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noiseutils.cpp
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noiseutils.cpp
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// noiseutils.cpp
//
// Copyright (C) 2003-2005 Jason Bevins
//
// This library is free software; you can redistribute it and/or modify it
// under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation; either version 2.1 of the License, or (at
// your option) any later version.
//
// This library is distributed in the hope that it will be useful, but WITHOUT
// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
// FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
// License (COPYING.txt) for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with this library; if not, write to the Free Software Foundation,
// Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
//
// The developer's email is [email protected] (for great email, take
// off every 'zig'.)
//
#include <fstream>
#include <noise/interp.h>
#include <noise/mathconsts.h>
#include "noiseutils.h"
using namespace noise;
using namespace noise::model;
using namespace noise::module;
// Bitmap header size.
const int BMP_HEADER_SIZE = 54;
// Direction of the light source, in compass degrees (0 = north, 90 = east,
// 180 = south, 270 = east)
const double DEFAULT_LIGHT_AZIMUTH = 45.0;
// Amount of contrast between light and dark areas.
const double DEFAULT_LIGHT_CONTRAST = 1.0;
// Elevation of the light source above the horizon, in degrees (0 = on
// horizon, 90 = directly overhead)
const double DEFAULT_LIGHT_ELEVATION = 45.0;
//////////////////////////////////////////////////////////////////////////////
// Miscellaneous functions
namespace noise
{
namespace utils
{
// Performs linear interpolation between two 8-bit channel values.
inline noise::uint8 BlendChannel (const uint8 channel0,
const uint8 channel1, float alpha)
{
float c0 = (float)channel0 / 255.0;
float c1 = (float)channel1 / 255.0;
return (noise::uint8)(((c1 * alpha) + (c0 * (1.0f - alpha))) * 255.0f);
}
// Performs linear interpolation between two colors and stores the result
// in out.
inline void LinearInterpColor (const Color& color0, const Color& color1,
float alpha, Color& out)
{
out.alpha = BlendChannel (color0.alpha, color1.alpha, alpha);
out.blue = BlendChannel (color0.blue , color1.blue , alpha);
out.green = BlendChannel (color0.green, color1.green, alpha);
out.red = BlendChannel (color0.red , color1.red , alpha);
}
// Unpacks a floating-point value into four bytes. This function is
// specific to Intel machines. A portable version will come soon (I
// hope.)
inline noise::uint8* UnpackFloat (noise::uint8* bytes, float value)
{
noise::uint8* pBytes = (noise::uint8*)(&value);
bytes[0] = *pBytes++;
bytes[1] = *pBytes++;
bytes[2] = *pBytes++;
bytes[3] = *pBytes++;
return bytes;
}
// Unpacks a 16-bit integer value into two bytes in little endian format.
inline noise::uint8* UnpackLittle16 (noise::uint8* bytes,
noise::uint16 integer)
{
bytes[0] = (noise::uint8)((integer & 0x00ff) );
bytes[1] = (noise::uint8)((integer & 0xff00) >> 8 );
return bytes;
}
// Unpacks a 32-bit integer value into four bytes in little endian format.
inline noise::uint8* UnpackLittle32 (noise::uint8* bytes,
noise::uint32 integer)
{
bytes[0] = (noise::uint8)((integer & 0x000000ff) );
bytes[1] = (noise::uint8)((integer & 0x0000ff00) >> 8 );
bytes[2] = (noise::uint8)((integer & 0x00ff0000) >> 16);
bytes[3] = (noise::uint8)((integer & 0xff000000) >> 24);
return bytes;
}
}
}
using namespace noise;
using namespace noise::utils;
//////////////////////////////////////////////////////////////////////////////
// GradientColor class
GradientColor::GradientColor ()
{
m_pGradientPoints = NULL;
}
GradientColor::~GradientColor ()
{
delete[] m_pGradientPoints;
}
void GradientColor::AddGradientPoint (double gradientPos,
const Color& gradientColor)
{
// Find the insertion point for the new gradient point and insert the new
// gradient point at that insertion point. The gradient point array will
// remain sorted by gradient position.
