/* Copyright (C) 2010 Kimmo Pekkola, MattKing, spx This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "StdAfx.h" #include "TintedImage.h" #include "ConfigParser.h" #include "Error.h" #include "Litestep.h" using namespace Gdiplus; #define PI (3.14159265f) #define CONVERT_TO_RADIANS(X) ((X) * (PI / 180.0f)) // GrayScale Matrix const Gdiplus::ColorMatrix CTintedImage::c_GreyScaleMatrix = { 0.299f, 0.299f, 0.299f, 0.0f, 0.0f, 0.587f, 0.587f, 0.587f, 0.0f, 0.0f, 0.114f, 0.114f, 0.114f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f }; const Gdiplus::ColorMatrix CTintedImage::c_IdentifyMatrix = { 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f }; CTintedImageHelper_DefineConfigArray(CTintedImage::c_DefaultConfigArray, L""); /* ** CTintedImage ** ** The constructor. ** ** If disableTransform is true, following configs are ignored: ** - ImageCrop ** - ImageRotate ** */ CTintedImage::CTintedImage(const WCHAR* name, const WCHAR** configArray, bool disableTransform) : m_DisableTransform(disableTransform), m_ConfigName(name ? name : L"Image"), m_ConfigArray(configArray ? configArray : c_DefaultConfigArray), m_Bitmap(), m_BitmapTint(), m_hBuffer(), m_Modified(), m_NeedsCrop(false), m_NeedsTinting(false), m_NeedsTransform(false), m_Crop(-1, -1, -1, -1), m_CropMode(CROPMODE_TL), m_GreyScale(false), m_ColorMatrix(new ColorMatrix), m_Flip(RotateNoneFlipNone), m_Rotate() { *m_ColorMatrix = c_IdentifyMatrix; } /* ** ~CTintedImage ** ** The destructor ** */ CTintedImage::~CTintedImage() { DisposeImage(); delete m_ColorMatrix; } /* ** DisposeImage ** ** Disposes the image buffers. ** */ void CTintedImage::DisposeImage() { delete m_Bitmap; m_Bitmap = NULL; delete m_BitmapTint; m_BitmapTint = NULL; if (m_hBuffer) { ::GlobalFree(m_hBuffer); m_hBuffer = NULL; } m_Modified.dwHighDateTime = 0; m_Modified.dwLowDateTime = 0; } /* ** LoadImageFromFileHandle ** ** Loads the image from file handle ** */ bool CTintedImage::LoadImageFromFileHandle(HANDLE fileHandle, Bitmap** pBitmap, HGLOBAL* phBuffer) { DWORD imageSize = GetFileSize(fileHandle, NULL); if (imageSize != INVALID_FILE_SIZE) { HGLOBAL hBuffer = ::GlobalAlloc(GMEM_MOVEABLE, imageSize); if (hBuffer) { void* pBuffer = ::GlobalLock(hBuffer); if (pBuffer) { DWORD readBytes; ReadFile(fileHandle, pBuffer, imageSize, &readBytes, NULL); ::GlobalUnlock(hBuffer); IStream* pStream = NULL; if (::CreateStreamOnHGlobal(hBuffer, FALSE, &pStream) == S_OK) { Bitmap* bitmap = Bitmap::FromStream(pStream); pStream->Release(); if (bitmap && Ok == bitmap->GetLastStatus()) { *pBitmap = bitmap; *phBuffer = hBuffer; return true; } else { delete bitmap; } } } ::GlobalFree(hBuffer); } } return false; } /* ** LoadImage ** ** Loads the image from disk ** */ void CTintedImage::LoadImage(const std::wstring& imageName, bool bLoadAlways) { // Load the bitmap if defined if (!imageName.empty()) { std::wstring filename = imageName; // Check extension and if it is missing, add .png size_t pos = filename.find_last_of(L"\\"); if (pos == std::wstring::npos) pos = 0; if (std::wstring::npos == filename.find(L'.', pos)) { filename += L".png"; } // Read the bitmap to memory so that it's not locked by GDI+ HANDLE fileHandle = CreateFile(filename.c_str(), GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL | FILE_FLAG_SEQUENTIAL_SCAN, NULL); if (fileHandle != INVALID_HANDLE_VALUE) { // Compare the timestamp and filename to check if the file has been