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- /*
- ==============================================================================
-
- This file is part of the JUCE library.
- Copyright (c) 2016 - ROLI Ltd.
-
- Permission is granted to use this software under the terms of the ISC license
- http://www.isc.org/downloads/software-support-policy/isc-license/
-
- Permission to use, copy, modify, and/or distribute this software for any
- purpose with or without fee is hereby granted, provided that the above
- copyright notice and this permission notice appear in all copies.
-
- THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES WITH REGARD
- TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND
- FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT,
- OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF
- USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
- TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE
- OF THIS SOFTWARE.
-
- -----------------------------------------------------------------------------
-
- To release a closed-source product which uses other parts of JUCE not
- licensed under the ISC terms, commercial licenses are available: visit
- www.juce.com for more information.
-
- ==============================================================================
- */
-
- #ifndef JUCE_MATHSFUNCTIONS_H_INCLUDED
- #define JUCE_MATHSFUNCTIONS_H_INCLUDED
-
- //==============================================================================
- /*
- This file sets up some handy mathematical typdefs and functions.
- */
-
- //==============================================================================
- // Definitions for the int8, int16, int32, int64 and pointer_sized_int types.
-
- /** A platform-independent 8-bit signed integer type. */
- typedef signed char int8;
- /** A platform-independent 8-bit unsigned integer type. */
- typedef unsigned char uint8;
- /** A platform-independent 16-bit signed integer type. */
- typedef signed short int16;
- /** A platform-independent 16-bit unsigned integer type. */
- typedef unsigned short uint16;
- /** A platform-independent 32-bit signed integer type. */
- typedef signed int int32;
- /** A platform-independent 32-bit unsigned integer type. */
- typedef unsigned int uint32;
- /** A platform-independent 64-bit integer type. */
- typedef long long int64;
- /** A platform-independent 64-bit unsigned integer type. */
- typedef unsigned long long uint64;
-
- #if JUCE_64BIT
- /** A signed integer type that's guaranteed to be large enough to hold a pointer without truncating it. */
- typedef int64 pointer_sized_int;
- /** An unsigned integer type that's guaranteed to be large enough to hold a pointer without truncating it. */
- typedef uint64 pointer_sized_uint;
- #else
- /** A signed integer type that's guaranteed to be large enough to hold a pointer without truncating it. */
- typedef int pointer_sized_int;
- /** An unsigned integer type that's guaranteed to be large enough to hold a pointer without truncating it. */
- typedef unsigned int pointer_sized_uint;
- #endif
-
- //==============================================================================
- // Some indispensable min/max functions
-
- /** Returns the larger of two values. */
- template <typename Type>
- Type jmax (const Type a, const Type b) { return (a < b) ? b : a; }
-
- /** Returns the larger of three values. */
- template <typename Type>
- Type jmax (const Type a, const Type b, const Type c) { return (a < b) ? ((b < c) ? c : b) : ((a < c) ? c : a); }
-
- /** Returns the larger of four values. */
- template <typename Type>
- Type jmax (const Type a, const Type b, const Type c, const Type d) { return jmax (a, jmax (b, c, d)); }
-
- /** Returns the smaller of two values. */
- template <typename Type>
- Type jmin (const Type a, const Type b) { return (b < a) ? b : a; }
-
- /** Returns the smaller of three values. */
- template <typename Type>
- Type jmin (const Type a, const Type b, const Type c) { return (b < a) ? ((c < b) ? c : b) : ((c < a) ? c : a); }
-
- /** Returns the smaller of four values. */
- template <typename Type>
- Type jmin (const Type a, const Type b, const Type c, const Type d) { return jmin (a, jmin (b, c, d)); }
-
- /** Remaps a normalised value (between 0 and 1) to a target range.
- This effectively returns (targetRangeMin + value0To1 * (targetRangeMax - targetRangeMin)).
