//////////////////////////////////////////////////////////// // // SFML - Simple and Fast Multimedia Library // Copyright (C) 2007-2015 Laurent Gomila (laurent@sfml-dev.org) // // This software is provided 'as-is', without any express or implied warranty. // In no event will the authors be held liable for any damages arising from the use of this software. // // Permission is granted to anyone to use this software for any purpose, // including commercial applications, and to alter it and redistribute it freely, // subject to the following restrictions: // // 1. The origin of this software must not be misrepresented; // you must not claim that you wrote the original software. // If you use this software in a product, an acknowledgment // in the product documentation would be appreciated but is not required. // // 2. Altered source versions must be plainly marked as such, // and must not be misrepresented as being the original software. // // 3. This notice may not be removed or altered from any source distribution. // //////////////////////////////////////////////////////////// #ifndef SFML_TEXTURE_HPP #define SFML_TEXTURE_HPP //////////////////////////////////////////////////////////// // Headers //////////////////////////////////////////////////////////// #include #include #include namespace sf { class Window; class RenderTarget; class RenderTexture; class InputStream; //////////////////////////////////////////////////////////// /// \brief Image living on the graphics card that can be used for drawing /// //////////////////////////////////////////////////////////// class SFML_GRAPHICS_API Texture : GlResource { public: //////////////////////////////////////////////////////////// /// \brief Types of texture coordinates that can be used for rendering /// //////////////////////////////////////////////////////////// enum CoordinateType { Normalized, ///< Texture coordinates in range [0 .. 1] Pixels ///< Texture coordinates in range [0 .. size] }; public: //////////////////////////////////////////////////////////// /// \brief Default constructor /// /// Creates an empty texture. /// //////////////////////////////////////////////////////////// Texture(); //////////////////////////////////////////////////////////// /// \brief Copy constructor /// /// \param copy instance to copy /// //////////////////////////////////////////////////////////// Texture(const Texture& copy); //////////////////////////////////////////////////////////// /// \brief Destructor /// //////////////////////////////////////////////////////////// ~Texture(); //////////////////////////////////////////////////////////// /// \brief Create the texture /// /// If this function fails, the texture is left unchanged. /// /// \param width Width of the texture /// \param height Height of the texture /// /// \return True if creation was successful /// //////////////////////////////////////////////////////////// bool create(unsigned int width, unsigned int height); //////////////////////////////////////////////////////////// /// \brief Load the texture from a file on disk /// /// This function is a shortcut for the following code: /// \code /// sf::Image image; /// image.loadFromFile(filename); /// texture.loadFromImage(image, area); /// \endcode /// /// The \a area argument can be used to load only a sub-rectangle /// of the whole image. If you want the entire image then leave /// the default value (which is an empty IntRect). /// If the \a area rectangle crosses the bounds of the image, it /// is adjusted to fit the image size. /// /// The maximum size for a texture depends on the graphics /// driver and can be retrieved with the getMaximumSize function. /// /// If this function fails, the texture is left unchanged. /// /// \param filename Path of the image file to load /// \param area Area of the image to load /// /// \return True if loading was successful /// /// \see loadFromMemory, loadFromStream, loadFromImage /// //////////////////////////////////////////////////////////// bool loadFromFile(const std::string& filename, const IntRect& area = IntRect()); //////////////////////////////////////////////////////////// /// \brief Load the texture from a file in memory /// /// This function is a shortcut for the following code: /// \code /// sf::Image image; /// image.loadFromMemory(data, size); /// texture.loadFromImage(image, area); /// \endcode /// /// The \a area argument can be used to load only a sub-rectangle /// of the whole image. If you want the entire image then leave /// the default value (which is an empty IntRect). /// If the \a area rectangle crosses the bounds of the image, it /// is adjusted to fit the image size. /// /// The maximum size for a texture depends on the graphics /// driver and can be retrieved with the getMaximumSize function. /// /// If this function fails, the texture is left unchanged. /// /// \param data Pointer to the file data in memory /// \param size Size of the data to load, in bytes /// \param area Area of the image to load /// /// \return True if loading was successful /// /// \see loadFromFile, loadFromStream, loadFromImage /// //////////////////////////////////////////////////////////// bool loadFromMemory(const void* data, std::size_t size, const IntRect& area = IntRect()); //////////////////////////////////////////////////////////// /// \brief Load the texture from a custom stream /// /// This function is a shortcut for the following code: /// \code /// sf::Image image; /// image.loadFromStream(stream); /// texture.loadFromImage(image, area); /// \endcode /// /// The \a area argument can be used to load only a sub-rectangle /// of the whole image. If you want the entire image then leave /// the default value (which is an empty IntRect). /// If the \a area rectangle crosses the bounds of the image, it /// is adjusted to fit the image size. /// /// The maximum size for a texture depends on the graphics /// driver and can be retrieved with the getMaximumSize function. /// /// If this function fails, the texture is left unchanged. /// /// \param stream Source stream to read from /// \param area Area of the image to load /// /// \return True if loading was successful /// /// \see loadFromFile, loadFromMemory, loadFromImage /// //////////////////////////////////////////////////////////// bool loadFromStream(InputStream& stream, const IntRect& area = IntRect()); //////////////////////////////////////////////////////////// /// \brief Load the texture from an image /// /// The \a area argument can be used to load only a sub-rectangle /// of the whole image. If you want the entire image then leave /// the default value (which is an empty IntRect). /// If the \a area rectangle crosses the bounds of the image, it /// is adjusted to fit the image size. /// /// The maximum size for a texture depends on the graphics /// driver and can be retrieved with the getMaximumSize function. /// /// If this function fails, the texture is left unchanged. /// /// \param image Image to load into the texture /// \param area Area of the image to load /// /// \return True if loading was successful /// /// \see loadFromFile, loadFromMemory /// //////////////////////////////////////////////////////////// bool loadFromImage(const Image& image, const IntRect& area = IntRect()); //////////////////////////////////////////////////////////// /// \brief Return the size of the texture /// /// \return Size in pixels /// //////////////////////////////////////////////////////////// Vector2u getSize() const; //////////////////////////////////////////////////////////// /// \brief Copy the texture pixels to an image /// /// This function performs a slow operation that downloads /// the texture's pixels from the graphics card and copies /// them to a new image, potentially applying transformations /// to pixels if necessary (texture may be padded or flipped). /// /// \return Image containing the texture's pixels /// /// \see loadFromImage /// //////////////////////////////////////////////////////////// Image copyToImage() const; //////////////////////////////////////////////////////////// /// \brief Update the whole texture from an array of pixels /// /// The \a pixel array is assumed to have the same size as /// the \a area rectangle, and to contain 32-bits RGBA pixels. /// /// No additional check is performed on the size of the pixel /// array, passing invalid arguments will lead to an undefined /// behavior. /// /// This function does nothing if \a pixels is null or if the /// texture was not previously created. /// /// \param pixels Array of pixels to copy to the texture /// //////////////////////////////////////////////////////////// void update(const Uint8* pixels); //////////////////////////////////////////////////////////// /// \brief Update a part of the texture from an array of pixels /// /// The size of the \a pixel array must match the \a width and /// \a height arguments, and it must contain 32-bits RGBA pixels. /// /// No additional check is performed on the size of the pixel /// array or the bounds of the area to update, passing invalid /// arguments will lead to an undefined behavior. /// /// This function does nothing if \a pixels is null or if the /// texture was not previously created. /// /// \param pixels Array of pixels to copy to the texture /// \param width Width of the pixel region contained in \a pixels /// \param height Height of the pixel region contained in \a pixels /// \param x X offset in the texture where to copy the source pixels /// \param y Y offset in the texture where to copy the source pixels /// //////////////////////////////////////////////////////////// void update(const Uint8* pixels, unsigned int width, unsigned int height, unsigned int x, unsigned int y); //////////////////////////////////////////////////////////// /// \brief Update the texture from an image /// /// Although the source image can be smaller than the texture, /// this function is usually used for updating the whole texture. /// The other overload, which has (x, y) additional arguments, /// is more convenient for updating a sub-area of the texture. /// /// No additional check is performed on the size of the image, /// passing an image bigger than the texture will lead to an /// undefined behavior. /// /// This function does nothing if the texture was not /// previously created. /// /// \param image Image to copy to the texture /// //////////////////////////////////////////////////////////// void update(const Image& image); //////////////////////////////////////////////////////////// /// \brief Update a part of the texture from an image /// /// No additional check is performed on the size of the image, /// passing an invalid combination of image size and offset /// will lead to an undefined behavior. /// /// This function does nothing if the texture was not /// previously created. /// /// \param image Image to copy to the texture /// \param x X offset in the texture where to copy the source image /// \param y Y offset in the texture where to copy the source image /// //////////////////////////////////////////////////////////// void update(const