = decltype(std::hypot(R(`1`), F(`1`))); };
105
106	// Implements hypot() without limiting number of arguments:
107	template <typename T>
108	class QHypotHelper
109	{
110	T scale, total;
111	template <typename F> friend class QHypotHelper;
112	QHypotHelper(T first, T prior) : scale(first), total(prior) {}
113	public:
114	QHypotHelper(T first) : scale(qAbs(first)), total(`1`) {}
115	T result() const
116	{ return qIsFinite(scale) ? scale > `0` ? scale * T(qSqrt(total)) : T(`0`) : scale; }
117
118	template<typename F, typename ...Fs>
119	auto add(F first, Fs... rest) const
120	{ return add(first).add(rest...); }
121
122	template<typename F, typename R = typename QHypotType<T, F>::type>
123	QHypotHelper<R> add(F next) const
124	{
125	if (qIsInf(scale) \|\| (qIsNaN(scale) && !qIsInf(next)))
126	return QHypotHelper<R>(scale, R(`1`));
127	if (qIsNaN(next))
128	return QHypotHelper<R>(next, R(`1`));
129	const R val = qAbs(next);
130	if (!(scale > `0`) \|\| qIsInf(next))
131	return QHypotHelper<R>(val, R(`1`));
132	if (!(val > `0`))
133	return QHypotHelper<R>(scale, total);
134	if (val > scale) {
135	const R ratio = scale / next;
136	return QHypotHelper<R>(val, total * ratio * ratio + R(`1`));
137	}
138	const R ratio = next / scale;
139	return QHypotHelper<R>(scale, total + ratio * ratio);
140	}
141	};
142	} // QtPrivate
143
144	template<typename F, typename ...Fs>
145	auto qHypot(F first, Fs... rest)
146	{
147	return QtPrivate::QHypotHelper<F>(first).add(rest...).result();
148	}
149
150	// However, where possible, use the standard library implementations:
151	template <typename Tx, typename Ty>
152	auto qHypot(Tx x, Ty y)
153	{
154	// C99 has hypot(), hence C++11 has std::hypot()
155	using std::hypot;
156	return hypot(x, y);
157	}
158
159	#if defined(__cpp_lib_hypot) && __cpp_lib_hypot >= 201603L // Expected to be true
160	template <typename Tx, typename Ty, typename Tz>
161	auto qHypot(Tx x, Ty y, Tz z)
162	{
163	using std::hypot;
164	return hypot(x, y, z);
165	}
166	#endif // else: no need to over-ride the arbitrarily-many-arg form
167
168	template <typename T> auto qLn(T v)
169	{
170	using std::log;
171	return log(v);
172	}
173
174	template <typename T> auto qExp(T v)
175	{
176	using std::exp;
177	return exp(v);
178	}
179
180	template <typename T1, typename T2> auto qPow(T1 x, T2 y)
181	{
182	using std::pow;
183	return pow(x, y);
184	}
185
186	// TODO: use template variables (e.g. Qt::pi<type>) for these once we have C++14 support:
187
188	#ifndef M_E
189	#define M_E (2.7182818284590452354)
190	#endif
191
192	#ifndef M_LOG2E
193	#define M_LOG2E (1.4426950408889634074)
194	#endif
195
196	#ifndef M_LOG10E
197	#define M_LOG10E (0.43429448190325182765)
198	#endif
199
200	#ifndef M_LN2
201	#define M_LN2 (0.69314718055994530942)
202	#endif
203
204	#ifndef M_LN10
205	#define M_LN10 (2.30258509299404568402)
206	#endif
207
208	#ifndef M_PI
209	#define M_PI (3.14159265358979323846)
210	#endif
211
212	#ifndef M_PI_2
213	#define M_PI_2 (1.57079632679489661923)
214	#endif
215
216	#ifndef M_PI_4
217	#define M_PI_4 (0.78539816339744830962)
218	#endif
219
220	#ifndef M_1_PI
221	#define M_1_PI (0.31830988618379067154)
222	#endif
223
224	#ifndef M_2_PI
225	#define M_2_PI (0.63661977236758134308)
226	#endif
227
228	#ifndef M_2_SQRTPI
229	#define M_2_SQRTPI (1.12837916709551257390)
230	#endif
231
232	#ifndef M_SQRT2
233	#define M_SQRT2 (1.41421356237309504880)
234	#endif
235
236	#ifndef M_SQRT1_2
237	#define M_SQRT1_2 (0.70710678118654752440)
238	#endif
239
240	inline qreal qFastSin(qreal x)
241	{
242	int si = int(x * (`0.5` * QT_SINE_TABLE_SIZE / M_PI)); // Would be more accurate with qRound, but slower.
243	qreal d = x - si * (`2.0` * M_PI / QT_SINE_TABLE_SIZE);
244	int ci = si + QT_SINE_TABLE_SIZE / `4`;
245	si &= QT_SINE_TABLE_SIZE - `1`;
246	ci &= QT_SINE_TABLE_SIZE - `1`;
247	return qt_sine_table[si] + (qt_sine_table[ci] - `0.5` * qt_sine_table[si] * d) * d;
248	}
249
250	inline qreal qFastCos(qreal x)
251	{
252	int ci = int(x * (`0.5` * QT_SINE_TABLE_SIZE / M_PI)); // Would be more accurate with qRound, but slower.
