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/*
* Copyright LWJGL. All rights reserved.
* License terms: https://www.lwjgl.org/license
* MACHINE GENERATED FILE, DO NOT EDIT
*/
package org.lwjgl.opengles;
import org.lwjgl.system.*;
/**
* Native bindings to the NV_coverage_sample extension.
*
* Anti-aliasing is a critical component for delivering high-quality OpenGL rendering. Traditionally, OpenGL implementations have implemented two
* anti-aliasing algorithms: edge anti-aliasing and multisampling.
*
* Edge anti-aliasing computes fractional fragment coverage for all primitives in a rendered frame, and blends edges of abutting and/or overlapping
* primitives to produce smooth results. The image quality produced by this approach is exceptionally high; however, applications are render their
* geometry perfectly ordered back-to-front in order to avoid artifacts such as bleed-through. Given the algorithmic complexity and performance cost of
* performing exact geometric sorts, edge anti-aliasing has been used very sparingly, and almost never in interactive games.
*
* Multisampling, on the other hand, computes and stores subpixel (a.k.a. "sample") coverage for rasterized fragments, and replicates all post-alpha test
* operations (e.g., depth test, stencil test, alpha blend) for each sample. After the entire scene is rendered, the samples are filtered to compute the
* final anti-aliased image. Because the post-alpha test operations are replicated for each sample, all of the bleed-through and ordering artifacts that
* could occur with edge anti-aliasing are avoided completely; however, since each sample must be computed and stored separately, anti-aliasing quality is
* limited by framebuffer storage and rendering performance.
*
* This extension introduces a new anti-aliasing algorithm to OpenGL, which dramatically improves multisampling quality without adversely affecting
* multisampling's robustness or significantly increasing the storage required, coverage sampling.
*
* Coverage sampling adds an additional high-precision geometric coverage buffer to the framebuffer, which is used to produce high-quality filtered
* results (with or without the presence of a multisample buffer). This coverage information is computed and stored during rasterization; since
* applications may render objects where the specified geometry does not correspond to the visual result (examples include alpha-testing for "imposters,"
* or extruded volume rendering for stencil shadow volumes), coverage buffer updates may be masked by the application, analagous to masking the depth
* buffer.
*/
public class NVCoverageSample {
static { GLES.initialize(); }
/** Accepted by the {@code internalformat} parameter of RenderbufferStorageEXT and the {@code format} parameter of ReadPixels. */
public static final int GL_COVERAGE_COMPONENT_NV = 0x8ED0;
/** Accepted by the {@code internalformat} parameter of RenderbufferStorageEXT. */
public static final int GL_COVERAGE_COMPONENT4_NV = 0x8ED1;
/** Accepted by the {@code operation} parameter of CoverageOperationNV. */
public static final int
GL_COVERAGE_ALL_FRAGMENTS_NV = 0x8ED5,
GL_COVERAGE_EDGE_FRAGMENTS_NV = 0x8ED6,
GL_COVERAGE_AUTOMATIC_NV = 0x8ED7;
/** Accepted by the {@code attachment} parameter of FramebufferRenderbuffer, and GetFramebufferAttachmentParameteriv. */
public static final int GL_COVERAGE_ATTACHMENT_NV = 0x8ED2;
/** Accepted by the {@code buf} parameter of Clear. */
public static final int GL_COVERAGE_BUFFER_BIT_NV = 0x8000;
/** Accepted by the {@code pname} parameter of GetIntegerv. */
public static final int
GL_COVERAGE_BUFFERS_NV = 0x8ED3,
GL_COVERAGE_SAMPLES_NV = 0x8ED4;
protected NVCoverageSample() {
throw new UnsupportedOperationException();
}
// --- [ glCoverageMaskNV ] ---
public static native void glCoverageMaskNV(@NativeType("GLboolean") boolean mask);
// --- [ glCoverageOperationNV ] ---
public static native void glCoverageOperationNV(@NativeType("GLenum") int operation);
}