int insertionPos = FindInsertionPos (gradientPos);
InsertAtPos (insertionPos, gradientPos, gradientColor);
}
void GradientColor::Clear ()
{
delete[] m_pGradientPoints;
m_pGradientPoints = NULL;
m_gradientPointCount = 0;
}
int GradientColor::FindInsertionPos (double gradientPos)
{
int insertionPos;
for (insertionPos = 0; insertionPos < m_gradientPointCount;
insertionPos++) {
if (gradientPos < m_pGradientPoints[insertionPos].pos) {
// We found the array index in which to insert the new gradient point.
// Exit now.
break;
} else if (gradientPos == m_pGradientPoints[insertionPos].pos) {
// Each gradient point is required to contain a unique gradient
// position, so throw an exception.
throw noise::ExceptionInvalidParam ();
}
}
return insertionPos;
}
const Color& GradientColor::GetColor (double gradientPos) const
{
assert (m_gradientPointCount >= 2);
// Find the first element in the gradient point array that has a gradient
// position larger than the gradient position passed to this method.
int indexPos;
for (indexPos = 0; indexPos < m_gradientPointCount; indexPos++) {
if (gradientPos < m_pGradientPoints[indexPos].pos) {
break;
}
}
// Find the two nearest gradient points so that we can perform linear
// interpolation on the color.
int index0 = ClampValue (indexPos - 1, 0, m_gradientPointCount - 1);
int index1 = ClampValue (indexPos , 0, m_gradientPointCount - 1);
// If some gradient points are missing (which occurs if the gradient
// position passed to this method is greater than the largest gradient
// position or less than the smallest gradient position in the array), get
// the corresponding gradient color of the nearest gradient point and exit
// now.
if (index0 == index1) {
m_workingColor = m_pGradientPoints[index1].color;
return m_workingColor;
}
// Compute the alpha value used for linear interpolation.
double input0 = m_pGradientPoints[index0].pos;
double input1 = m_pGradientPoints[index1].pos;
double alpha = (gradientPos - input0) / (input1 - input0);
// Now perform the linear interpolation given the alpha value.
const Color& color0 = m_pGradientPoints[index0].color;
const Color& color1 = m_pGradientPoints[index1].color;
LinearInterpColor (color0, color1, (float)alpha, m_workingColor);
return m_workingColor;
}
void GradientColor::InsertAtPos (int insertionPos, double gradientPos,
const Color& gradientColor)
{
// Make room for the new gradient point at the specified insertion position
// within the gradient point array. The insertion position is determined by
// the gradient point's position; the gradient points must be sorted by
// gradient position within that array.
GradientPoint* newGradientPoints;
newGradientPoints = new GradientPoint[m_gradientPointCount + 1];
for (int i = 0; i < m_gradientPointCount; i++) {
if (i < insertionPos) {
newGradientPoints[i] = m_pGradientPoints[i];
} else {
newGradientPoints[i + 1] = m_pGradientPoints[i];
}
}
delete[] m_pGradientPoints;
m_pGradientPoints = newGradientPoints;
++m_gradientPointCount;
// Now that we've made room for the new gradient point within the array, add
// the new gradient point.
