llvm/tools/llvm-xray/xray-color-helper.cpp - llvm-project - Git at Google

 //===-- xray-graph.cpp: XRay Function Call Graph Renderer -----------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // A class to get a color from a specified gradient.
 //
 //===----------------------------------------------------------------------===//

 #include "xray-color-helper.h"
 #include "llvm/Support/FormatVariadic.h"
 #include "llvm/Support/raw_ostream.h"

 using namespace llvm;
 using namespace xray;

 //  Sequential ColorMaps, which are used to represent information
 //  from some minimum to some maximum.

 static const std::tuple<uint8_t, uint8_t, uint8_t> SequentialMaps[][9] = {
     {// The greys color scheme from http://colorbrewer2.org/
      std::make_tuple(255, 255, 255), std::make_tuple(240, 240, 240),
      std::make_tuple(217, 217, 217), std::make_tuple(189, 189, 189),
      std::make_tuple(150, 150, 150), std::make_tuple(115, 115, 115),
      std::make_tuple(82, 82, 82), std::make_tuple(37, 37, 37),
      std::make_tuple(0, 0, 0)},
     {// The OrRd color scheme from http://colorbrewer2.org/
      std::make_tuple(255, 247, 236), std::make_tuple(254, 232, 200),
      std::make_tuple(253, 212, 158), std::make_tuple(253, 187, 132),
      std::make_tuple(252, 141, 89), std::make_tuple(239, 101, 72),
      std::make_tuple(215, 48, 31), std::make_tuple(179, 0, 0),
      std::make_tuple(127, 0, 0)},
     {// The PuBu color scheme from http://colorbrewer2.org/
      std::make_tuple(255, 247, 251), std::make_tuple(236, 231, 242),
      std::make_tuple(208, 209, 230), std::make_tuple(166, 189, 219),
      std::make_tuple(116, 169, 207), std::make_tuple(54, 144, 192),
      std::make_tuple(5, 112, 176), std::make_tuple(4, 90, 141),
      std::make_tuple(2, 56, 88)}};

 // Sequential Maps extend the last colors given out of range inputs.
 static const std::tuple<uint8_t, uint8_t, uint8_t> SequentialBounds[][2] = {
     {// The Bounds for the greys color scheme
      std::make_tuple(255, 255, 255), std::make_tuple(0, 0, 0)},
     {// The Bounds for the OrRd color Scheme
      std::make_tuple(255, 247, 236), std::make_tuple(127, 0, 0)},
     {// The Bounds for the PuBu color Scheme
      std::make_tuple(255, 247, 251), std::make_tuple(2, 56, 88)}};

 ColorHelper::ColorHelper(ColorHelper::SequentialScheme S)
     : MinIn(0.0), MaxIn(1.0), ColorMap(SequentialMaps[static_cast<int>(S)]),
       BoundMap(SequentialBounds[static_cast<int>(S)]) {}

 // Diverging ColorMaps, which are used to represent information
 // representing differenes, or a range that goes from negative to positive.
 // These take an input in the range [-1,1].

 static const std::tuple<uint8_t, uint8_t, uint8_t> DivergingCoeffs[][11] = {
     {// The PiYG color scheme from http://colorbrewer2.org/
      std::make_tuple(142, 1, 82), std::make_tuple(197, 27, 125),
      std::make_tuple(222, 119, 174), std::make_tuple(241, 182, 218),
      std::make_tuple(253, 224, 239), std::make_tuple(247, 247, 247),
      std::make_tuple(230, 245, 208), std::make_tuple(184, 225, 134),
      std::make_tuple(127, 188, 65), std::make_tuple(77, 146, 33),
      std::make_tuple(39, 100, 25)}};

 // Diverging maps use out of bounds ranges to show missing data. Missing Right
 // Being below min, and missing left being above max.
 static const std::tuple<uint8_t, uint8_t, uint8_t> DivergingBounds[][2] = {
     {// The PiYG color scheme has green and red for missing right and left
      // respectively.
      std::make_tuple(255, 0, 0), std::make_tuple(0, 255, 0)}};

