/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2020 - Raw Material Software Limited JUCE is an open source library subject to commercial or open-source licensing. By using JUCE, you agree to the terms of both the JUCE 6 End-User License Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020). End User License Agreement: www.juce.com/juce-6-licence Privacy Policy: www.juce.com/juce-privacy-policy Or: You may also use this code under the terms of the GPL v3 (see www.gnu.org/licenses). JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { ImagePixelData::ImagePixelData (Image::PixelFormat format, int w, int h) : pixelFormat (format), width (w), height (h) { jassert (format == Image::RGB || format == Image::ARGB || format == Image::SingleChannel); jassert (w > 0 && h > 0); // It's illegal to create a zero-sized image! } ImagePixelData::~ImagePixelData() { listeners.call ([this] (Listener& l) { l.imageDataBeingDeleted (this); }); } void ImagePixelData::sendDataChangeMessage() { listeners.call ([this] (Listener& l) { l.imageDataChanged (this); }); } int ImagePixelData::getSharedCount() const noexcept { return getReferenceCount(); } //============================================================================== ImageType::ImageType() {} ImageType::~ImageType() {} Image ImageType::convert (const Image& source) const { if (source.isNull() || getTypeID() == source.getPixelData()->createType()->getTypeID()) return source; const Image::BitmapData src (source, Image::BitmapData::readOnly); Image newImage (create (src.pixelFormat, src.width, src.height, false)); Image::BitmapData dest (newImage, Image::BitmapData::writeOnly); if (src.pixelStride == dest.pixelStride && src.pixelFormat == dest.pixelFormat) { for (int y = 0; y < dest.height; ++y) memcpy (dest.getLinePointer (y), src.getLinePointer (y), (size_t) dest.lineStride); } else { for (int y = 0; y < dest.height; ++y) for (int x = 0; x < dest.width; ++x) dest.setPixelColour (x, y, src.getPixelColour (x, y)); } return newImage; } //============================================================================== class SoftwarePixelData : public ImagePixelData { public: SoftwarePixelData (Image::PixelFormat formatToUse, int w, int h, bool clearImage) : ImagePixelData (formatToUse, w, h), pixelStride (formatToUse == Image::RGB ? 3 : ((formatToUse == Image::ARGB) ? 4 : 1)), lineStride ((pixelStride * jmax (1, w) + 3) & ~3) { imageData.allocate ((size_t) lineStride * (size_t) jmax (1, h), clearImage); } std::unique_ptr createLowLevelContext() override { sendDataChangeMessage(); return std::make_unique (Image (*this)); } void initialiseBitmapData (Image::BitmapData& bitmap, int x, int y, Image::BitmapData::ReadWriteMode mode) override { bitmap.data = imageData + (size_t) x * (size_t) pixelStride + (size_t) y * (size_t) lineStride; bitmap.pixelFormat = pixelFormat; bitmap.lineStride = lineStride; bitmap.pixelStride = pixelStride; if (mode != Image::BitmapData::readOnly) sendDataChangeMessage(); } ImagePixelData::Ptr clone() override { auto s = new SoftwarePixelData (pixelFormat, width, height, false); memcpy (s->imageData, imageData, (size_t) lineStride * (size_t) height); return *s; } std::unique_ptr createType() const override { return std::make_unique(); } private: HeapBlock imageData; const int pixelStride, lineStride; JUCE_LEAK_DETECTOR (SoftwarePixelData) }; SoftwareImageType::SoftwareImageType() {} SoftwareImageType::~SoftwareImageType() {} ImagePixelData::Ptr SoftwareImageType::create (Image::PixelFormat format, int width, int height, bool clearImage) const { return *new SoftwarePixelData (format, width, height, clearImage); } int SoftwareImageType::getTypeID() const { return 2; } //============================================================================== NativeImageType::NativeImageType() {} NativeImageType::~NativeImageType() {} int NativeImageType::getTypeID() const { return 1; } #if JUCE_WINDOWS || JUCE_LINUX ImagePixelData::Ptr NativeImageType::create (Image::PixelFormat format, int width, int height, bool clearImage) const { return new SoftwarePixelData (format, width, height, clearImage); } #endif //============================================================================== class