Image& image, unsigned int x, unsigned int y); //////////////////////////////////////////////////////////// /// \brief Update the texture from the contents of a window /// /// Although the source window can be smaller than the texture, /// this function is usually used for updating the whole texture. /// The other overload, which has (x, y) additional arguments, /// is more convenient for updating a sub-area of the texture. /// /// No additional check is performed on the size of the window, /// passing a window bigger than the texture will lead to an /// undefined behavior. /// /// This function does nothing if either the texture or the window /// was not previously created. /// /// \param window Window to copy to the texture /// //////////////////////////////////////////////////////////// void update(const Window& window); //////////////////////////////////////////////////////////// /// \brief Update a part of the texture from the contents of a window /// /// No additional check is performed on the size of the window, /// passing an invalid combination of window size and offset /// will lead to an undefined behavior. /// /// This function does nothing if either the texture or the window /// was not previously created. /// /// \param window Window to copy to the texture /// \param x X offset in the texture where to copy the source window /// \param y Y offset in the texture where to copy the source window /// //////////////////////////////////////////////////////////// void update(const Window& window, unsigned int x, unsigned int y); //////////////////////////////////////////////////////////// /// \brief Enable or disable the smooth filter /// /// When the filter is activated, the texture appears smoother /// so that pixels are less noticeable. However if you want /// the texture to look exactly the same as its source file, /// you should leave it disabled. /// The smooth filter is disabled by default. /// /// \param smooth True to enable smoothing, false to disable it /// /// \see isSmooth /// //////////////////////////////////////////////////////////// void setSmooth(bool smooth); //////////////////////////////////////////////////////////// /// \brief Tell whether the smooth filter is enabled or not /// /// \return True if smoothing is enabled, false if it is disabled /// /// \see setSmooth /// //////////////////////////////////////////////////////////// bool isSmooth() const; //////////////////////////////////////////////////////////// /// \brief Enable or disable repeating /// /// Repeating is involved when using texture coordinates /// outside the texture rectangle [0, 0, width, height]. /// In this case, if repeat mode is enabled, the whole texture /// will be repeated as many times as needed to reach the /// coordinate (for example, if the X texture coordinate is /// 3 * width, the texture will be repeated 3 times). /// If repeat mode is disabled, the "extra space" will instead /// be filled with border pixels. /// Warning: on very old graphics cards, white pixels may appear /// when the texture is repeated. With such cards, repeat mode /// can be used reliably only if the texture has power-of-two /// dimensions (such as 256x128). /// Repeating is disabled by default. /// /// \param repeated True to repeat the texture, false to disable repeating /// /// \see isRepeated /// //////////////////////////////////////////////////////////// void setRepeated(bool repeated); //////////////////////////////////////////////////////////// /// \brief Tell whether the texture is repeated or not /// /// \return True if repeat mode is enabled, false if it is disabled /// /// \see setRepeated /// //////////////////////////////////////////////////////////// bool isRepeated() const; //////////////////////////////////////////////////////////// /// \brief Overload of assignment operator /// /// \param right Instance to assign /// /// \return Reference to self /// //////////////////////////////////////////////////////////// Texture& operator =(const Texture& right); //////////////////////////////////////////////////////////// /// \brief Get the underlying OpenGL handle of the texture. /// /// You shouldn't need to use this function, unless you have /// very specific stuff to implement that SFML doesn't support, /// or implement a temporary workaround until a bug is fixed. /// /// \return OpenGL handle of the texture or 0 if not yet created /// //////////////////////////////////////////////////////////// unsigned int getNativeHandle() const; //////////////////////////////////////////////////////////// /// \brief Bind a texture for rendering /// /// This function is not part of the graphics API, it mustn't be /// used when drawing SFML entities. It must be used only if you /// mix sf::Texture with OpenGL code. /// /// \code /// sf::Texture t1, t2; /// ... /// sf::Texture::bind(&t1); /// // draw OpenGL stuff that use t1... /// sf::Texture::bind(&t2); /// // draw OpenGL stuff that use t2... /// sf::Texture::bind(NULL); /// // draw OpenGL stuff that use no texture... /// \endcode /// /// The \a coordinateType argument controls how texture /// coordinates will be interpreted. If Normalized (the default), they /// must be in range [0 .. 