 ColorHelper::ColorHelper(ColorHelper::DivergingScheme S)
     : MinIn(-1.0), MaxIn(1.0), ColorMap(DivergingCoeffs[static_cast<int>(S)]),
       BoundMap(DivergingBounds[static_cast<int>(S)]) {}

 // Takes a tuple of uint8_ts representing a color in RGB and converts them to
 // HSV represented by a tuple of doubles
 static std::tuple<double, double, double>
 convertToHSV(const std::tuple<uint8_t, uint8_t, uint8_t> &Color) {
   double Scaled[3] = {std::get<0>(Color) / 255.0, std::get<1>(Color) / 255.0,
                       std::get<2>(Color) / 255.0};
   int Min = 0;
   int Max = 0;
   for (int i = 1; i < 3; ++i) {
     if (Scaled[i] < Scaled[Min])
       Min = i;
     if (Scaled[i] > Scaled[Max])
       Max = i;
   }

   double C = Scaled[Max] - Scaled[Min];

   double HPrime =
       (C == 0) ? 0 : (Scaled[(Max + 1) % 3] - Scaled[(Max + 2) % 3]) / C;
   HPrime = HPrime + 2.0 * Max;

   double H = (HPrime < 0) ? (HPrime + 6.0) * 60
                           : HPrime * 60; // Scale to between 0 and 360
   double V = Scaled[Max];

   double S = (V == 0.0) ? 0.0 : C / V;

   return std::make_tuple(H, S, V);
 }

 // Takes a double precision number, clips it between 0 and 1 and then converts
 // that to an integer between 0x00 and 0xFF with proxpper rounding.
 static uint8_t unitIntervalTo8BitChar(double B) {
   double n = std::max(std::min(B, 1.0), 0.0);
   return static_cast<uint8_t>(255 * n + 0.5);
 }

 // Takes a typle of doubles representing a color in HSV and converts them to
 // RGB represented as a tuple of uint8_ts
 static std::tuple<uint8_t, uint8_t, uint8_t>
 convertToRGB(const std::tuple<double, double, double> &Color) {
   const double &H = std::get<0>(Color);
   const double &S = std::get<1>(Color);
   const double &V = std::get<2>(Color);

   double C = V * S;

   double HPrime = H / 60;
   double X = C * (1 - std::abs(std::fmod(HPrime, 2.0) - 1));

   double RGB1[3];
   int HPrimeInt = static_cast<int>(HPrime);
   if (HPrimeInt % 2 == 0) {
     RGB1[(HPrimeInt / 2) % 3] = C;
     RGB1[(HPrimeInt / 2 + 1) % 3] = X;
     RGB1[(HPrimeInt / 2 + 2) % 3] = 0.0;
   } else {
     RGB1[(HPrimeInt / 2) % 3] = X;
     RGB1[(HPrimeInt / 2 + 1) % 3] = C;
     RGB1[(HPrimeInt / 2 + 2) % 3] = 0.0;
   }

   double Min = V - C;
   double RGB2[3] = {RGB1[0] + Min, RGB1[1] + Min, RGB1[2] + Min};

   return std::make_tuple(unitIntervalTo8BitChar(RGB2[0]),
                          unitIntervalTo8BitChar(RGB2[1]),
                          unitIntervalTo8BitChar(RGB2[2]));
 }

 // The Hue component of the HSV interpolation Routine
 static double interpolateHue(double H0, double H1, double T) {
   double D = H1 - H0;
   if (H0 > H1) {
     std::swap(H0, H1);

     D = -D;
     T = 1 - T;
   }

   if (D <= 180) {
     return H0 + T * (H1 - H0);
   } else {
     H0 = H0 + 360;
     return std::fmod(H0 + T * (H1 - H0) + 720, 360);
   }
 }

 // Interpolates between two HSV Colors both represented as a tuple of doubles
 // Returns an HSV Color represented as a tuple of doubles
 static std::tuple<double, double, double>
 interpolateHSV(const std::tuple<double, double, double> &C0,
                const std::tuple<double, double, double> &C1, double T) {
   double H = interpolateHue(std::get<0>(C0), std::get<0>(C1), T);
   double S = std::get<1>(C0) + T * (std::get<1>(C1) - std::get<1>(C0));
   double V = std::get<2>(C0) + T * (std::get<2>(C1) - std::get<2>(C0));
   return std::make_tuple(H, S, V);
 }

