/** * Sets the OpenGL integer texture parameter for the texture's target. This gives control over * parameters such as GL_TEXTURE_WRAP_S and GL_TEXTURE_WRAP_T, which by default are set to * GL_CLAMP_TO_EDGE if OpenGL 1.2 is supported on the current platform and GL_CLAMP if not. Causes * this texture to be bound to the current texture state. * * @throws GLException if no OpenGL context was current or if any OpenGL-related errors occurred */ public void setTexParameteri(int parameterName, int value) { bind(); GL gl = GLU.getCurrentGL(); gl.glTexParameteri(target, parameterName, value); }
/** * Updates the content area of the specified target of this texture using the data in the given * image. In general this is intended for construction of cube maps. * * @throws GLException if no OpenGL context was current or if any OpenGL-related errors occurred */ public void updateImage(TextureData data, int target) throws GLException { GL gl = GLU.getCurrentGL(); imgWidth = data.getWidth(); imgHeight = data.getHeight(); aspectRatio = (float) imgWidth / (float) imgHeight; mustFlipVertically = data.getMustFlipVertically(); int texTarget = 0; int texParamTarget = this.target; // See whether we have automatic mipmap generation support boolean haveAutoMipmapGeneration = (gl.isExtensionAvailable("GL_VERSION_1_4") || gl.isExtensionAvailable("GL_SGIS_generate_mipmap")); // Indicate to the TextureData what functionality is available data.setHaveEXTABGR(gl.isExtensionAvailable("GL_EXT_abgr")); data.setHaveGL12(gl.isExtensionAvailable("GL_VERSION_1_2")); // Note that automatic mipmap generation doesn't work for // GL_ARB_texture_rectangle if ((!isPowerOfTwo(imgWidth) || !isPowerOfTwo(imgHeight)) && !haveNPOT(gl)) { haveAutoMipmapGeneration = false; } boolean expandingCompressedTexture = false; if (data.getMipmap() && !haveAutoMipmapGeneration) { // GLU always scales the texture's dimensions to be powers of // two. It also doesn't really matter exactly what the texture // width and height are because the texture coords are always // between 0.0 and 1.0. imgWidth = nextPowerOfTwo(imgWidth); imgHeight = nextPowerOfTwo(imgHeight); texWidth = imgWidth; texHeight = imgHeight; texTarget = GL.GL_TEXTURE_2D; } else if ((isPowerOfTwo(imgWidth) && isPowerOfTwo(imgHeight)) || haveNPOT(gl)) { if (DEBUG) { if (isPowerOfTwo(imgWidth) && isPowerOfTwo(imgHeight)) { System.err.println("Power-of-two texture"); } else { System.err.println("Using GL_ARB_texture_non_power_of_two"); } } texWidth = imgWidth; texHeight = imgHeight; texTarget = GL.GL_TEXTURE_2D; } else if (haveTexRect(gl) && !data.isDataCompressed()) { // GL_ARB_texture_rectangle does not work for compressed textures if (DEBUG) { System.err.println("Using GL_ARB_texture_rectangle"); } texWidth = imgWidth; texHeight = imgHeight; texTarget = GL.GL_TEXTURE_RECTANGLE_ARB; } else { // If we receive non-power-of-two compressed texture data and // don't have true hardware support for compressed textures, we // can fake this support by producing an empty "compressed" // texture image, using glCompressedTexImage2D with that to // allocate the texture, and glCompressedTexSubImage2D with the // incoming data. if (data.isDataCompressed()) { if (data.getMipmapData() != null) { // We don't currently support expanding of compressed, // mipmapped non-power-of-two textures to the nearest power // of two; the obvious port of the non-mipmapped code didn't // work throw new GLException( "Mipmapped non-power-of-two compressed textures only supported on OpenGL 2.0 hardware (GL_ARB_texture_non_power_of_two)"); } expandingCompressedTexture = true; } if (DEBUG) { System.err.println("Expanding texture to power-of-two dimensions"); } if (data.getBorder() != 0) { throw new RuntimeException( "Scaling up a non-power-of-two texture which has a border won't work"); } texWidth = nextPowerOfTwo(imgWidth); texHeight = nextPowerOfTwo(imgHeight); texTarget = GL.GL_TEXTURE_2D; } texParamTarget = texTarget; setImageSize(imgWidth, imgHeight, texTarget); if (target != 0) { // Allow user to override auto detection and skip