m_pGradientPoints[insertionPos].pos = gradientPos ;
m_pGradientPoints[insertionPos].color = gradientColor;
}
//////////////////////////////////////////////////////////////////////////////
// NoiseMap class
NoiseMap::NoiseMap ()
{
InitObj ();
}
NoiseMap::NoiseMap (int width, int height)
{
InitObj ();
SetSize (width, height);
}
NoiseMap::NoiseMap (const NoiseMap& rhs)
{
InitObj ();
CopyNoiseMap (rhs);
}
NoiseMap::~NoiseMap ()
{
delete[] m_pNoiseMap;
}
NoiseMap& NoiseMap::operator= (const NoiseMap& rhs)
{
CopyNoiseMap (rhs);
return *this;
}
void NoiseMap::Clear (float value)
{
if (m_pNoiseMap != NULL) {
for (int y = 0; y < m_height; y++) {
float* pDest = GetSlabPtr (0, y);
for (int x = 0; x < m_width; x++) {
*pDest++ = value;
}
}
}
}
void NoiseMap::CopyNoiseMap (const NoiseMap& source)
{
// Resize the noise map buffer, then copy the slabs from the source noise
// map buffer to this noise map buffer.
SetSize (source.GetWidth (), source.GetHeight ());
for (int y = 0; y < source.GetHeight (); y++) {
const float* pSource = source.GetConstSlabPtr (0, y);
float* pDest = GetSlabPtr (0, y);
memcpy (pDest, pSource, (size_t)source.GetWidth () * sizeof (float));
}
// Copy the border value as well.
m_borderValue = source.m_borderValue;
}
void NoiseMap::DeleteNoiseMapAndReset ()
{
delete[] m_pNoiseMap;
InitObj ();
}
float NoiseMap::GetValue (int x, int y) const
{
if (m_pNoiseMap != NULL) {
if (x >= 0 && x < m_width && y >= 0 && y < m_height) {
return *(GetConstSlabPtr (x, y));
}
}
// The coordinates specified are outside the noise map. Return the border
// value.
return m_borderValue;
}
void NoiseMap::InitObj ()
{
m_pNoiseMap = NULL;
m_height = 0;
m_width = 0;
m_stride = 0;
m_memUsed = 0;
m_borderValue = 0.0;
}
void NoiseMap::ReclaimMem ()
{
size_t newMemUsage = CalcMinMemUsage (m_width, m_height);
if (m_memUsed > newMemUsage) {
// There is wasted memory. Create the smallest buffer that can fit the
// data and copy the data to it.
float* pNewNoiseMap = NULL;
try {
pNewNoiseMap = new float[newMemUsage];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
memcpy (pNewNoiseMap, m_pNoiseMap, newMemUsage * sizeof (float));
delete[] m_pNoiseMap;
m_pNoiseMap = pNewNoiseMap;
m_memUsed = newMemUsage;
}
}
void NoiseMap::SetSize (int width, int height)
{
if (width < 0 || height < 0
|| width > RASTER_MAX_WIDTH || height > RASTER_MAX_HEIGHT) {
// Invalid width or height.
throw noise::ExceptionInvalidParam ();
} else if (width == 0 || height == 0) {
// An empty noise map was specified. Delete it and zero out the size
// member variables.
DeleteNoiseMapAndReset ();
} else {
// A new noise map size was specified. Allocate a new noise map buffer
// unless the current buffer is large enough for the new noise map (we
// don't want costly reallocations going on.)
size_t newMemUsage = CalcMinMemUsage (width, height);
if (m_memUsed < newMemUsage) {
// The new size is too big for the current noise map buffer. We need to
// reallocate.
DeleteNoiseMapAndReset ();
try {
m_pNoiseMap = new float[newMemUsage];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
m_memUsed = newMemUsage;
}
m_stride = (int)CalcStride (width);
m_width = width;
m_height = height;
}
}
void NoiseMap::SetValue (int x, int y, float value)
{
if (m_pNoiseMap != NULL) {
if (x >= 0 && x < m_width && y >= 0 && y < m_height) {
*(GetSlabPtr (x, y)) = value;
}
}
}
void NoiseMap::TakeOwnership (NoiseMap& source)
{
// Copy the values and the noise map buffer from the source noise map to
// this noise map. Now this noise map pwnz the source buffer.