 // Get the Color as a tuple of uint8_ts
 std::tuple<uint8_t, uint8_t, uint8_t>
 ColorHelper::getColorTuple(double Point) const {
   assert(!ColorMap.empty() && "ColorMap must not be empty!");
   assert(!BoundMap.empty() && "BoundMap must not be empty!");

   if (Point < MinIn)
     return BoundMap[0];
   if (Point > MaxIn)
     return BoundMap[1];

   size_t MaxIndex = ColorMap.size() - 1;
   double IntervalWidth = MaxIn - MinIn;
   double OffsetP = Point - MinIn;
   double SectionWidth = IntervalWidth / static_cast<double>(MaxIndex);
   size_t SectionNo = std::floor(OffsetP / SectionWidth);
   double T = (OffsetP - SectionNo * SectionWidth) / SectionWidth;

   auto &RGBColor0 = ColorMap[SectionNo];
   auto &RGBColor1 = ColorMap[std::min(SectionNo + 1, MaxIndex)];

   auto HSVColor0 = convertToHSV(RGBColor0);
   auto HSVColor1 = convertToHSV(RGBColor1);

   auto InterpolatedHSVColor = interpolateHSV(HSVColor0, HSVColor1, T);
   return convertToRGB(InterpolatedHSVColor);
 }

 // A helper method to convert a color represented as tuple of uint8s to a hex
 // string.
 std::string
 ColorHelper::getColorString(std::tuple<uint8_t, uint8_t, uint8_t> t) {
   return llvm::formatv("#{0:X-2}{1:X-2}{2:X-2}", std::get<0>(t), std::get<1>(t),
                        std::get<2>(t));
 }

 // Gets a color in a gradient given a number in the interval [0,1], it does this
 // by evaluating a polynomial which maps [0, 1] -> [0, 1] for each of the R G
 // and B values in the color. It then converts this [0,1] colors to a 24 bit
 // color as a hex string.
 std::string ColorHelper::getColorString(double Point) const {
   return getColorString(getColorTuple(Point));
 }
	//===-- xray-graph.cpp: XRay Function Call Graph Renderer -----------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// A class to get a color from a specified gradient.
	//
	//===----------------------------------------------------------------------===//

	#include "xray-color-helper.h"
	#include "llvm/Support/FormatVariadic.h"
	#include "llvm/Support/raw_ostream.h"

	using namespace llvm;
	using namespace xray;

	// Sequential ColorMaps, which are used to represent information
	// from some minimum to some maximum.

	static const std::tuple<uint8_t, uint8_t, uint8_t> SequentialMaps[][9] = {
	{// The greys color scheme from http://colorbrewer2.org/
	std::make_tuple(255, 255, 255), std::make_tuple(240, 240, 240),
	std::make_tuple(217, 217, 217), std::make_tuple(189, 189, 189),
	std::make_tuple(150, 150, 150), std::make_tuple(115, 115, 115),
	std::make_tuple(82, 82, 82), std::make_tuple(37, 37, 37),
	std::make_tuple(0, 0, 0)},
	{// The OrRd color scheme from http://colorbrewer2.org/
	std::make_tuple(255, 247, 236), std::make_tuple(254, 232, 200),
	std::make_tuple(253, 212, 158), std::make_tuple(253, 187, 132),
	std::make_tuple(252, 141, 89), std::make_tuple(239, 101, 72),
	std::make_tuple(215, 48, 31), std::make_tuple(179, 0, 0),
	std::make_tuple(127, 0, 0)},
	{// The PuBu color scheme from http://colorbrewer2.org/
	std::make_tuple(255, 247, 251), std::make_tuple(236, 231, 242),
	std::make_tuple(208, 209, 230), std::make_tuple(166, 189, 219),
	std::make_tuple(116, 169, 207), std::make_tuple(54, 144, 192),
	std::make_tuple(5, 112, 176), std::make_tuple(4, 90, 141),
	std::make_tuple(2, 56, 88)}};