- */
- template <typename Type>
- Type jmap (Type value0To1, Type targetRangeMin, Type targetRangeMax)
- {
- return targetRangeMin + value0To1 * (targetRangeMax - targetRangeMin);
- }
-
- /** Remaps a value from a source range to a target range. */
- template <typename Type>
- Type jmap (Type sourceValue, Type sourceRangeMin, Type sourceRangeMax, Type targetRangeMin, Type targetRangeMax)
- {
- jassert (sourceRangeMax != sourceRangeMin); // mapping from a range of zero will produce NaN!
- return targetRangeMin + ((targetRangeMax - targetRangeMin) * (sourceValue - sourceRangeMin)) / (sourceRangeMax - sourceRangeMin);
- }
-
- /** Scans an array of values, returning the minimum value that it contains. */
- template <typename Type>
- Type findMinimum (const Type* data, int numValues)
- {
- if (numValues <= 0)
- return Type();
-
- Type result (*data++);
-
- while (--numValues > 0) // (> 0 rather than >= 0 because we've already taken the first sample)
- {
- const Type& v = *data++;
- if (v < result) result = v;
- }
-
- return result;
- }
-
- /** Scans an array of values, returning the maximum value that it contains. */
- template <typename Type>
- Type findMaximum (const Type* values, int numValues)
- {
- if (numValues <= 0)
- return Type();
-
- Type result (*values++);
-
- while (--numValues > 0) // (> 0 rather than >= 0 because we've already taken the first sample)
- {
- const Type& v = *values++;
- if (result < v) result = v;
- }
-
- return result;
- }
-
- /** Scans an array of values, returning the minimum and maximum values that it contains. */
- template <typename Type>
- void findMinAndMax (const Type* values, int numValues, Type& lowest, Type& highest)
- {
- if (numValues <= 0)
- {
- lowest = Type();
- highest = Type();
- }
- else
- {
- Type mn (*values++);
- Type mx (mn);
-
- while (--numValues > 0) // (> 0 rather than >= 0 because we've already taken the first sample)
- {
- const Type& v = *values++;
-
- if (mx < v) mx = v;
- if (v < mn) mn = v;
- }
-
- lowest = mn;
- highest = mx;
- }
- }
-
-
- //==============================================================================
- /** Constrains a value to keep it within a given range.
-
- This will check that the specified value lies between the lower and upper bounds
- specified, and if not, will return the nearest value that would be in-range. Effectively,
- it's like calling jmax (lowerLimit, jmin (upperLimit, value)).
-
- Note that it expects that lowerLimit <= upperLimit. If this isn't true,
- the results will be unpredictable.
-
- @param lowerLimit the minimum value to return
- @param upperLimit the maximum value to return
- @param valueToConstrain the value to try to return
- @returns the closest value to valueToConstrain which lies between lowerLimit
- and upperLimit (inclusive)
- @see jmin, jmax, jmap
- */
- template <typename Type>
- Type jlimit (const Type lowerLimit,
- const Type upperLimit,
- const Type valueToConstrain) noexcept
- {
- jassert (lowerLimit <= upperLimit); // if these are in the wrong order, results are unpredictable..
-
- return (valueToConstrain < lowerLimit) ? lowerLimit
- : ((upperLimit < valueToConstrain) ? upperLimit
- : valueToConstrain);
- }
-
- /** Returns true if a value is at least zero, and also below a specified upper limit.
- This is basically a quicker way to write:
- @code valueToTest >= 0 && valueToTest < upperLimit
- @endcode
- */
- template <typename Type>
- bool isPositiveAndBelow (Type valueToTest, Type upperLimit) noexcept
- {
- jassert (Type() <= upperLimit); // makes no sense to call this if the upper limit is itself below zero..
- return Type() <= valueToTest && valueToTest < upperLimit;
- }
-
- template <>
- inline bool isPositiveAndBelow (const int valueToTest, const int upperLimit) noexcept
- {
- jassert (upperLimit >= 0); // makes no sense to call this if the upper limit is itself below zero..
- return static_cast<unsigned int> (valueToTest) < static_cast<unsigned int> (upperLimit);
- }
-
- /** Returns true if a value is at least zero, and also less than or equal to a specified upper limit.