delete[] m_pNoiseMap;
m_memUsed = source.m_memUsed;
m_height = source.m_height;
m_pNoiseMap = source.m_pNoiseMap;
m_stride = source.m_stride;
m_width = source.m_width;
// Now that the source buffer is assigned to this noise map, reset the
// source noise map object.
source.InitObj ();
}
//////////////////////////////////////////////////////////////////////////////
// Image class
Image::Image ()
{
InitObj ();
}
Image::Image (int width, int height)
{
InitObj ();
SetSize (width, height);
}
Image::Image (const Image& rhs)
{
InitObj ();
CopyImage (rhs);
}
Image::~Image ()
{
delete[] m_pImage;
}
Image& Image::operator= (const Image& rhs)
{
CopyImage (rhs);
return *this;
}
void Image::Clear (const Color& value)
{
if (m_pImage != NULL) {
for (int y = 0; y < m_height; y++) {
Color* pDest = GetSlabPtr (0, y);
for (int x = 0; x < m_width; x++) {
*pDest++ = value;
}
}
}
}
void Image::CopyImage (const Image& source)
{
// Resize the image buffer, then copy the slabs from the source image
// buffer to this image buffer.
SetSize (source.GetWidth (), source.GetHeight ());
for (int y = 0; y < source.GetHeight (); y++) {
const Color* pSource = source.GetConstSlabPtr (0, y);
Color* pDest = GetSlabPtr (0, y);
memcpy (pDest, pSource, (size_t)source.GetWidth () * sizeof (float));
}
// Copy the border value as well.
m_borderValue = source.m_borderValue;
}
void Image::DeleteImageAndReset ()
{
delete[] m_pImage;
InitObj ();
}
Color Image::GetValue (int x, int y) const
{
if (m_pImage != NULL) {
if (x >= 0 && x < m_width && y >= 0 && y < m_height) {
return *(GetConstSlabPtr (x, y));
}
}
// The coordinates specified are outside the image. Return the border
// value.
return m_borderValue;
}
void Image::InitObj ()
{
m_pImage = NULL;
m_height = 0;
m_width = 0;
m_stride = 0;
m_memUsed = 0;
m_borderValue = Color (0, 0, 0, 0);
}
void Image::ReclaimMem ()
{
size_t newMemUsage = CalcMinMemUsage (m_width, m_height);
if (m_memUsed > newMemUsage) {
// There is wasted memory. Create the smallest buffer that can fit the
// data and copy the data to it.
Color* pNewImage = NULL;
try {
pNewImage = new Color[newMemUsage];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
memcpy (pNewImage, m_pImage, newMemUsage * sizeof (float));
delete[] m_pImage;
m_pImage = pNewImage;
m_memUsed = newMemUsage;
}
}
void Image::SetSize (int width, int height)
{
if (width < 0 || height < 0
|| width > RASTER_MAX_WIDTH || height > RASTER_MAX_HEIGHT) {
// Invalid width or height.
throw noise::ExceptionInvalidParam ();
} else if (width == 0 || height == 0) {
// An empty image was specified. Delete it and zero out the size member
// variables.
DeleteImageAndReset ();
} else {
// A new image size was specified. Allocate a new image buffer unless
// the current buffer is large enough for the new image (we don't want
// costly reallocations going on.)
size_t newMemUsage = CalcMinMemUsage (width, height);
if (m_memUsed < newMemUsage) {
// The new size is too big for the current image buffer. We need to
// reallocate.
DeleteImageAndReset ();
try {
m_pImage = new Color[newMemUsage];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
m_memUsed = newMemUsage;
}
m_stride = (int)CalcStride (width);
m_width = width;
m_height = height;
}
}
void Image::SetValue (int x, int y, const Color& value)
{
if (m_pImage != NULL) {
if (x >= 0 && x < m_width && y >= 0 && y < m_height) {
*(GetSlabPtr (x, y)) = value;
}
}
}
void Image::TakeOwnership (Image& source)
{
// Copy the values and the image buffer from the source image to this image.