	// Sequential Maps extend the last colors given out of range inputs.
	static const std::tuple<uint8_t, uint8_t, uint8_t> SequentialBounds[][2] = {
	{// The Bounds for the greys color scheme
	std::make_tuple(255, 255, 255), std::make_tuple(0, 0, 0)},
	{// The Bounds for the OrRd color Scheme
	std::make_tuple(255, 247, 236), std::make_tuple(127, 0, 0)},
	{// The Bounds for the PuBu color Scheme
	std::make_tuple(255, 247, 251), std::make_tuple(2, 56, 88)}};

	ColorHelper::ColorHelper(ColorHelper::SequentialScheme S)
	: MinIn(0.0), MaxIn(1.0), ColorMap(SequentialMaps[static_cast<int>(S)]),
	BoundMap(SequentialBounds[static_cast<int>(S)]) {}

	// Diverging ColorMaps, which are used to represent information
	// representing differenes, or a range that goes from negative to positive.
	// These take an input in the range [-1,1].

	static const std::tuple<uint8_t, uint8_t, uint8_t> DivergingCoeffs[][11] = {
	{// The PiYG color scheme from http://colorbrewer2.org/
	std::make_tuple(142, 1, 82), std::make_tuple(197, 27, 125),
	std::make_tuple(222, 119, 174), std::make_tuple(241, 182, 218),
	std::make_tuple(253, 224, 239), std::make_tuple(247, 247, 247),
	std::make_tuple(230, 245, 208), std::make_tuple(184, 225, 134),
	std::make_tuple(127, 188, 65), std::make_tuple(77, 146, 33),
	std::make_tuple(39, 100, 25)}};

	// Diverging maps use out of bounds ranges to show missing data. Missing Right
	// Being below min, and missing left being above max.
	static const std::tuple<uint8_t, uint8_t, uint8_t> DivergingBounds[][2] = {
	{// The PiYG color scheme has green and red for missing right and left
	// respectively.
	std::make_tuple(255, 0, 0), std::make_tuple(0, 255, 0)}};

	ColorHelper::ColorHelper(ColorHelper::DivergingScheme S)
	: MinIn(-1.0), MaxIn(1.0), ColorMap(DivergingCoeffs[static_cast<int>(S)]),
	BoundMap(DivergingBounds[static_cast<int>(S)]) {}

	// Takes a tuple of uint8_ts representing a color in RGB and converts them to
	// HSV represented by a tuple of doubles
	static std::tuple<double, double, double>
	convertToHSV(const std::tuple<uint8_t, uint8_t, uint8_t> &Color) {
	double Scaled[3] = {std::get<0>(Color) / 255.0, std::get<1>(Color) / 255.0,
	std::get<2>(Color) / 255.0};
	int Min = 0;
	int Max = 0;
	for (int i = 1; i < 3; ++i) {
	if (Scaled[i] < Scaled[Min])
	Min = i;
	if (Scaled[i] > Scaled[Max])
	Max = i;
	}

	double C = Scaled[Max] - Scaled[Min];

	double HPrime =
	(C == 0) ? 0 : (Scaled[(Max + 1) % 3] - Scaled[(Max + 2) % 3]) / C;
	HPrime = HPrime + 2.0 * Max;

	double H = (HPrime < 0) ? (HPrime + 6.0) * 60
	: HPrime * 60; // Scale to between 0 and 360
	double V = Scaled[Max];

	double S = (V == 0.0) ? 0.0 : C / V;

	return std::make_tuple(H, S, V);
	}

	// Takes a double precision number, clips it between 0 and 1 and then converts
	// that to an integer between 0x00 and 0xFF with proxpper rounding.
	static uint8_t unitIntervalTo8BitChar(double B) {
	double n = std::max(std::min(B, 1.0), 0.0);
	return static_cast<uint8_t>(255 * n + 0.5);
	}