bind step (for // cubemap construction) texTarget = target; if (this.target == 0) { throw new GLException("Override of target failed; no target specified yet"); } texParamTarget = this.target; gl.glBindTexture(texParamTarget, texID); } else { gl.glBindTexture(texTarget, texID); } if (data.getMipmap() && !haveAutoMipmapGeneration) { int[] align = new int[1]; gl.glGetIntegerv(GL.GL_UNPACK_ALIGNMENT, align, 0); // save alignment gl.glPixelStorei(GL.GL_UNPACK_ALIGNMENT, data.getAlignment()); if (data.isDataCompressed()) { throw new GLException("May not request mipmap generation for compressed textures"); } try { GLU glu = new GLU(); glu.gluBuild2DMipmaps( texTarget, data.getInternalFormat(), data.getWidth(), data.getHeight(), data.getPixelFormat(), data.getPixelType(), data.getBuffer()); } finally { gl.glPixelStorei(GL.GL_UNPACK_ALIGNMENT, align[0]); // restore alignment } } else { checkCompressedTextureExtensions(data); Buffer[] mipmapData = data.getMipmapData(); if (mipmapData != null) { int width = texWidth; int height = texHeight; for (int i = 0; i < mipmapData.length; i++) { if (data.isDataCompressed()) { // Need to use glCompressedTexImage2D directly to allocate and fill this image // Avoid spurious memory allocation when possible gl.glCompressedTexImage2D( texTarget, i, data.getInternalFormat(), width, height, data.getBorder(), mipmapData[i].remaining(), mipmapData[i]); } else { // Allocate texture image at this level gl.glTexImage2D( texTarget, i, data.getInternalFormat(), width, height, data.getBorder(), data.getPixelFormat(), data.getPixelType(), null); updateSubImageImpl(data, texTarget, i, 0, 0, 0, 0, data.getWidth(), data.getHeight()); } width = Math.max(width / 2, 1); height = Math.max(height / 2, 1); } } else { if (data.isDataCompressed()) { if (!expandingCompressedTexture) { // Need to use glCompressedTexImage2D directly to allocate and fill this image // Avoid spurious memory allocation when possible gl.glCompressedTexImage2D( texTarget, 0, data.getInternalFormat(), texWidth, texHeight, data.getBorder(), data.getBuffer().capacity(), data.getBuffer()); } else { ByteBuffer buf = DDSImage.allocateBlankBuffer(texWidth, texHeight, data.getInternalFormat()); gl.glCompressedTexImage2D( texTarget, 0, data.getInternalFormat(), texWidth, texHeight, data.getBorder(), buf.capacity(), buf); updateSubImageImpl(data, texTarget, 0, 0, 0, 0, 0, data.getWidth(), data.getHeight()); } } else { if (data.getMipmap() && haveAutoMipmapGeneration) { // For now, only use hardware mipmapping for uncompressed 2D // textures where the user hasn't explicitly specified // mipmap data; don't know about interactions between // GL_GENERATE_MIPMAP and glCompressedTexImage2D gl.glTexParameteri(texParamTarget, GL.GL_GENERATE_MIPMAP, GL.GL_TRUE); usingAutoMipmapGeneration = true; } gl.glTexImage2D( texTarget, 0, data.getInternalFormat(), texWidth, texHeight, data.getBorder(), data.getPixelFormat(), data.getPixelType(), null); updateSubImageImpl(data, texTarget, 0, 0, 0, 0, 0, data.getWidth(), data.getHeight()); } } } int minFilter = (data.getMipmap() ? GL.GL_LINEAR_MIPMAP_LINEAR : GL.GL_LINEAR); int magFilter = GL.GL_LINEAR; int wrapMode = (gl.isExtensionAvailable("GL_VERSION_1_2") ? GL.GL_CLAMP_TO_EDGE : GL.GL_CLAMP); // REMIND: figure out what to do for GL_TEXTURE_RECTANGLE_ARB if (texTarget != GL.GL_TEXTURE_RECTANGLE_ARB) { gl.glTexParameteri(texParamTarget, GL.GL_TEXTURE_MIN_FILTER, minFilter); gl.glTexParameteri(texParamTarget, GL.GL_TEXTURE_MAG_FILTER, magFilter); gl.glTexParameteri(texParamTarget, GL.GL_TEXTURE_WRAP_S, wrapMode); gl.glTexParameteri(texParamTarget, GL.GL_TEXTURE_WRAP_T, wrapMode); if (this.target == GL.GL_TEXTURE_CUBE_MAP) { gl.glTexParameteri(texParamTarget, GL.GL_TEXTURE_WRAP_R, wrapMode); } } // Don't overwrite target if we're loading e.g. faces of a cube // map if ((this.target == 0) || (this.target == GL.GL_TEXTURE_2D) || (this.target == GL.GL_TEXTURE_RECTANGLE_ARB)) { this.target = texTarget; } // This estimate will be wrong for cube maps estimatedMemorySize = data.getEstimatedMemorySize(); }