// Now this image pwnz the source buffer.
delete[] m_pImage;
m_memUsed = source.m_memUsed;
m_height = source.m_height;
m_pImage = source.m_pImage;
m_stride = source.m_stride;
m_width = source.m_width;
// Now that the source buffer is assigned to this image, reset the source
// image object.
source.InitObj ();
}
/////////////////////////////////////////////////////////////////////////////
// WriterBMP class
int WriterBMP::CalcWidthByteCount (int width) const
{
return ((width * 3) + 3) & ~0x03;
}
void WriterBMP::WriteDestFile ()
{
if (m_pSourceImage == NULL) {
throw noise::ExceptionInvalidParam ();
}
int width = m_pSourceImage->GetWidth ();
int height = m_pSourceImage->GetHeight ();
// The width of one line in the file must be aligned on a 4-byte boundary.
int bufferSize = CalcWidthByteCount (width);
int destSize = bufferSize * height;
// This buffer holds one horizontal line in the destination file.
noise::uint8* pLineBuffer = NULL;
// File object used to write the file.
std::ofstream os;
os.clear ();
// Allocate a buffer to hold one horizontal line in the bitmap.
try {
pLineBuffer = new noise::uint8[bufferSize];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
// Open the destination file.
os.open (m_destFilename.c_str (), std::ios::out | std::ios::binary);
if (os.fail () || os.bad ()) {
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
// Build the header.
noise::uint8 d[4];
os.write ("BM", 2);
os.write ((char*)UnpackLittle32 (d, destSize + BMP_HEADER_SIZE), 4);
os.write ("\0\0\0\0", 4);
os.write ((char*)UnpackLittle32 (d, (noise::uint32)BMP_HEADER_SIZE), 4);
os.write ((char*)UnpackLittle32 (d, 40), 4); // Palette offset
os.write ((char*)UnpackLittle32 (d, (noise::uint32)width ), 4);
os.write ((char*)UnpackLittle32 (d, (noise::uint32)height), 4);
os.write ((char*)UnpackLittle16 (d, 1 ), 2); // Planes per pixel
os.write ((char*)UnpackLittle16 (d, 24), 2); // Bits per plane
os.write ("\0\0\0\0", 4); // Compression (0 = none)
os.write ((char*)UnpackLittle32 (d, (noise::uint32)destSize), 4);
os.write ((char*)UnpackLittle32 (d, 2834), 4); // X pixels per meter
os.write ((char*)UnpackLittle32 (d, 2834), 4); // Y pixels per meter
os.write ("\0\0\0\0", 4);
os.write ("\0\0\0\0", 4);
if (os.fail () || os.bad ()) {
os.clear ();
os.close ();
os.clear ();
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
// Build and write each horizontal line to the file.
for (int y = 0; y < height; y++) {
memset (pLineBuffer, 0, bufferSize);
Color* pSource = m_pSourceImage->GetSlabPtr (y);
noise::uint8* pDest = pLineBuffer;
for (int x = 0; x < width; x++) {
*pDest++ = pSource->blue ;
*pDest++ = pSource->green;
*pDest++ = pSource->red ;
++pSource;
}
os.write ((char*)pLineBuffer, (size_t)bufferSize);
if (os.fail () || os.bad ()) {
os.clear ();
os.close ();
os.clear ();
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
}
os.close ();
os.clear ();
delete[] pLineBuffer;
}
/////////////////////////////////////////////////////////////////////////////
// WriterTER class
int WriterTER::CalcWidthByteCount (int width) const
{
return (width * sizeof (int16));
}
void WriterTER::WriteDestFile ()
{
if (m_pSourceNoiseMap == NULL) {
throw noise::ExceptionInvalidParam ();
}
int width = m_pSourceNoiseMap->GetWidth ();
int height = m_pSourceNoiseMap->GetHeight ();
int bufferSize = CalcWidthByteCount (width);
int destSize = bufferSize * height;
// This buffer holds one horizontal line in the destination file.