1], which is the default way of handling /// texture coordinates with OpenGL. If Pixels, they must be given /// in pixels (range [0 .. size]). This mode is used internally by /// the graphics classes of SFML, it makes the definition of texture /// coordinates more intuitive for the high-level API, users don't need /// to compute normalized values. /// /// \param texture Pointer to the texture to bind, can be null to use no texture /// \param coordinateType Type of texture coordinates to use /// //////////////////////////////////////////////////////////// static void bind(const Texture* texture, CoordinateType coordinateType = Normalized); //////////////////////////////////////////////////////////// /// \brief Get the maximum texture size allowed /// /// This maximum size is defined by the graphics driver. /// You can expect a value of 512 pixels for low-end graphics /// card, and up to 8192 pixels or more for newer hardware. /// /// Note: The first call to this function, whether by your /// code or SFML will result in a context switch. /// /// \return Maximum size allowed for textures, in pixels /// //////////////////////////////////////////////////////////// static unsigned int getMaximumSize(); private: friend class RenderTexture; friend class RenderTarget; //////////////////////////////////////////////////////////// /// \brief Get a valid image size according to hardware support /// /// This function checks whether the graphics driver supports /// non power of two sizes or not, and adjusts the size /// accordingly. /// The returned size is greater than or equal to the original size. /// /// \param size size to convert /// /// \return Valid nearest size (greater than or equal to specified size) /// //////////////////////////////////////////////////////////// static unsigned int getValidSize(unsigned int size); //////////////////////////////////////////////////////////// // Member data //////////////////////////////////////////////////////////// Vector2u m_size; ///< Public texture size Vector2u m_actualSize; ///< Actual texture size (can be greater than public size because of padding) unsigned int m_texture; ///< Internal texture identifier bool m_isSmooth; ///< Status of the smooth filter bool m_isRepeated; ///< Is the texture in repeat mode? mutable bool m_pixelsFlipped; ///< To work around the inconsistency in Y orientation bool m_fboAttachment; ///< Is this texture owned by a framebuffer object? Uint64 m_cacheId; ///< Unique number that identifies the texture to the render target's cache }; } // namespace sf #endif // SFML_TEXTURE_HPP //////////////////////////////////////////////////////////// /// \class sf::Texture /// \ingroup graphics /// /// sf::Texture stores pixels that can be drawn, with a sprite /// for example. A texture lives in the graphics card memory, /// therefore it is very fast to draw a texture to a render target, /// or copy a render target to a texture (the graphics card can /// access both directly). /// /// Being stored in the graphics card memory has some drawbacks. /// A texture cannot be manipulated as freely as a sf::Image, /// you need to prepare the pixels first and then upload them /// to the texture in a single operation (see Texture::update). /// /// sf::Texture makes it easy to convert from/to sf::Image, but /// keep in mind that these calls require transfers between /// the graphics card and the central memory, therefore they are /// slow operations. /// /// A texture can be loaded from an image, but also directly /// from a file/memory/stream. The necessary shortcuts are defined /// so that you don't need an image first for the most common cases. /// However, if you want to perform some modifications on the pixels /// before creating the final texture, you can load your file to a /// sf::Image, do whatever you need with the pixels, and then call /// Texture::loadFromImage. /// /// Since they live in the graphics card memory, the pixels of a texture /// cannot be accessed without a slow copy first. And they cannot be /// accessed individually. Therefore, if you need to read the texture's /// pixels (like for pixel-perfect collisions), it is recommended to /// store the collision information separately, for example in an array /// of booleans. /// /// Like sf::Image, sf::Texture can handle a unique internal /// representation of pixels, which is RGBA 32 bits. This means /// that a pixel must be composed of 8 bits red, green, blue and /// alpha channels -- just like a sf::Color. /// /// Usage example: /// \code /// // This example shows the most common use of sf::Texture: /// // drawing a sprite /// /// // Load a texture from a file /// sf::Texture texture; /// if (!texture.loadFromFile("texture.png")) /// return -1; /// /// // Assign it to a sprite /// sf::Sprite sprite; /// sprite.setTexture(texture); /// /// // Draw the textured sprite /// window.draw(sprite); /// \endcode /// /// \code /// // This example shows another common use of sf::Texture: /// // streaming real-time data, like video frames /// /// // Create an empty texture /// sf::Texture texture; /// if (!texture.create(640, 480)) /// return -1; /// /// // Create a sprite that will display the texture /// sf::Sprite sprite(texture); /// /// while (...) // the main loop /// { /// ... /// /// // update the texture /// sf::Uint8* pixels = ...; // get a fresh chunk of pixels (the next frame of a movie, for example) /// texture.update(pixels); /// /// // draw it /// window.draw(sprite); /// /// ... /// } /// /// \endcode /// /// Like sf::Shader that can be used as a raw OpenGL shader, /// sf::Texture can also be used directly as a raw texture for /// custom OpenGL geometry. /// \code /// sf::Texture::bind(&texture); /// ... render OpenGL geometry ... /// sf::Texture::bind(NULL); /// \endcode /// /// \see sf::Sprite, sf::Image, sf::RenderTexture /// ////////////////////////////////////////////////////////////