changed (don't load if it's not) FILETIME tmpTime; GetFileTime(fileHandle, NULL, NULL, &tmpTime); if (bLoadAlways || CompareFileTime(&tmpTime, &m_Modified) != 0) { DisposeImage(); if (LoadImageFromFileHandle(fileHandle, &m_Bitmap, &m_hBuffer)) { m_Modified = tmpTime; // Check whether the new image needs tinting (or cropping, flipping, rotating) if (!m_NeedsCrop) { if (m_Crop.Width >= 0 || m_Crop.Height >= 0) { m_NeedsCrop = true; } } if (!m_NeedsTinting) { if (m_GreyScale || !CompareColorMatrix(m_ColorMatrix, &c_IdentifyMatrix)) { m_NeedsTinting = true; } } if (!m_NeedsTransform) { if (m_Flip != RotateNoneFlipNone || m_Rotate != 0.0f) { m_NeedsTransform = true; } } } else { LogWithArgs(LOG_ERROR, L"Unable to load %s: %s", m_ConfigName.c_str(), filename.c_str()); } } CloseHandle(fileHandle); if (m_Bitmap) { // We need a copy of the image if has tinting (or flipping, rotating) if (m_NeedsCrop || m_NeedsTinting || m_NeedsTransform) { if (m_BitmapTint) { delete m_BitmapTint; m_BitmapTint = NULL; } if (m_Bitmap->GetWidth() > 0 && m_Bitmap->GetHeight() > 0) { ApplyCrop(); if (!m_BitmapTint || (m_BitmapTint->GetWidth() > 0 && m_BitmapTint->GetHeight() > 0)) { ApplyTint(); ApplyTransform(); } } m_NeedsCrop = false; m_NeedsTinting = false; m_NeedsTransform = false; } } } else { LogWithArgs(LOG_ERROR, L"Unable to open %s: %s", m_ConfigName.c_str(), filename.c_str()); DisposeImage(); } } else if (IsLoaded()) { DisposeImage(); } } /* ** ApplyCrop ** ** This will apply the cropping. ** */ void CTintedImage::ApplyCrop() { if (m_Crop.Width >= 0 && m_Crop.Height >= 0) { if (m_Crop.Width == 0 || m_Crop.Height == 0) { m_BitmapTint = new Bitmap(0, 0, PixelFormat32bppPARGB); // create dummy bitmap } else { int imageW = m_Bitmap->GetWidth(); int imageH = m_Bitmap->GetHeight(); int x, y; switch (m_CropMode) { case CROPMODE_TL: default: x = m_Crop.X; y = m_Crop.Y; break; case CROPMODE_TR: x = m_Crop.X + imageW; y = m_Crop.Y; break; case CROPMODE_BR: x = m_Crop.X + imageW; y = m_Crop.Y + imageH; break; case CROPMODE_BL: x = m_Crop.X; y = m_Crop.Y + imageH; break; case CROPMODE_C: x = m_Crop.X + (imageW / 2); y = m_Crop.Y + (imageH / 2); break; } Rect r(0, 0, m_Crop.Width, m_Crop.Height); m_BitmapTint = new Bitmap(r.Width, r.Height, PixelFormat32bppPARGB); Graphics graphics(m_BitmapTint); graphics.DrawImage(m_Bitmap, r, x, y, r.Width, r.Height, UnitPixel); } } } /* ** ApplyTint ** ** This will apply the Greyscale matrix and the color tinting. ** */ void CTintedImage::ApplyTint() { if (m_GreyScale || !CompareColorMatrix(m_ColorMatrix, &c_IdentifyMatrix)) { Bitmap* original = GetImage(); ImageAttributes ImgAttr; ImgAttr.SetColorMatrix(m_ColorMatrix, ColorMatrixFlagsDefault, ColorAdjustTypeBitmap); Rect r(0, 0, original->GetWidth(), original->GetHeight()); Bitmap* tint = new Bitmap(r.Width, r.Height, PixelFormat32bppPARGB); Graphics graphics(tint); if (m_GreyScale) { Bitmap* gray = TurnGreyscale(original); graphics.DrawImage(gray, r, 0, 0, r.Width, r.Height, UnitPixel, &ImgAttr); delete gray; } else { graphics.DrawImage(original, r, 0, 0, r.Width, r.Height, UnitPixel, &ImgAttr); } delete m_BitmapTint; m_BitmapTint = tint; } } /* ** TurnGreyscale ** ** Turns the image greyscale by applying a greyscale color matrix. ** Note that the returned bitmap image must be freed by caller. ** */ Bitmap* CTintedImage::TurnGreyscale(Bitmap* source) { ImageAttributes