noise::uint8* pLineBuffer = NULL;
// File object used to write the file.
std::ofstream os;
os.clear ();
// Allocate a buffer to hold one horizontal line in the height map.
try {
pLineBuffer = new noise::uint8[bufferSize];
}
catch (...) {
throw noise::ExceptionOutOfMemory ();
}
// Open the destination file.
os.open (m_destFilename.c_str (), std::ios::out | std::ios::binary);
if (os.fail () || os.bad ()) {
os.clear ();
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
// Build the header.
noise::uint8 d[4];
int16 heightScale = (int16)(floor (32768.0 / (double)m_metersPerPoint));
os.write ("TERRAGENTERRAIN ", 16);
os.write ("SIZE", 4);
os.write ((char*)UnpackLittle16 (d, GetMin (width, height) - 1), 2);
os.write ("\0\0", 2);
os.write ("XPTS", 4);
os.write ((char*)UnpackLittle16 (d, width), 2);
os.write ("\0\0", 2);
os.write ("YPTS", 4);
os.write ((char*)UnpackLittle16 (d, height), 2);
os.write ("\0\0", 2);
os.write ("SCAL", 4);
os.write ((char*)UnpackFloat (d, m_metersPerPoint), 4);
os.write ((char*)UnpackFloat (d, m_metersPerPoint), 4);
os.write ((char*)UnpackFloat (d, m_metersPerPoint), 4);
os.write ("ALTW", 4);
os.write ((char*)UnpackLittle16 (d, heightScale), 2);
os.write ("\0\0", 2);
if (os.fail () || os.bad ()) {
os.clear ();
os.close ();
os.clear ();
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
// Build and write each horizontal line to the file.
for (int y = 0; y < height; y++) {
float* pSource = m_pSourceNoiseMap->GetSlabPtr (y);
noise::uint8* pDest = pLineBuffer;
for (int x = 0; x < width; x++) {
int16 scaledHeight = (int16)(floor (*pSource * 2.0));
UnpackLittle16 (pDest, scaledHeight);
pDest += 2;
++pSource;
}
os.write ((char*)pLineBuffer, (size_t)bufferSize);
if (os.fail () || os.bad ()) {
os.clear ();
os.close ();
os.clear ();
delete[] pLineBuffer;
throw noise::ExceptionUnknown ();
}
}
os.close ();
os.clear ();
delete[] pLineBuffer;
}
/////////////////////////////////////////////////////////////////////////////
// NoiseMapBuilder class
NoiseMapBuilder::NoiseMapBuilder ():
m_pCallback (NULL),
m_destHeight (0),
m_destWidth (0),
m_pDestNoiseMap (NULL),
m_pSourceModule (NULL)
{
}
void NoiseMapBuilder::SetCallback (NoiseMapCallback pCallback)
{
m_pCallback = pCallback;
}
/////////////////////////////////////////////////////////////////////////////
// NoiseMapBuilderCylinder class
NoiseMapBuilderCylinder::NoiseMapBuilderCylinder ():
m_lowerAngleBound (0.0),
m_lowerHeightBound (0.0),
m_upperAngleBound (0.0),
m_upperHeightBound (0.0)
{
}
void NoiseMapBuilderCylinder::Build ()
{
if ( m_upperAngleBound <= m_lowerAngleBound
|| m_upperHeightBound <= m_lowerHeightBound
|| m_destWidth <= 0
|| m_destHeight <= 0
|| m_pSourceModule == NULL
|| m_pDestNoiseMap == NULL) {
throw noise::ExceptionInvalidParam ();
}
// Resize the destination noise map so that it can store the new output
// values from the source model.
m_pDestNoiseMap->SetSize (m_destWidth, m_destHeight);
// Create the cylinder model.