- This is basically a quicker way to write:
- @code valueToTest >= 0 && valueToTest <= upperLimit
- @endcode
- */
- template <typename Type>
- bool isPositiveAndNotGreaterThan (Type valueToTest, Type upperLimit) noexcept
- {
- jassert (Type() <= upperLimit); // makes no sense to call this if the upper limit is itself below zero..
- return Type() <= valueToTest && valueToTest <= upperLimit;
- }
-
- template <>
- inline bool isPositiveAndNotGreaterThan (const int valueToTest, const int upperLimit) noexcept
- {
- jassert (upperLimit >= 0); // makes no sense to call this if the upper limit is itself below zero..
- return static_cast<unsigned int> (valueToTest) <= static_cast<unsigned int> (upperLimit);
- }
-
- //==============================================================================
- /** Handy function to swap two values. */
- template <typename Type>
- void swapVariables (Type& variable1, Type& variable2)
- {
- std::swap (variable1, variable2);
- }
-
- /** Handy function for avoiding unused variables warning. */
- template <typename Type1>
- void ignoreUnused (const Type1&) noexcept {}
-
- template <typename Type1, typename Type2>
- void ignoreUnused (const Type1&, const Type2&) noexcept {}
-
- template <typename Type1, typename Type2, typename Type3>
- void ignoreUnused (const Type1&, const Type2&, const Type3&) noexcept {}
-
- template <typename Type1, typename Type2, typename Type3, typename Type4>
- void ignoreUnused (const Type1&, const Type2&, const Type3&, const Type4&) noexcept {}
-
- /** Handy function for getting the number of elements in a simple const C array.
- E.g.
- @code
- static int myArray[] = { 1, 2, 3 };
-
- int numElements = numElementsInArray (myArray) // returns 3
- @endcode
- */
- template <typename Type, int N>
- int numElementsInArray (Type (&array)[N])
- {
- ignoreUnused (array);
- (void) sizeof (0[array]); // This line should cause an error if you pass an object with a user-defined subscript operator
- return N;
- }
-
- //==============================================================================
- // Some useful maths functions that aren't always present with all compilers and build settings.
-
- /** Using juce_hypot is easier than dealing with the different types of hypot function
- that are provided by the various platforms and compilers. */
- template <typename Type>
- Type juce_hypot (Type a, Type b) noexcept
- {
- return static_cast<Type> (hypot (a, b));
- }
-
- template <>
- inline float juce_hypot (float a, float b) noexcept
- {
- return hypotf (a, b);
- }
-
- /** 64-bit abs function. */
- inline int64 abs64 (const int64 n) noexcept
- {
- return (n >= 0) ? n : -n;
- }
-
- //==============================================================================
- /** A predefined value for Pi, at double-precision.
- @see float_Pi
- */
- const double double_Pi = 3.1415926535897932384626433832795;
-
- /** A predefined value for Pi, at single-precision.
- @see double_Pi
- */
- const float float_Pi = 3.14159265358979323846f;
-
-
- /** Converts an angle in degrees to radians. */
- inline float degreesToRadians (float degrees) noexcept { return degrees * (float_Pi / 180.0f); }
-
- /** Converts an angle in degrees to radians. */
- inline double degreesToRadians (double degrees) noexcept { return degrees * (double_Pi / 180.0); }
-
- /** Converts an angle in radians to degrees. */
- inline float radiansToDegrees (float radians) noexcept { return radians * (180.0f / float_Pi); }
-
- /** Converts an angle in radians to degrees. */
- inline double radiansToDegrees (double radians) noexcept { return radians * (180.0 / double_Pi); }
-
-
- //==============================================================================
- /** The isfinite() method seems to vary between platforms, so this is a
- platform-independent function for it.
- */
- template <typename NumericType>
- bool juce_isfinite (NumericType) noexcept
- {
- return true; // Integer types are always finite
- }
-
- template <>
- inline bool juce_isfinite (float value) noexcept
- {
- return std::isfinite (value);
- }
-
- template <>
- inline bool juce_isfinite (double value) noexcept
- {
- return std::isfinite (value);
- }
-
- //==============================================================================
- /** Fast floating-point-to-integer conversion.