ImgAttr; ImgAttr.SetColorMatrix(&c_GreyScaleMatrix, ColorMatrixFlagsDefault, ColorAdjustTypeBitmap); // We need a blank bitmap to paint our greyscale to in case of alpha Rect r(0, 0, source->GetWidth(), source->GetHeight()); Bitmap* bitmap = new Bitmap(r.Width, r.Height, PixelFormat32bppPARGB); Graphics graphics(bitmap); graphics.DrawImage(source, r, 0, 0, r.Width, r.Height, UnitPixel, &ImgAttr); return bitmap; } /* ** ApplyTransform ** ** This will apply the flipping and rotating. ** */ void CTintedImage::ApplyTransform() { if (m_Rotate != 0.0f) { Bitmap* original = GetImage(); REAL originalW = (REAL)original->GetWidth(); REAL originalH = (REAL)original->GetHeight(); REAL cos_f = cos(CONVERT_TO_RADIANS(m_Rotate)), sin_f = sin(CONVERT_TO_RADIANS(m_Rotate)); REAL transformW = fabs(originalW * cos_f) + fabs(originalH * sin_f); REAL transformH = fabs(originalW * sin_f) + fabs(originalH * cos_f); Bitmap* transform = new Bitmap((int)(transformW + 0.5f), (int)(transformH + 0.5f), PixelFormat32bppPARGB); Graphics graphics(transform); graphics.SetPixelOffsetMode(PixelOffsetModeHighQuality); REAL cx = transformW / 2.0f; REAL cy = transformH / 2.0f; Matrix rotateMatrix; rotateMatrix.RotateAt(m_Rotate, PointF(cx, cy)); graphics.SetTransform(&rotateMatrix); if (m_Flip != RotateNoneFlipNone) { original->RotateFlip(m_Flip); } RectF r(cx - originalW / 2.0f, cy - originalH / 2.0f, originalW, originalH); graphics.DrawImage(original, r, -0.5f, -0.5f, originalW + 1.0f, originalH + 1.0f, UnitPixel); // Makes the anti-aliased edge if (m_Flip != RotateNoneFlipNone) { original->RotateFlip(RotateNoneFlipNone); } delete m_BitmapTint; m_BitmapTint = transform; } else if (m_Flip != RotateNoneFlipNone) { Bitmap* original = GetImage(); Rect r(0, 0, original->GetWidth(), original->GetHeight()); Bitmap* transform = new Bitmap(r.Width, r.Height, PixelFormat32bppPARGB); Graphics graphics(transform); original->RotateFlip(m_Flip); graphics.DrawImage(original, r, 0, 0, r.Width, r.Height, UnitPixel); original->RotateFlip(RotateNoneFlipNone); delete m_BitmapTint; m_BitmapTint = transform; } } /* ** ReadConfig ** ** Read the meter-specific configs from the ini-file. ** */ void CTintedImage::ReadConfig(CConfigParser& parser, const WCHAR* section) { // Store the current values so we know if the image needs to be tinted or transformed Rect oldCrop = m_Crop; CROPMODE oldCropMode = m_CropMode; bool oldGreyScale = m_GreyScale; ColorMatrix oldColorMatrix = *m_ColorMatrix; RotateFlipType oldFlip = m_Flip; REAL oldRotate = m_Rotate; if (!m_DisableTransform) { m_Crop.X = m_Crop.Y = m_Crop.Width = m_Crop.Height = -1; m_CropMode = CROPMODE_TL; std::wstring crop = parser.ReadString(section, m_ConfigArray[ConfigIndexImageCrop], L""); if (!crop.empty()) { if (wcschr(crop.c_str(), L',')) { WCHAR* parseSz = _wcsdup(crop.c_str()); WCHAR* token; token = wcstok(parseSz, L","); if (token) { m_Crop.X = _wtoi(token); } token = wcstok(NULL, L","); if (token) { m_Crop.Y = _wtoi(token); } token = wcstok(NULL, L","); if (token) { m_Crop.Width = _wtoi(token); } token = wcstok(NULL, L","); if (token) { m_Crop.Height = _wtoi(token); } token = wcstok(NULL, L","); if (token) { m_CropMode = (CROPMODE)_wtoi(token); } free(parseSz); } if (m_CropMode < CROPMODE_TL || m_CropMode > CROPMODE_C) { std::wstring error = m_ConfigArray[ConfigIndexImageCrop]; error += L"="; error += crop; error += L" (origin) is not valid in meter ["; error += section; error += L"]."; throw CError(error, __LINE__, __FILE__); } } } m_NeedsCrop = (oldCrop.X != m_Crop.X || oldCrop.Y != m_Crop.Y || oldCrop.Width != m_Crop.Width || oldCrop.Height != m_Crop.Height || oldCropMode != m_CropMode); m_GreyScale = 0!