model::Cylinder cylinderModel;
cylinderModel.SetModule (*m_pSourceModule);
double angleExtent = m_upperAngleBound - m_lowerAngleBound ;
double heightExtent = m_upperHeightBound - m_lowerHeightBound;
double xDelta = angleExtent / (double)m_destWidth ;
double yDelta = heightExtent / (double)m_destHeight;
double curAngle = m_lowerAngleBound ;
double curHeight = m_lowerHeightBound;
// Fill every point in the noise map with the output values from the model.
for (int y = 0; y < m_destHeight; y++) {
float* pDest = m_pDestNoiseMap->GetSlabPtr (y);
curAngle = m_lowerAngleBound;
for (int x = 0; x < m_destWidth; x++) {
float curValue = (float)cylinderModel.GetValue (curAngle, curHeight);
*pDest++ = curValue;
curAngle += xDelta;
}
curHeight += yDelta;
if (m_pCallback != NULL) {
m_pCallback (y);
}
}
}
/////////////////////////////////////////////////////////////////////////////
// NoiseMapBuilderPlane class
NoiseMapBuilderPlane::NoiseMapBuilderPlane ():
m_isSeamlessEnabled (false),
m_lowerXBound (0.0),
m_lowerZBound (0.0),
m_upperXBound (0.0),
m_upperZBound (0.0)
{
}
void NoiseMapBuilderPlane::Build ()
{
if ( m_upperXBound <= m_lowerXBound
|| m_upperZBound <= m_lowerZBound
|| m_destWidth <= 0
|| m_destHeight <= 0
|| m_pSourceModule == NULL
|| m_pDestNoiseMap == NULL) {
throw noise::ExceptionInvalidParam ();
}
// Resize the destination noise map so that it can store the new output
// values from the source model.
m_pDestNoiseMap->SetSize (m_destWidth, m_destHeight);
// Create the plane model.
model::Plane planeModel;
planeModel.SetModule (*m_pSourceModule);
double xExtent = m_upperXBound - m_lowerXBound;
double zExtent = m_upperZBound - m_lowerZBound;
double xDelta = xExtent / (double)m_destWidth ;
double zDelta = zExtent / (double)m_destHeight;
double xCur = m_lowerXBound;
double zCur = m_lowerZBound;
// Fill every point in the noise map with the output values from the model.
for (int z = 0; z < m_destHeight; z++) {
float* pDest = m_pDestNoiseMap->GetSlabPtr (z);
xCur = m_lowerXBound;
for (int x = 0; x < m_destWidth; x++) {
float finalValue;
if (!m_isSeamlessEnabled) {
finalValue = planeModel.GetValue (xCur, zCur);
} else {
double swValue, seValue, nwValue, neValue;
swValue = planeModel.GetValue (xCur , zCur );
seValue = planeModel.GetValue (xCur + xExtent, zCur );
nwValue = planeModel.GetValue (xCur , zCur + zExtent);
neValue = planeModel.GetValue (xCur + xExtent, zCur + zExtent);
double xBlend = 1.0 - ((xCur - m_lowerXBound) / xExtent);
double zBlend = 1.0 - ((zCur - m_lowerZBound) / zExtent);
double z0 = LinearInterp (swValue, seValue, xBlend);
double z1 = LinearInterp (nwValue, neValue, xBlend);
finalValue = (float)LinearInterp (z0, z1, zBlend);
}
*pDest++ = finalValue;
xCur += xDelta;
}
zCur += zDelta;
if (m_pCallback != NULL) {
m_pCallback (z);
}
}
}
/////////////////////////////////////////////////////////////////////////////
// NoiseMapBuilderSphere class
NoiseMapBuilderSphere::NoiseMapBuilderSphere ():
m_eastLonBound (0.0),
m_northLatBound (0.0),
m_southLatBound (0.0),
m_westLonBound (0.0)
{
}
void NoiseMapBuilderSphere::Build ()
{
if ( m_eastLonBound <= m_westLonBound
|| m_northLatBound <= m_southLatBound
|| m_destWidth <= 0
|| m_destHeight <= 0
|| m_pSourceModule == NULL
|| m_pDestNoiseMap == NULL) {
throw noise::ExceptionInvalidParam ();
}
// Resize the destination noise map so that it can store the new output
// values from the source model.
