2015-05-24 06:55:12 +02:00
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// Copyright 2008 Dolphin Emulator Project
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2021-07-05 03:22:19 +02:00
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// SPDX-License-Identifier: GPL-2.0-or-later
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2008-12-08 05:46:09 +01:00
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2014-02-10 19:54:46 +01:00
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#pragma once
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2008-12-08 05:46:09 +01:00
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2015-09-12 05:43:17 +02:00
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#include <algorithm>
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2022-10-10 11:03:15 +02:00
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#include <bit>
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2020-02-13 02:15:02 +01:00
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#include <cmath>
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2021-01-28 12:45:50 +01:00
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#include <limits>
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2020-04-29 00:48:13 +02:00
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#include <type_traits>
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2014-02-17 11:18:15 +01:00
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2014-09-08 03:06:58 +02:00
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#include "Common/CommonTypes.h"
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2009-07-12 23:58:32 +02:00
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2009-06-14 12:59:06 +02:00
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namespace MathUtil
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{
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2018-12-19 03:06:16 +01:00
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constexpr double TAU = 6.2831853071795865;
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constexpr double PI = TAU / 2;
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2019-11-09 01:23:22 +01:00
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constexpr double GRAVITY_ACCELERATION = 9.80665;
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2018-12-19 03:06:16 +01:00
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2019-04-07 14:57:04 +02:00
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template <typename T>
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constexpr auto Sign(const T& val) -> decltype((T{} < val) - (val < T{}))
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{
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return (T{} < val) - (val < T{});
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}
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template <typename T, typename F>
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constexpr auto Lerp(const T& x, const T& y, const F& a) -> decltype(x + (y - x) * a)
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{
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return x + (y - x) * a;
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}
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2021-01-28 12:45:50 +01:00
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// Casts the specified value to a Dest. The value will be clamped to fit in the destination type.
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// Warning: The result of SaturatingCast(NaN) is undefined.
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template <typename Dest, typename T>
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constexpr Dest SaturatingCast(T value)
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{
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static_assert(std::is_integral<Dest>());
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2022-01-17 08:32:27 +01:00
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[[maybe_unused]] constexpr Dest lo = std::numeric_limits<Dest>::lowest();
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2021-01-28 12:45:50 +01:00
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constexpr Dest hi = std::numeric_limits<Dest>::max();
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// T being a signed integer and Dest unsigned is a problematic case because the value will
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// be converted into an unsigned integer, and u32(...) < 0 is always false.
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if constexpr (std::is_integral<T>() && std::is_signed<T>() && std::is_unsigned<Dest>())
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{
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static_assert(lo == 0);
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if (value < 0)
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return lo;
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// Now that we got rid of negative values, we can safely cast value to an unsigned T
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// since unsigned T can represent any positive value signed T could represent.
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// The compiler will then promote the LHS or the RHS if necessary.
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if (std::make_unsigned_t<T>(value) > hi)
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return hi;
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}
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else if constexpr (std::is_integral<T>() && std::is_unsigned<T>() && std::is_signed<Dest>())
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{
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// value and hi will never be negative, and hi is representable as an unsigned Dest.
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if (value > std::make_unsigned_t<Dest>(hi))
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return hi;
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}
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else
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{
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// Do not use std::clamp or a similar function here to avoid overflow.
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// For example, if Dest = s64 and T = int, we want integer promotion to convert value to a s64
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// instead of changing lo or hi into an int.