253	qreal d = x - ci * (`2.0` * M_PI / QT_SINE_TABLE_SIZE);
254	int si = ci + QT_SINE_TABLE_SIZE / `4`;
255	si &= QT_SINE_TABLE_SIZE - `1`;
256	ci &= QT_SINE_TABLE_SIZE - `1`;
257	return qt_sine_table[si] - (qt_sine_table[ci] + `0.5` * qt_sine_table[si] * d) * d;
258	}
259
260	constexpr inline float qDegreesToRadians(float degrees)
261	{
262	return degrees * float(M_PI / `180`);
263	}
264
265	constexpr inline double qDegreesToRadians(double degrees)
266	{
267	return degrees * (M_PI / `180`);
268	}
269
270	constexpr inline long double qDegreesToRadians(long double degrees)
271	{
272	return degrees * (M_PI / `180`);
273	}
274
275	template <typename T, std::enable_if_t<std::is_integral_v<T>, bool> = true>
276	constexpr inline double qDegreesToRadians(T degrees)
277	{
278	return qDegreesToRadians(degrees: static_cast<double>(degrees));
279	}
280
281	constexpr inline float qRadiansToDegrees(float radians)
282	{
283	return radians * float(`180` / M_PI);
284	}
285
286	constexpr inline double qRadiansToDegrees(double radians)
287	{
288	return radians * (`180` / M_PI);
289	}
290
291	constexpr inline long double qRadiansToDegrees(long double radians)
292	{
293	return radians * (`180` / M_PI);
294	}
295
296	// A qRadiansToDegrees(Integral) overload isn't here; it's extremely
297	// questionable that someone is manipulating quantities in radians
298	// using integral datatypes...
299
300	namespace QtPrivate {
301	constexpr inline quint32 qConstexprNextPowerOfTwo(quint32 v)
302	{
303	v \|= v >> `1`;
304	v \|= v >> `2`;
305	v \|= v >> `4`;
306	v \|= v >> `8`;
307	v \|= v >> `16`;
308	++v;
309	return v;
310	}
311
312	constexpr inline quint64 qConstexprNextPowerOfTwo(quint64 v)
313	{
314	v \|= v >> `1`;
315	v \|= v >> `2`;
316	v \|= v >> `4`;
317	v \|= v >> `8`;
318	v \|= v >> `16`;
319	v \|= v >> `32`;
320	++v;
321	return v;
322	}
323
324	constexpr inline quint32 qConstexprNextPowerOfTwo(qint32 v)
325	{
326	return qConstexprNextPowerOfTwo(v: quint32(v));
327	}
328
329	constexpr inline quint64 qConstexprNextPowerOfTwo(qint64 v)
330	{
331	return qConstexprNextPowerOfTwo(v: quint64(v));
332	}
333	} // namespace QtPrivate
334
335	constexpr inline quint32 qNextPowerOfTwo(quint32 v)
336	{
337	Q_ASSERT(static_cast<qint32>(v) >= `0`); // There is a next power of two
338	#if defined(__cpp_lib_int_pow2) && __cpp_lib_int_pow2 >= 202002L
339	return std::bit_ceil(v + `1`);
340	#elif defined(QT_HAS_BUILTIN_CLZ)
341	if (v == `0`)
342	return `1`;
343	return `2U` << (`31` ^ QAlgorithmsPrivate::qt_builtin_clz(v));
344	#else
345	return QtPrivate::qConstexprNextPowerOfTwo(v);
346	#endif
347	}
348
349	constexpr inline quint64 qNextPowerOfTwo(quint64 v)
350	{
351	Q_ASSERT(static_cast<qint64>(v) >= `0`); // There is a next power of two
352	#if defined(__cpp_lib_int_pow2) && __cpp_lib_int_pow2 >= 202002L
353	return std::bit_ceil(v + `1`);
354	#elif defined(QT_HAS_BUILTIN_CLZLL)
355	if (v == `0`)
356	return `1`;
357	return Q_UINT64_C(`2`) << (`63` ^ QAlgorithmsPrivate::qt_builtin_clzll(v));
358	#else
359	return QtPrivate::qConstexprNextPowerOfTwo(v);
360	#endif
361	}
362
363	constexpr inline quint32 qNextPowerOfTwo(qint32 v)
364	{
365	return qNextPowerOfTwo(v: quint32(v));
366	}
367
368	constexpr inline quint64 qNextPowerOfTwo(qint64 v)
369	{
370	return qNextPowerOfTwo(v: quint64(v));
371	}
372
373	constexpr inline unsigned long qNextPowerOfTwo(unsigned long v)
374	{
375	return qNextPowerOfTwo(v: QIntegerForSizeof<long>::Unsigned(v));
376	}
377
378	constexpr inline unsigned long qNextPowerOfTwo(long v)
379	{
380	return qNextPowerOfTwo(v: QIntegerForSizeof<long>::Unsigned(v));
381	}
382
383	QT_END_NAMESPACE
384
385	#endif // QMATH_H
386

source code of qtbase/src/corelib/kernel/qmath.h