=parser.ReadInt(section, m_ConfigArray[ConfigIndexGreyscale], 0); Color tint = parser.ReadColor(section, m_ConfigArray[ConfigIndexImageTint], Color::White); int alpha = parser.ReadInt(section, m_ConfigArray[ConfigIndexImageAlpha], tint.GetAlpha()); // for backwards compatibility alpha = min(255, alpha); alpha = max(0, alpha); *m_ColorMatrix = c_IdentifyMatrix; // Read in the Color Matrix // It has to be read in like this because it crashes when reading over 17 floats // at one time. The parser does it fine, but after putting the returned values // into the Color Matrix the next time the parser is used it crashes. std::vector matrix1 = parser.ReadFloats(section, m_ConfigArray[ConfigIndexColorMatrix1]); if (matrix1.size() == 5) { for (int i = 0; i < 4; ++i) // The fifth column must be 0. { m_ColorMatrix->m[0][i] = matrix1[i]; } } else { m_ColorMatrix->m[0][0] = (REAL)tint.GetRed() / 255.0f; } std::vector matrix2 = parser.ReadFloats(section, m_ConfigArray[ConfigIndexColorMatrix2]); if (matrix2.size() == 5) { for(int i = 0; i < 4; ++i) // The fifth column must be 0. { m_ColorMatrix->m[1][i] = matrix2[i]; } } else { m_ColorMatrix->m[1][1] = (REAL)tint.GetGreen() / 255.0f; } std::vector matrix3 = parser.ReadFloats(section, m_ConfigArray[ConfigIndexColorMatrix3]); if (matrix3.size() == 5) { for(int i = 0; i < 4; ++i) // The fifth column must be 0. { m_ColorMatrix->m[2][i] = matrix3[i]; } } else { m_ColorMatrix->m[2][2] = (REAL)tint.GetBlue() / 255.0f; } std::vector matrix4 = parser.ReadFloats(section, m_ConfigArray[ConfigIndexColorMatrix4]); if (matrix4.size() == 5) { for(int i = 0; i < 4; ++i) // The fifth column must be 0. { m_ColorMatrix->m[3][i] = matrix4[i]; } } else { m_ColorMatrix->m[3][3] = (REAL)alpha / 255.0f; } std::vector matrix5 = parser.ReadFloats(section, m_ConfigArray[ConfigIndexColorMatrix5]); if (matrix5.size() == 5) { for(int i = 0; i < 4; ++i) // The fifth column must be 1. { m_ColorMatrix->m[4][i] = matrix5[i]; } } m_NeedsTinting = (oldGreyScale != m_GreyScale || !CompareColorMatrix(&oldColorMatrix, m_ColorMatrix)); std::wstring flip = parser.ReadString(section, m_ConfigArray[ConfigIndexImageFlip], L"NONE"); if(_wcsicmp(flip.c_str(), L"NONE") == 0) { m_Flip = RotateNoneFlipNone; } else if(_wcsicmp(flip.c_str(), L"HORIZONTAL") == 0) { m_Flip = RotateNoneFlipX; } else if(_wcsicmp(flip.c_str(), L"VERTICAL") == 0) { m_Flip = RotateNoneFlipY; } else if(_wcsicmp(flip.c_str(), L"BOTH") == 0) { m_Flip = RotateNoneFlipXY; } else { std::wstring error = m_ConfigArray[ConfigIndexImageFlip]; error += L"="; error += flip; error += L" is not valid in meter ["; error += section; error += L"]."; throw CError(error, __LINE__, __FILE__); } if (!m_DisableTransform) { m_Rotate = (REAL)parser.ReadFloat(section, m_ConfigArray[ConfigIndexImageRotate], 0.0); } m_NeedsTransform = (oldFlip != m_Flip || oldRotate != m_Rotate); } /* ** CompareColorMatrix ** ** Compares the two given color matrices. ** */ bool CTintedImage::CompareColorMatrix(const Gdiplus::ColorMatrix* a, const Gdiplus::ColorMatrix* b) { for (int i = 0; i < 5; ++i) { for (int j = 0; j < 4; ++j) // The fifth column is reserved. { if (a->m[i][j] != b->m[i][j]) { return false; } } } return true; }