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if (value < lo)
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return lo;
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if (value > hi)
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return hi;
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}
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return static_cast<Dest>(value);
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}
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2018-03-23 14:50:09 +01:00
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template <typename T>
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constexpr bool IsPow2(T imm)
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2015-09-12 06:22:48 +02:00
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{
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2018-03-23 14:50:09 +01:00
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return imm > 0 && (imm & (imm - 1)) == 0;
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2015-09-12 06:22:48 +02:00
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}
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2018-05-11 01:06:19 +02:00
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constexpr u32 NextPowerOf2(u32 value)
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{
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--value;
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value |= value >> 1;
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value |= value >> 2;
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value |= value >> 4;
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value |= value >> 8;
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value |= value >> 16;
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++value;
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return value;
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}
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2009-07-15 02:51:24 +02:00
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template <class T>
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struct Rectangle
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{
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2015-10-21 02:11:25 +02:00
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T left{};
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T top{};
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T right{};
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T bottom{};
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2016-06-24 10:43:46 +02:00
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2015-10-21 02:24:11 +02:00
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constexpr Rectangle() = default;
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2016-06-24 10:43:46 +02:00
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2015-10-21 02:24:11 +02:00
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constexpr Rectangle(T theLeft, T theTop, T theRight, T theBottom)
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2011-03-08 08:39:36 +01:00
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: left(theLeft), top(theTop), right(theRight), bottom(theBottom)
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2015-10-21 02:24:11 +02:00
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{
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}
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2016-06-24 10:43:46 +02:00
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2015-10-21 02:24:11 +02:00
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constexpr bool operator==(const Rectangle& r) const
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{
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return left == r.left && top == r.top && right == r.right && bottom == r.bottom;
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}
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2016-06-24 10:43:46 +02:00
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2020-04-29 00:48:13 +02:00
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constexpr T GetWidth() const { return GetDistance(left, right); }
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constexpr T GetHeight() const { return GetDistance(top, bottom); }
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2009-07-15 02:51:24 +02:00
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// If the rectangle is in a coordinate system with a lower-left origin, use
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// this Clamp.
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void ClampLL(T x1, T y1, T x2, T y2)
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{
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2017-12-26 00:38:44 +01:00
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left = std::clamp(left, x1, x2);
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right = std::clamp(right, x1, x2);
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top = std::clamp(top, y2, y1);
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bottom = std::clamp(bottom, y2, y1);
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2009-07-15 02:51:24 +02:00
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}
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2016-06-24 10:43:46 +02:00
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2011-03-08 08:39:36 +01:00
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// If the rectangle is in a coordinate system with an upper-left origin,
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2009-07-15 02:51:24 +02:00
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// use this Clamp.
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void ClampUL(T x1, T y1, T x2, T y2)
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{
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2017-12-26 00:38:44 +01:00
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left = std::clamp(left, x1, x2);
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right = std::clamp(right, x1, x2);
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top = std::clamp(top, y1, y2);
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bottom = std::clamp(bottom, y1, y2);
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2009-07-15 02:51:24 +02:00
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}
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2020-04-29 00:48:13 +02:00
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private:
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constexpr T GetDistance(T a, T b) const
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{
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if constexpr (std::is_unsigned<T>())
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return b > a ? b - a : a - b;
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else
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return std::abs(b - a);
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}
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2009-07-15 02:51:24 +02:00
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};
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2020-02-13 02:15:02 +01:00
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template <typename T>
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class RunningMean
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{
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public:
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constexpr void Clear() { *this = {}; }
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constexpr void Push(T x) { m_mean = m_mean + (x - m_mean) / ++m_count; }
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constexpr size_t Count() const { return m_count; }
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constexpr T Mean() const { return m_mean; }
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private:
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size_t m_count = 0;
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T m_mean{};
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};
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template <typename T>
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class RunningVariance
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{
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public:
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constexpr void Clear() { *this = {}; }
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constexpr void Push(T x)
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{
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const auto old_mean = m_running_mean.Mean();
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m_running_mean.Push(x);
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m_variance += (x - old_mean) * (x - m_running_mean.Mean());
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}
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constexpr size_t Count() const { return m_running_mean.Count(); }
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constexpr T Mean() const { return m_running_mean.Mean(); }
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2020-09-23 00:44:28 +02:00
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2020-02-13 02:15:02 +01:00
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constexpr T Variance() const { return m_variance / (Count() - 1); }
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2020-09-23 00:44:28 +02:00
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T StandardDeviation() const { return std::sqrt(Variance()); }
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constexpr T PopulationVariance() const { return m_variance / Count(); }
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T PopulationStandardDeviation() const { return std::sqrt(PopulationVariance()); }
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2020-02-13 02:15:02 +01:00
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private:
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RunningMean<T> m_running_mean;
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T m_variance{};
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};
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2013-03-05 22:48:57 +01:00
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// Rounds down. 0 -> undefined
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2021-07-06 15:01:38 +02:00
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constexpr int IntLog2(u64 val)
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2013-03-05 10:12:17 +01:00
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{
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2022-10-10 11:03:15 +02:00
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return 63 - std::countl_zero(val);
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2013-03-05 10:12:17 +01:00
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}
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2023-04-15 09:27:35 +02:00
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} // namespace MathUtil
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