GY-63_MS5611/libraries/map2colour/map2colour.cpp
2022-10-20 11:58:00 +02:00

205 lines
4.2 KiB
C++

//
// FILE: map2colour.cpp
// AUTHOR: Rob Tillaart
// VERSION: 0.1.5
// PURPOSE: Arduino library for mapping a float to colour spectrum
// URL: https://github.com/RobTillaart/map2colour
//
// HISTORY see changelog.md
#include "map2colour.h"
map2colour::map2colour()
{
}
bool map2colour::begin(float * values, uint32_t * colourMap)
{
// split colour map in channels
if (colourMap != NULL)
{
for (int i = 0; i < 7; i++)
{
uint32_t val = colourMap[i];
_Blue[i] = val & 0xFF;
val >>= 8;
_Green[i] = val & 0xFF;
val >>= 8;
_Red[i] = val & 0xFF;
}
}
_values = values;
for (int index = 1; index < 7; index++)
{
// catch non increasing values.
float den = _values[index] - _values[index - 1];
if (den <= 0.0) return false;
}
return true;
}
uint32_t map2colour::map2RGB(float value)
{
int index = 1;
// default values + out of lower range
uint8_t R = _Red[0];
uint8_t G = _Green[0];
uint8_t B = _Blue[0];
if (_values[0] < value)
{
if (value <= _values[6] )
{
// search the interval
while (_values[index] < value) index++;
// base value
R = _Red[index];
G = _Green[index];
B = _Blue[index];
// calculate the interpolation factor
// map2colourFast uses pre calculated dividers (costs 24 bytes extra RAM).
float factor = (_values[index] - value) / (_values[index] - _values[index - 1]);
// interpolate only if delta != 0
int delta = _Red[index] - _Red[index - 1];
if (delta != 0 ) R -= factor * delta;
delta = _Green[index] - _Green[index - 1];
if (delta != 0 ) G -= factor * delta;
delta = _Blue[index] - _Blue[index - 1];
if (delta != 0 ) B -= factor * delta;
}
else
{
// out of upper range
R = _Red[6];
G = _Green[6];
B = _Blue[6];
}
}
uint32_t colour = R;
colour <<= 8;
colour |= G;
colour <<= 8;
colour |= B;
return colour;
}
uint16_t map2colour::map2_565(float value)
{
uint32_t RGB = map2RGB(value);
uint16_t colour = 0x0000;
RGB >>= 3;
colour |= (RGB & 0x001F); // B channel 5 bits
RGB >>= 2;
colour |= (RGB & 0x07E0); // G channel 6 bits
RGB >>= 3;
colour |= (RGB & 0xF800); // R channel 5 bits
return colour;
}
/////////////////////////////////////////////////////////////////////////
//
// DERIVED CLASS
//
map2colourFast::map2colourFast() : map2colour()
{
}
bool map2colourFast::begin(float * values, uint32_t * colourMap)
{
// load the colour-map and check non-decreasing order.
bool OK = map2colour::begin(values, colourMap);
// pre-calculate dividers
for (int index = 1; index < 7; index++)
{
float divider = _values[index] - _values[index - 1];
if (divider > 0)
{
divFactor[index - 1] = 1.0 / divider;
}
else
{
divFactor[index - 1] = 0;
}
}
return OK;
}
uint32_t map2colourFast::map2RGB(float value)
{
int index = 1;
// default values + out of lower range
uint8_t R = _Red[0];
uint8_t G = _Green[0];
uint8_t B = _Blue[0];
if (_values[0] < value)
{
if (value <= _values[6] )
{
// search the interval
while (_values[index] < value) index++;
// base value
R = _Red[index];
G = _Green[index];
B = _Blue[index];
// calculate the interpolation factor
float factor = (_values[index] - value) * divFactor[index - 1];
// interpolate if delta <> 0
int delta = _Red[index] - _Red[index - 1];
if (delta != 0 ) R -= factor * delta;
delta = _Green[index] - _Green[index - 1];
if (delta != 0 ) G -= factor * delta;
delta = _Blue[index] - _Blue[index - 1];
if (delta != 0 ) B -= factor * delta;
}
else
{
// out of upper range
R = _Red[6];
G = _Green[6];
B = _Blue[6];
}
}
uint32_t colour = R;
colour <<= 8;
colour |= G;
colour <<= 8;
colour |= B;
return colour;
}
uint16_t map2colourFast::map2_565(float value)
{
uint32_t RGB = map2RGB(value);
uint16_t colour = 0x0000;
RGB >>= 3;
colour |= (RGB & 0x001F); // B channel 5 bits
RGB >>= 2;
colour |= (RGB & 0x07E0); // G channel 6 bits
RGB >>= 3;
colour |= (RGB & 0xF800); // R channel 5 bits
return colour;
}
// -- END OF FILE --