SubsectionPixelData : public ImagePixelData { public: SubsectionPixelData (ImagePixelData::Ptr source, Rectangle r) : ImagePixelData (source->pixelFormat, r.getWidth(), r.getHeight()), sourceImage (std::move (source)), area (r) { } std::unique_ptr createLowLevelContext() override { auto g = sourceImage->createLowLevelContext(); g->clipToRectangle (area); g->setOrigin (area.getPosition()); return g; } void initialiseBitmapData (Image::BitmapData& bitmap, int x, int y, Image::BitmapData::ReadWriteMode mode) override { sourceImage->initialiseBitmapData (bitmap, x + area.getX(), y + area.getY(), mode); if (mode != Image::BitmapData::readOnly) sendDataChangeMessage(); } ImagePixelData::Ptr clone() override { jassert (getReferenceCount() > 0); // (This method can't be used on an unowned pointer, as it will end up self-deleting) auto type = createType(); Image newImage (type->create (pixelFormat, area.getWidth(), area.getHeight(), pixelFormat != Image::RGB)); { Graphics g (newImage); g.drawImageAt (Image (*this), 0, 0); } return *newImage.getPixelData(); } std::unique_ptr createType() const override { return sourceImage->createType(); } /* as we always hold a reference to image, don't double count */ int getSharedCount() const noexcept override { return getReferenceCount() + sourceImage->getSharedCount() - 1; } private: friend class Image; const ImagePixelData::Ptr sourceImage; const Rectangle area; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (SubsectionPixelData) }; Image Image::getClippedImage (const Rectangle& area) const { if (area.contains (getBounds())) return *this; auto validArea = area.getIntersection (getBounds()); if (validArea.isEmpty()) return {}; return Image (*new SubsectionPixelData (image, validArea)); } //============================================================================== Image::Image() noexcept { } Image::Image (ReferenceCountedObjectPtr instance) noexcept : image (std::move (instance)) { } Image::Image (PixelFormat format, int width, int height, bool clearImage) : image (NativeImageType().create (format, width, height, clearImage)) { } Image::Image (PixelFormat format, int width, int height, bool clearImage, const ImageType& type) : image (type.create (format, width, height, clearImage)) { } Image::Image (const Image& other) noexcept : image (other.image) { } Image& Image::operator= (const Image& other) { image = other.image; return *this; } Image::Image (Image&& other) noexcept : image (std::move (other.image)) { } Image& Image::operator= (Image&& other) noexcept { image = std::move (other.image); return *this; } Image::~Image() { } JUCE_DECLARE_DEPRECATED_STATIC (const Image Image::null;) int Image::getReferenceCount() const noexcept { return image == nullptr ? 0 : image->getSharedCount(); } int Image::getWidth() const noexcept { return image == nullptr ? 0 : image->width; } int Image::getHeight() const noexcept { return image == nullptr ? 0 : image->height; } Rectangle Image::getBounds() const noexcept { return image == nullptr ? Rectangle() : Rectangle (image->width, image->height); } Image::PixelFormat Image::getFormat() const noexcept { return image == nullptr ? UnknownFormat : image->pixelFormat; } bool Image::isARGB() const noexcept { return getFormat() == ARGB; } bool Image::isRGB() const noexcept { return getFormat() == RGB; } bool Image::isSingleChannel() const noexcept { return getFormat() == SingleChannel; } bool Image::hasAlphaChannel() const noexcept { return getFormat() != RGB; } std::unique_ptr Image::createLowLevelContext() const { if (image != nullptr) return image->createLowLevelContext(); return {}; } void Image::duplicateIfShared() { if (getReferenceCount() > 1) image = image->clone(); } Image Image::createCopy() const { if (image != nullptr) return Image (image->clone()); return {}; } Image Image::rescaled (int newWidth, int newHeight, Graphics::ResamplingQuality quality) const { if (image == nullptr || (image->width == newWidth && image->height == newHeight)) return *this; auto type = image->createType(); Image newImage (type->create (image->pixelFormat, newWidth, newHeight, hasAlphaChannel())); Graphics g (newImage); g.setImageResamplingQuality (quality); g.drawImageTransformed (*this, AffineTransform::scale ((float) newWidth / (float) image->width, (float) newHeight / (float) image->height), false); return newImage; } Image Image::convertedToFormat (PixelFormat newFormat) const { if (image == nullptr || newFormat == image->pixelFormat) return *this; auto w = image->width, h = image->height; auto type = image->createType(); Image newImage (type->create (newFormat, w, h, false)); if (newFormat == SingleChannel) { if (! hasAlphaChannel()) { newImage.clear (getBounds(), Colours::black); } else { const BitmapData destData (newImage, 0, 0, w, h, BitmapData::writeOnly); const BitmapData srcData (*this, 0, 0, w, h); for (int y = 0; y < h; ++y) { auto src = reinterpret_cast (srcData.getLinePointer (y)); auto dst = destData.getLinePointer (y); for (int x = 0; x < w; ++x) dst[x] = src[x].getAlpha(); } } } else if (image->pixelFormat == SingleChannel && newFormat == Image::ARGB) { const BitmapData destData (newImage, 0, 0, w, h, BitmapData::writeOnly); const BitmapData srcData (*this, 0, 0, w, h); for (int y = 0; y < h; ++y) { auto src = reinterpret_cast (srcData.getLinePointer (y)); auto dst = reinterpret_cast (destData.getLinePointer (y)); for (int x = 0; x < w; ++x) dst[x].set (src[x]); } } else { if (hasAlphaChannel()) newImage.clear (getBounds()); Graphics g (newImage); g.drawImageAt (*this, 0, 0); } return newImage; } NamedValueSet* Image::getProperties() const { return image == nullptr ? nullptr : &(image->userData); } //============================================================================== Image::BitmapData::BitmapData (Image& im, int x, int y, int w, int h, BitmapData::ReadWriteMode mode) : width (w), height (h) { // The BitmapData class must be given a valid image, and a valid rectangle within it! jassert (im.image != nullptr); jassert (x >= 0 && y >= 0 && w > 0 && h > 0 && x + w <= im.getWidth() && y + h <= im.getHeight()); im.image->initialiseBitmapData (*this, x, y, mode); jassert (data != nullptr && pixelStride > 0 && lineStride != 0); } Image::BitmapData::BitmapData (const Image& im, int x, int y, int w, int h) : width (w), height (h) { // The BitmapData class must be given a valid image, and a valid rectangle within it! jassert (im.image != nullptr); jassert (x >= 0 && y >= 0 && w > 0 && h > 0 && x + w <= im.getWidth() && y + h <= im.getHeight()); im.image->initialiseBitmapData (*this, x, y, readOnly); jassert (data != nullptr && pixelStride > 0 && lineStride != 0); } Image::BitmapData::BitmapData (const Image& im, BitmapData::ReadWriteMode mode) : width (im.getWidth()), height (im.getHeight()) { // The BitmapData class must be given a valid image! jassert (im.image != nullptr); im.image->initialiseBitmapData (*this, 0, 0, mode); jassert (data != nullptr && pixelStride > 0 && lineStride != 0); } Image::BitmapData::~BitmapData() { } Colour Image::BitmapData::getPixelColour (int x, int y) const noexcept { jassert (isPositiveAndBelow (x, width) && isPositiveAndBelow (y, height)); auto pixel = getPixelPointer (x, y); switch (pixelFormat) { case Image::ARGB: return Colour ( ((const PixelARGB*) pixel)->getUnpremultiplied()); case Image::RGB: return Colour (*((const PixelRGB*) pixel)); case Image::SingleChannel: return Colour (*((const PixelAlpha*) pixel)); case Image::UnknownFormat: default: jassertfalse; break; } return {}; } void Image::BitmapData::setPixelColour (int x, int y, Colour colour) const noexcept { jassert (isPositiveAndBelow (x, width) && isPositiveAndBelow (y, height)); auto pixel = getPixelPointer (x, y); auto col = colour.getPixelARGB(); switch (pixelFormat) { case Image::ARGB: ((PixelARGB*) pixel)->set (col); break; case Image::RGB: ((PixelRGB*) pixel)->set (col); break; case Image::SingleChannel: ((PixelAlpha*) pixel)->set (col); break; case Image::UnknownFormat: default: jassertfalse; break; } } //============================================================================== void Image::clear (const Rectangle& area, Colour colourToClearTo) { if (image != nullptr) { auto g = image->createLowLevelContext(); g->setFill (colourToClearTo); g->fillRect (area, true); } } //============================================================================== Colour Image::getPixelAt (int