m_pDestNoiseMap->SetSize (m_destWidth, m_destHeight);
// Create the plane model.
model::Sphere sphereModel;
sphereModel.SetModule (*m_pSourceModule);
double lonExtent = m_eastLonBound - m_westLonBound ;
double latExtent = m_northLatBound - m_southLatBound;
double xDelta = lonExtent / (double)m_destWidth ;
double yDelta = latExtent / (double)m_destHeight;
double curLon = m_westLonBound ;
double curLat = m_southLatBound;
// Fill every point in the noise map with the output values from the model.
for (int y = 0; y < m_destHeight; y++) {
float* pDest = m_pDestNoiseMap->GetSlabPtr (y);
curLon = m_westLonBound;
for (int x = 0; x < m_destWidth; x++) {
float curValue = (float)sphereModel.GetValue (curLat, curLon);
*pDest++ = curValue;
curLon += xDelta;
}
curLat += yDelta;
if (m_pCallback != NULL) {
m_pCallback (y);
}
}
}
//////////////////////////////////////////////////////////////////////////////
// RendererImage class
RendererImage::RendererImage ():
m_isLightEnabled (false),
m_isWrapEnabled (false),
m_lightAzimuth (45.0),
m_lightBrightness (1.0),
m_lightColor (255, 255, 255, 255),
m_lightContrast (1.0),
m_lightElev (45.0),
m_lightIntensity (1.0),
m_pBackgroundImage (NULL),
m_pDestImage (NULL),
m_pSourceNoiseMap (NULL),
m_recalcLightValues (true)
{
BuildGrayscaleGradient ();
};
void RendererImage::AddGradientPoint (double gradientPos,
const Color& gradientColor)
{
m_gradient.AddGradientPoint (gradientPos, gradientColor);
}
void RendererImage::BuildGrayscaleGradient ()
{
ClearGradient ();
m_gradient.AddGradientPoint (-1.0, Color ( 0, 0, 0, 255));
m_gradient.AddGradientPoint ( 1.0, Color (255, 255, 255, 255));
}
void RendererImage::BuildTerrainGradient ()
{
ClearGradient ();
m_gradient.AddGradientPoint (-1.00, Color ( 0, 0, 128, 255));
m_gradient.AddGradientPoint (-0.20, Color ( 32, 64, 128, 255));
m_gradient.AddGradientPoint (-0.04, Color ( 64, 96, 192, 255));
m_gradient.AddGradientPoint (-0.02, Color (192, 192, 128, 255));
m_gradient.AddGradientPoint ( 0.00, Color ( 0, 192, 0, 255));
m_gradient.AddGradientPoint ( 0.25, Color (192, 192, 0, 255));
m_gradient.AddGradientPoint ( 0.50, Color (160, 96, 64, 255));
m_gradient.AddGradientPoint ( 0.75, Color (128, 255, 255, 255));
m_gradient.AddGradientPoint ( 1.00, Color (255, 255, 255, 255));
}
Color RendererImage::CalcDestColor (const Color& sourceColor,
const Color& backgroundColor, double lightValue) const
{
double sourceRed = (double)sourceColor.red / 255.0;
double sourceGreen = (double)sourceColor.green / 255.0;
double sourceBlue = (double)sourceColor.blue / 255.0;
double sourceAlpha = (double)sourceColor.alpha / 255.0;
double backgroundRed = (double)backgroundColor.red / 255.0;
double backgroundGreen = (double)backgroundColor.green / 255.0;
double backgroundBlue = (double)backgroundColor.blue / 255.0;