-
- This is faster than using the normal c++ cast to convert a float to an int, and
- it will round the value to the nearest integer, rather than rounding it down
- like the normal cast does.
-
- Note that this routine gets its speed at the expense of some accuracy, and when
- rounding values whose floating point component is exactly 0.5, odd numbers and
- even numbers will be rounded up or down differently.
- */
- template <typename FloatType>
- int roundToInt (const FloatType value) noexcept
- {
- union { int asInt[2]; double asDouble; } n;
- n.asDouble = ((double) value) + 6755399441055744.0;
-
- #if JUCE_BIG_ENDIAN
- return n.asInt [1];
- #else
- return n.asInt [0];
- #endif
- }
-
- inline int roundToInt (int value) noexcept
- {
- return value;
- }
-
- /** Fast floating-point-to-integer conversion.
-
- This is a slightly slower and slightly more accurate version of roundDoubleToInt(). It works
- fine for values above zero, but negative numbers are rounded the wrong way.
- */
- inline int roundToIntAccurate (double value) noexcept
- {
- return roundToInt (value + 1.5e-8);
- }
-
- /** Fast floating-point-to-integer conversion.
-
- This is faster than using the normal c++ cast to convert a double to an int, and
- it will round the value to the nearest integer, rather than rounding it down
- like the normal cast does.
-
- Note that this routine gets its speed at the expense of some accuracy, and when
- rounding values whose floating point component is exactly 0.5, odd numbers and
- even numbers will be rounded up or down differently. For a more accurate conversion,
- see roundDoubleToIntAccurate().
- */
- inline int roundDoubleToInt (double value) noexcept
- {
- return roundToInt (value);
- }
-
- /** Fast floating-point-to-integer conversion.
-
- This is faster than using the normal c++ cast to convert a float to an int, and
- it will round the value to the nearest integer, rather than rounding it down
- like the normal cast does.
-
- Note that this routine gets its speed at the expense of some accuracy, and when
- rounding values whose floating point component is exactly 0.5, odd numbers and
- even numbers will be rounded up or down differently.
- */
- inline int roundFloatToInt (float value) noexcept
- {
- return roundToInt (value);
- }
-
- //==============================================================================
- /** Returns true if the specified integer is a power-of-two. */
- template <typename IntegerType>
- bool isPowerOfTwo (IntegerType value)
- {
- return (value & (value - 1)) == 0;
- }
-
- /** Returns the smallest power-of-two which is equal to or greater than the given integer. */
- inline int nextPowerOfTwo (int n) noexcept
- {
- --n;
- n |= (n >> 1);
- n |= (n >> 2);
- n |= (n >> 4);
- n |= (n >> 8);
- n |= (n >> 16);
- return n + 1;
- }
-
- /** Returns the index of the highest set bit in a (non-zero) number.
- So for n=3 this would return 1, for n=7 it returns 2, etc.
- An input value of 0 is illegal!
- */
- int findHighestSetBit (uint32 n) noexcept;
-
- /** Returns the number of bits in a 32-bit integer. */
- inline int countNumberOfBits (uint32 n) noexcept
- {
- n -= ((n >> 1) & 0x55555555);
- n = (((n >> 2) & 0x33333333) + (n & 0x33333333));
- n = (((n >> 4) + n) & 0x0f0f0f0f);
- n += (n >> 8);
- n += (n >> 16);
- return (int) (n & 0x3f);
- }
-
- /** Returns the number of bits in a 64-bit integer. */
- inline int countNumberOfBits (uint64 n) noexcept
- {
- return countNumberOfBits ((uint32) n) + countNumberOfBits ((uint32) (n >> 32));
- }
-
- /** Performs a modulo operation, but can cope with the dividend being negative.
- The divisor must be greater than zero.