	// Takes a typle of doubles representing a color in HSV and converts them to
	// RGB represented as a tuple of uint8_ts
	static std::tuple<uint8_t, uint8_t, uint8_t>
	convertToRGB(const std::tuple<double, double, double> &Color) {
	const double &H = std::get<0>(Color);
	const double &S = std::get<1>(Color);
	const double &V = std::get<2>(Color);

	double C = V * S;

	double HPrime = H / 60;
	double X = C * (1 - std::abs(std::fmod(HPrime, 2.0) - 1));

	double RGB1[3];
	int HPrimeInt = static_cast<int>(HPrime);
	if (HPrimeInt % 2 == 0) {
	RGB1[(HPrimeInt / 2) % 3] = C;
	RGB1[(HPrimeInt / 2 + 1) % 3] = X;
	RGB1[(HPrimeInt / 2 + 2) % 3] = 0.0;
	} else {
	RGB1[(HPrimeInt / 2) % 3] = X;
	RGB1[(HPrimeInt / 2 + 1) % 3] = C;
	RGB1[(HPrimeInt / 2 + 2) % 3] = 0.0;
	}

	double Min = V - C;
	double RGB2[3] = {RGB1[0] + Min, RGB1[1] + Min, RGB1[2] + Min};

	return std::make_tuple(unitIntervalTo8BitChar(RGB2[0]),
	unitIntervalTo8BitChar(RGB2[1]),
	unitIntervalTo8BitChar(RGB2[2]));
	}

	// The Hue component of the HSV interpolation Routine
	static double interpolateHue(double H0, double H1, double T) {
	double D = H1 - H0;
	if (H0 > H1) {
	std::swap(H0, H1);

	D = -D;
	T = 1 - T;
	}

	if (D <= 180) {
	return H0 + T * (H1 - H0);
	} else {
	H0 = H0 + 360;
	return std::fmod(H0 + T * (H1 - H0) + 720, 360);
	}
	}

	// Interpolates between two HSV Colors both represented as a tuple of doubles
	// Returns an HSV Color represented as a tuple of doubles
	static std::tuple<double, double, double>
	interpolateHSV(const std::tuple<double, double, double> &C0,
	const std::tuple<double, double, double> &C1, double T) {
	double H = interpolateHue(std::get<0>(C0), std::get<0>(C1), T);
	double S = std::get<1>(C0) + T * (std::get<1>(C1) - std::get<1>(C0));
	double V = std::get<2>(C0) + T * (std::get<2>(C1) - std::get<2>(C0));
	return std::make_tuple(H, S, V);
	}

	// Get the Color as a tuple of uint8_ts
	std::tuple<uint8_t, uint8_t, uint8_t>
	ColorHelper::getColorTuple(double Point) const {
	assert(!ColorMap.empty() && "ColorMap must not be empty!");
	assert(!BoundMap.empty() && "BoundMap must not be empty!");

	if (Point < MinIn)
	return BoundMap[0];
	if (Point > MaxIn)
	return BoundMap[1];

	size_t MaxIndex = ColorMap.size() - 1;
	double IntervalWidth = MaxIn - MinIn;
	double OffsetP = Point - MinIn;
	double SectionWidth = IntervalWidth / static_cast<double>(MaxIndex);
	size_t SectionNo = std::floor(OffsetP / SectionWidth);
	double T = (OffsetP - SectionNo * SectionWidth) / SectionWidth;

	auto &RGBColor0 = ColorMap[SectionNo];
	auto &RGBColor1 = ColorMap[std::min(SectionNo + 1, MaxIndex)];

	auto HSVColor0 = convertToHSV(RGBColor0);
	auto HSVColor1 = convertToHSV(RGBColor1);

	auto InterpolatedHSVColor = interpolateHSV(HSVColor0, HSVColor1, T);
	return convertToRGB(InterpolatedHSVColor);
	}

	// A helper method to convert a color represented as tuple of uint8s to a hex
	// string.
	std::string
	ColorHelper::getColorString(std::tuple<uint8_t, uint8_t, uint8_t> t) {
	return llvm::formatv("#{0:X-2}{1:X-2}{2:X-2}", std::get<0>(t), std::get<1>(t),
	std::get<2>(t));
	}

	// Gets a color in a gradient given a number in the interval [0,1], it does this
	// by evaluating a polynomial which maps [0, 1] -> [0, 1] for each of the R G
	// and B values in the color. It then converts this [0,1] colors to a 24 bit
	// color as a hex string.
	std::string ColorHelper::getColorString(double Point) const {
	return getColorString(getColorTuple(Point));
	}