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A royalty-free, cross-platform API for full-function 2D and 3D graphics on embedded systems - including consoles, phones, appliances and vehicles.

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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 java.nio.*;

import org.lwjgl.system.*;

import static org.lwjgl.system.Checks.*;
import static org.lwjgl.system.JNI.*;
import static org.lwjgl.system.MemoryUtil.*;

/**
 * Native bindings to the NV_framebuffer_mixed_samples extension.
 * 
 * 

This extension allows multisample rendering with a raster and depth/stencil sample count that is larger than the color sample count. Rasterization and * the results of the depth and stencil tests together determine the portion of a pixel that is "covered". It can be useful to evaluate coverage at a * higher frequency than color samples are stored. This coverage is then "reduced" to a collection of covered color samples, each having an opacity value * corresponding to the fraction of the color sample covered. The opacity can optionally be blended into individual color samples.

* *

In the current hardware incarnation both depth and stencil testing are supported with mixed samples, although the API accommodates supporting only one * or the other.

* *

Rendering with fewer color samples than depth/stencil samples can greatly reduce the amount of memory and bandwidth consumed by the color buffer. * However, converting the coverage values into opacity can introduce artifacts where triangles share edges and may not be suitable for normal triangle * mesh rendering.

* *

One expected use case for this functionality is Stencil-then-Cover path rendering (NV_path_rendering). The stencil step determines the coverage (in the * stencil buffer) for an entire path at the higher sample frequency, and then the cover step can draw the path into the lower frequency color buffer * using the coverage information to antialias path edges. With this two-step process, internal edges are fully covered when antialiasing is applied and * there is no corruption on these edges.

* *

The key features of this extension are:

* *
    *
  • It allows a framebuffer object to be considered complete when its depth or stencil samples are a multiple of the number of color samples.
  • *
  • It redefines SAMPLES to be the number of depth/stencil samples (if any); otherwise, it uses the number of color samples. SAMPLE_BUFFERS is one if * there are multisample depth/stencil attachments. Multisample rasterization and multisample fragment ops are allowed if SAMPLE_BUFFERS is one.
  • *
  • It replaces several error checks involving SAMPLE_BUFFERS by error checks directly referencing the number of samples in the relevant attachments.
  • *
  • A coverage reduction step is added to Per-Fragment Operations which converts a set of covered raster/depth/stencil samples to a set of covered * color samples. The coverage reduction step also includes an optional coverage modulation step, multiplying color values by a fractional opacity * corresponding to the number of associated raster/depth/stencil samples covered.
  • *
*/ public class NVFramebufferMixedSamples { static { GLES.initialize(); } /** Accepted by the {@code cap} parameter of Enable, Disable, IsEnabled. */ public static final int GL_RASTER_MULTISAMPLE_EXT = 0x9327, GL_COVERAGE_MODULATION_TABLE_NV = 0x9331; /** Accepted by the {@code pname} parameter of GetBooleanv, GetDoublev, GetIntegerv, and GetFloatv. */ public static final int GL_RASTER_SAMPLES_EXT = 0x9328, GL_MAX_RASTER_SAMPLES_EXT = 0x9329, GL_RASTER_FIXED_SAMPLE_LOCATIONS_EXT = 0x932A, GL_MULTISAMPLE_RASTERIZATION_ALLOWED_EXT = 0x932B, GL_EFFECTIVE_RASTER_SAMPLES_EXT = 0x932C, GL_COLOR_SAMPLES_NV = 0x8E20, GL_DEPTH_SAMPLES_NV = 0x932D, GL_STENCIL_SAMPLES_NV = 0x932E, GL_MIXED_DEPTH_SAMPLES_SUPPORTED_NV = 0x932F, GL_MIXED_STENCIL_SAMPLES_SUPPORTED_NV = 0x9330, GL_COVERAGE_MODULATION_NV = 0x9332, GL_COVERAGE_MODULATION_TABLE_SIZE_NV = 0x9333; protected NVFramebufferMixedSamples() { throw new UnsupportedOperationException(); } // --- [ glRasterSamplesEXT ] --- public static void glRasterSamplesEXT(@NativeType("GLuint") int samples, @NativeType("GLboolean") boolean fixedsamplelocations) { EXTRasterMultisample.glRasterSamplesEXT(samples, fixedsamplelocations); } // --- [ glCoverageModulationTableNV ] --- public static native void nglCoverageModulationTableNV(int n, long v); public static void glCoverageModulationTableNV(@NativeType("GLfloat const *") FloatBuffer v) { nglCoverageModulationTableNV(v.remaining(), memAddress(v)); } // --- [ glGetCoverageModulationTableNV ] --- public static native void nglGetCoverageModulationTableNV(int bufsize, long v); public static void glGetCoverageModulationTableNV(@NativeType("GLfloat *") FloatBuffer v) { nglGetCoverageModulationTableNV(v.remaining(), memAddress(v)); } // --- [ glCoverageModulationNV ] --- public static native void glCoverageModulationNV(@NativeType("GLenum") int components); /** Array version of: {@link #glCoverageModulationTableNV CoverageModulationTableNV} */ public static void glCoverageModulationTableNV(@NativeType("GLfloat const *") float[] v) { long __functionAddress = GLES.getICD().glCoverageModulationTableNV; if (CHECKS) { check(__functionAddress); } callPV(v.length, v, __functionAddress); } /** Array version of: {@link #glGetCoverageModulationTableNV GetCoverageModulationTableNV} */ public static void glGetCoverageModulationTableNV(@NativeType("GLfloat *") float[] v) { long __functionAddress = GLES.getICD().glGetCoverageModulationTableNV; if (CHECKS) { check(__functionAddress); } callPV(v.length, v, __functionAddress); } }




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