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36 int64_t num, int64_t den, int64_t
max)
39 int sign = (num < 0) ^ (den < 0);
43 num =
FFABS(num) / gcd;
44 den =
FFABS(den) / gcd;
46 if (num <=
max && den <=
max) {
52 uint64_t x = num / den;
53 int64_t next_den = num - den * x;
54 int64_t a2n = x *
a1.num +
a0.num;
55 int64_t a2d = x *
a1.den +
a0.den;
57 if (a2n >
max || a2d >
max) {
61 if (den * (2 * x *
a1.den +
a0.den) > num *
a1.den)
74 *dst_num = sign ? -
a1.num :
a1.num;
83 b.num * (int64_t)
c.num,
84 b.den * (int64_t)
c.den, INT_MAX);
95 b.num * (int64_t)
c.den +
96 c.num * (int64_t)
b.den,
97 b.den * (int64_t)
c.den, INT_MAX);
113 if (fabs(d) > INT_MAX + 3LL)
116 exponent =
FFMAX(exponent-1, 0);
117 den = 1LL << (61 - exponent);
121 if ((!
a.num || !
a.den) && d &&
max>0 &&
max<INT_MAX)
122 av_reduce(&
a.num, &
a.den, floor(d * den + 0.5), den, INT_MAX);
130 int64_t
a =
q1.num * (int64_t)q2.
den + q2.
num * (int64_t)
q1.den;
131 int64_t
b = 2 * (int64_t)
q1.den * q2.
den;
144 int i, nearest_q_idx = 0;
145 for (
i = 0; q_list[
i].
den;
i++)
146 if (
av_nearer_q(q, q_list[
i], q_list[nearest_q_idx]) > 0)
149 return nearest_q_idx;
166 if (!q.
num && !q.
den)
return 0xFFC00000;
167 if (!q.
num)
return 0;
168 if (!q.
den)
return 0x7F800000 | (q.
num & 0x80000000);
183 return sign<<31 | (150-
shift)<<23 | (
n - (1<<23));
static const uint8_t q1[256]
AVRational av_div_q(AVRational b, AVRational c)
Divide one rational by another.
AVRational av_sub_q(AVRational b, AVRational c)
Subtract one rational from another.
int64_t av_gcd(int64_t a, int64_t b)
Compute the greatest common divisor of two integer operands.
uint32_t av_q2intfloat(AVRational q)
Convert an AVRational to a IEEE 32-bit float expressed in fixed-point format.
@ AV_ROUND_UP
Round toward +infinity.
int av_reduce(int *dst_num, int *dst_den, int64_t num, int64_t den, int64_t max)
Reduce a fraction.
#define FFABS(a)
Absolute value, Note, INT_MIN / INT64_MIN result in undefined behavior as they are not representable ...
Rational number (pair of numerator and denominator).
Undefined Behavior In the C some operations are like signed integer dereferencing freed accessing outside allocated Undefined Behavior must not occur in a C it is not safe even if the output of undefined operations is unused The unsafety may seem nit picking but Optimizing compilers have in fact optimized code on the assumption that no undefined Behavior occurs Optimizing code based on wrong assumptions can and has in some cases lead to effects beyond the output of computations The signed integer overflow problem in speed critical code Code which is highly optimized and works with signed integers sometimes has the problem that often the output of the computation does not c
int64_t av_rescale_rnd(int64_t a, int64_t b, int64_t c, enum AVRounding rnd)
Rescale a 64-bit integer with specified rounding.
The reader does not expect b to be semantically here and if the code is changed by maybe adding a a division or other the signedness will almost certainly be mistaken To avoid this confusion a new type was SUINT is the C unsigned type but it holds a signed int to use the same example SUINT a
int av_find_nearest_q_idx(AVRational q, const AVRational *q_list)
Find the value in a list of rationals nearest a given reference rational.
#define av_assert2(cond)
assert() equivalent, that does lie in speed critical code.
#define i(width, name, range_min, range_max)
#define av_assert1(cond)
assert() equivalent, that does not lie in speed critical code.
@ AV_ROUND_DOWN
Round toward -infinity.
AVRational av_d2q(double d, int max)
Convert a double precision floating point number to a rational.
int64_t av_rescale(int64_t a, int64_t b, int64_t c)
Rescale a 64-bit integer with rounding to nearest.
static int av_cmp_q(AVRational a, AVRational b)
Compare two rationals.
AVRational av_mul_q(AVRational b, AVRational c)
Multiply two rationals.
static int shift(int a, int b)
int av_nearer_q(AVRational q, AVRational q1, AVRational q2)
Find which of the two rationals is closer to another rational.
AVRational av_add_q(AVRational b, AVRational c)
Add two rationals.