x, int y) const { if (isPositiveAndBelow (x, getWidth()) && isPositiveAndBelow (y, getHeight())) { const BitmapData srcData (*this, x, y, 1, 1); return srcData.getPixelColour (0, 0); } return {}; } void Image::setPixelAt (int x, int y, Colour colour) { if (isPositiveAndBelow (x, getWidth()) && isPositiveAndBelow (y, getHeight())) { const BitmapData destData (*this, x, y, 1, 1, BitmapData::writeOnly); destData.setPixelColour (0, 0, colour); } } void Image::multiplyAlphaAt (int x, int y, float multiplier) { if (isPositiveAndBelow (x, getWidth()) && isPositiveAndBelow (y, getHeight()) && hasAlphaChannel()) { const BitmapData destData (*this, x, y, 1, 1, BitmapData::readWrite); if (isARGB()) reinterpret_cast (destData.data)->multiplyAlpha (multiplier); else *(destData.data) = (uint8) (*(destData.data) * multiplier); } } template struct PixelIterator { template static void iterate (const Image::BitmapData& data, const PixelOperation& pixelOp) { for (int y = 0; y < data.height; ++y) { auto p = data.getLinePointer (y); for (int x = 0; x < data.width; ++x) { pixelOp (*reinterpret_cast (p)); p += data.pixelStride; } } } }; template static void performPixelOp (const Image::BitmapData& data, const PixelOperation& pixelOp) { switch (data.pixelFormat) { case Image::ARGB: PixelIterator ::iterate (data, pixelOp); break; case Image::RGB: PixelIterator ::iterate (data, pixelOp); break; case Image::SingleChannel: PixelIterator::iterate (data, pixelOp); break; case Image::UnknownFormat: default: jassertfalse; break; } } struct AlphaMultiplyOp { float alpha; template void operator() (PixelType& pixel) const { pixel.multiplyAlpha (alpha); } }; void Image::multiplyAllAlphas (float amountToMultiplyBy) { jassert (hasAlphaChannel()); const BitmapData destData (*this, 0, 0, getWidth(), getHeight(), BitmapData::readWrite); performPixelOp (destData, AlphaMultiplyOp { amountToMultiplyBy }); } struct DesaturateOp { template void operator() (PixelType& pixel) const { pixel.desaturate(); } }; void Image::desaturate() { if (isARGB() || isRGB()) { const BitmapData destData (*this, 0, 0, getWidth(), getHeight(), BitmapData::readWrite); performPixelOp (destData, DesaturateOp()); } } void Image::createSolidAreaMask (RectangleList& result, float alphaThreshold) const { if (hasAlphaChannel()) { auto threshold = (uint8) jlimit (0, 255, roundToInt (alphaThreshold * 255.0f)); SparseSet pixelsOnRow; const BitmapData srcData (*this, 0, 0, getWidth(), getHeight()); for (int y = 0; y < srcData.height; ++y) { pixelsOnRow.clear(); auto lineData = srcData.getLinePointer (y); if (isARGB()) { for (int x = 0; x < srcData.width; ++x) { if (reinterpret_cast (lineData)->getAlpha() >= threshold) pixelsOnRow.addRange (Range (x, x + 1)); lineData += srcData.pixelStride; } } else { for (int x = 0; x < srcData.width; ++x) { if (*lineData >= threshold) pixelsOnRow.addRange (Range (x, x + 1)); lineData += srcData.pixelStride; } } for (int i = 0; i < pixelsOnRow.getNumRanges(); ++i) { auto range = pixelsOnRow.getRange (i); result.add (Rectangle (range.getStart(), y, range.getLength(), 1)); } result.consolidate(); } } else { result.add (0, 0, getWidth(), getHeight()); } } void Image::moveImageSection (int dx, int dy, int sx, int sy, int w, int h) { if (dx < 0) { w += dx; sx -= dx; dx = 0; } if (dy < 0) { h += dy; sy -= dy; dy = 0; } if (sx < 0) { w += sx; dx -= sx; sx = 0; } if (sy < 0) { h += sy; dy -= sy; sy = 0; } const int minX = jmin (dx, sx); const int minY = jmin (dy, sy); w = jmin (w, getWidth() - jmax (sx, dx)); h = jmin (h, getHeight() - jmax (sy, dy)); if (w > 0 && h > 0) { auto maxX = jmax (dx, sx) + w; auto maxY = jmax (dy, sy) + h; const BitmapData destData (*this, minX, minY, maxX - minX, maxY - minY, BitmapData::readWrite); auto dst = destData.getPixelPointer (dx - minX, dy - minY); auto src = destData.getPixelPointer (sx - minX, sy - minY); auto lineSize = (size_t) destData.pixelStride * (size_t) w; if (dy > sy) { while (--h >= 0) { const int offset = h * destData.lineStride; memmove (dst + offset, src + offset, lineSize); } } else if (dst != src) { while (--h >= 0) { memmove (dst, src, lineSize); dst += destData.lineStride; src += destData.lineStride; } } } } } // namespace juce