- */
- template <typename IntegerType>
- IntegerType negativeAwareModulo (IntegerType dividend, const IntegerType divisor) noexcept
- {
- jassert (divisor > 0);
- dividend %= divisor;
- return (dividend < 0) ? (dividend + divisor) : dividend;
- }
-
- /** Returns the square of its argument. */
- template <typename NumericType>
- NumericType square (NumericType n) noexcept
- {
- return n * n;
- }
-
- //==============================================================================
- /** Writes a number of bits into a memory buffer at a given bit index.
- The buffer is treated as a sequence of 8-bit bytes, and the value is encoded in little-endian order,
- so for example if startBit = 10, and numBits = 11 then the lower 6 bits of the value would be written
- into bits 2-8 of targetBuffer[1], and the upper 5 bits of value into bits 0-5 of targetBuffer[2].
-
- @see readLittleEndianBitsInBuffer
- */
- void writeLittleEndianBitsInBuffer (void* targetBuffer, uint32 startBit, uint32 numBits, uint32 value) noexcept;
-
- /** Reads a number of bits from a buffer at a given bit index.
- The buffer is treated as a sequence of 8-bit bytes, and the value is encoded in little-endian order,
- so for example if startBit = 10, and numBits = 11 then the lower 6 bits of the result would be read
- from bits 2-8 of sourceBuffer[1], and the upper 5 bits of the result from bits 0-5 of sourceBuffer[2].
-
- @see writeLittleEndianBitsInBuffer
- */
- uint32 readLittleEndianBitsInBuffer (const void* sourceBuffer, uint32 startBit, uint32 numBits) noexcept;
-
-
- //==============================================================================
- /** This namespace contains a few template classes for helping work out class type variations.
- */
- namespace TypeHelpers
- {
- /** The ParameterType struct is used to find the best type to use when passing some kind
- of object as a parameter.
-
- Of course, this is only likely to be useful in certain esoteric template situations.
-
- Because "typename TypeHelpers::ParameterType<SomeClass>::type" is a bit of a mouthful, there's
- a PARAMETER_TYPE(SomeClass) macro that you can use to get the same effect.
-
- E.g. "myFunction (PARAMETER_TYPE (int), PARAMETER_TYPE (MyObject))"
- would evaluate to "myfunction (int, const MyObject&)", keeping any primitive types as
- pass-by-value, but passing objects as a const reference, to avoid copying.
- */
- template <typename Type> struct ParameterType { typedef const Type& type; };
- template <typename Type> struct ParameterType <Type&> { typedef Type& type; };
- template <typename Type> struct ParameterType <Type*> { typedef Type* type; };
- template <> struct ParameterType <char> { typedef char type; };
- template <> struct ParameterType <unsigned char> { typedef unsigned char type; };
- template <> struct ParameterType <short> { typedef short type; };
- template <> struct ParameterType <unsigned short> { typedef unsigned short type; };
- template <> struct ParameterType <int> { typedef int type; };
- template <> struct ParameterType <unsigned int> { typedef unsigned int type; };
- template <> struct ParameterType <long> { typedef long type; };
- template <> struct ParameterType <unsigned long> { typedef unsigned long type; };
- template <> struct ParameterType <int64> { typedef int64 type; };
- template <> struct ParameterType <uint64> { typedef uint64 type; };
- template <> struct ParameterType <bool> { typedef bool type; };
- template <> struct ParameterType <float> { typedef float type; };
- template <> struct ParameterType <double> { typedef double type; };
-
- /** A helpful macro to simplify the use of the ParameterType template.
- @see ParameterType
- */
- #define PARAMETER_TYPE(a) typename TypeHelpers::ParameterType<a>::type
-
-
- /** These templates are designed to take a type, and if it's a double, they return a double
- type; for anything else, they return a float type.
- */
- template <typename Type> struct SmallestFloatType { typedef float type; };
- template <> struct SmallestFloatType <double> { typedef double type; };
- }
-
-
- //==============================================================================
-
- #endif // JUCE_MATHSFUNCTIONS_H_INCLUDED
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