/** * Copyright 2010-2023 JogAmp Community. All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, are * permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this list of * conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, this list * of conditions and the following disclaimer in the documentation and/or other materials * provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY JogAmp Community ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL JogAmp Community OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are those of the * authors and should not be interpreted as representing official policies, either expressed * or implied, of JogAmp Community. */ package com.jogamp.graph.curve; import java.io.PrintStream; import java.nio.FloatBuffer; import java.nio.IntBuffer; import java.nio.ShortBuffer; import java.util.ArrayList; import java.util.List; import java.util.Locale; import java.util.concurrent.TimeUnit; import jogamp.opengl.Debug; import com.jogamp.graph.geom.Triangle; import com.jogamp.graph.geom.Vertex; import com.jogamp.graph.geom.plane.AffineTransform; import com.jogamp.common.nio.Buffers; import com.jogamp.common.os.Clock; import com.jogamp.common.util.PerfCounterCtrl; import com.jogamp.graph.curve.opengl.GLRegion; import com.jogamp.opengl.GLCapabilitiesImmutable; import com.jogamp.opengl.GLProfile; import com.jogamp.opengl.math.Vec3f; import com.jogamp.opengl.math.Vec4f; import com.jogamp.opengl.math.geom.AABBox; import com.jogamp.opengl.math.geom.Frustum; import com.jogamp.opengl.util.texture.TextureSequence; /** * Abstract Outline shape representation define the method an OutlineShape(s) * is bound and rendered. * * @see GLRegion */ public abstract class Region { /** Debug flag for region impl (graph.curve) */ public static final boolean DEBUG = Debug.debug("graph.curve"); public static final boolean DEBUG_INSTANCE = Debug.debug("graph.curve.Instance"); /** * Rendering-Mode bit for {@link #getRenderModes() Region} *
* One pass `norm` rendering either using no AA or underlying full-screen AA (fsaa). *
*/ public static final int NORM_RENDERING_BIT = 0; /** * Rendering-Mode bit for {@link #getRenderModes() Region} ** MSAA based Anti-Aliasing, a two pass region rendering, slower and more * resource hungry (FBO), but providing fast MSAA in case * the whole scene is not rendered with MSAA. *
*/ public static final int MSAA_RENDERING_BIT = 1 << 0; /** * Rendering-Mode bit for {@link #getRenderModes() Region} ** View based Anti-Aliasing, a two pass region rendering, slower and more * resource hungry (FBO), but AA is perfect. Otherwise the default fast one * pass MSAA region rendering is being used. *
*/ public static final int VBAA_RENDERING_BIT = 1 << 1; /** * Rendering-Mode bit for {@link #getRenderModes() Region} ** Use non uniform weights [0.0 .. 1.9] for curve region rendering. * Otherwise the default weight 1.0 for uniform curve region rendering is * being applied. *
*/ public static final int VARWEIGHT_RENDERING_BIT = 1 << 8; /** * Rendering-Mode bit for {@link #getRenderModes() Region} to optionally enable a color-channel per vertex. ** If set, a color channel attribute per vertex is added to the stream via {@link #addOutlineShape(OutlineShape, AffineTransform, float[])}, * otherwise {@link com.jogamp.graph.curve.opengl.RegionRenderer#setColorStatic(com.jogamp.opengl.GL2ES2, float, float, float, float) static color} * can being used for a monotonic color. *
* @see #getRenderModes() * @see #hasColorChannel() * @see #addOutlineShape(OutlineShape, AffineTransform, float[]) * @see com.jogamp.graph.curve.opengl.RegionRenderer#setColorStatic(com.jogamp.opengl.GL2ES2, float, float, float, float) */ public static final int COLORCHANNEL_RENDERING_BIT = 1 << 9; /** * Rendering-Mode bit for {@link #getRenderModes() Region} ** If set, a color texture is used to determine the color. *
*/ public static final int COLORTEXTURE_RENDERING_BIT = 1 << 10; /** Default maximum {@link #getQuality() quality}, {@value}. */ public static final int MAX_QUALITY = 1; public static final int DEFAULT_TWO_PASS_TEXTURE_UNIT = 0; protected static final int DIRTY_SHAPE = 1 << 0 ; protected static final int DIRTY_STATE = 1 << 1 ; private final int renderModes; private final boolean use_int32_idx; private final int max_indices; private int quality; private int dirty = DIRTY_SHAPE | DIRTY_STATE; private int numVertices = 0; protected final AABBox box = new AABBox(); protected Frustum frustum = null; public static boolean isVBAA(final int renderModes) { return 0 != (renderModes & Region.VBAA_RENDERING_BIT); } public static boolean isMSAA(final int renderModes) { return 0 != (renderModes & Region.MSAA_RENDERING_BIT); } public static boolean isTwoPass(final int renderModes) { return 0 != ( renderModes & ( Region.VBAA_RENDERING_BIT | Region.MSAA_RENDERING_BIT) ); } /** * Returns true if render mode capable of variable weights, * i.e. the bit {@link #VARWEIGHT_RENDERING_BIT} is set, * otherwise false. */ public static boolean hasVariableWeight(final int renderModes) { return 0 != (renderModes & Region.VARWEIGHT_RENDERING_BIT); } /** * Returns true if render mode has a color channel, * i.e. the bit {@link #COLORCHANNEL_RENDERING_BIT} is set, * otherwise false. */ public static boolean hasColorChannel(final int renderModes) { return 0 != (renderModes & Region.COLORCHANNEL_RENDERING_BIT); } /** * Returns true if render mode has a color texture, * i.e. the bit {@link #COLORTEXTURE_RENDERING_BIT} is set, * otherwise false. */ public static boolean hasColorTexture(final int renderModes) { return 0 != (renderModes & Region.COLORTEXTURE_RENDERING_BIT); } /** * Returns a unique technical description string for renderModes as follows: ** (vbaa|msaa|norm)[-curve][-cols][-ctex] ** @param renderModes Graph renderModes, see {@link GLRegion#create(GLProfile, int, TextureSequence) create(..)} */ public static String getRenderModeString(final int renderModes) { final String curveS = hasVariableWeight(renderModes) ? "-curve" : ""; final String cChanS = hasColorChannel(renderModes) ? "-cols" : ""; final String cTexS = hasColorTexture(renderModes) ? "-ctex" : ""; if( Region.isVBAA(renderModes) ) { return "vbaa"+curveS+cChanS+cTexS; } else if( Region.isMSAA(renderModes) ) { return "msaa"+curveS+cChanS+cTexS; } else { return "norm"+curveS+cChanS+cTexS; } } /** * Return a unique technical description string for renderModes and sample counts as follows: *
* {@link #getRenderModeString(int)}-s{sampleCount}-fsaa{CapsNumSamples} ** * @param renderModes the used Graph renderModes, see {@link GLRegion#create(GLProfile, int, TextureSequence) create(..)} * @param graphSampleCount Graph sample count for {@link Region#VBAA_RENDERING_BIT} or {@link Region#MSAA_RENDERING_BIT} * @param fsaaSampleCount full-screen AA (fsaa) sample count, retrieved e.g. via {@link GLCapabilitiesImmutable#getNumSamples()} */ public static String getRenderModeString(final int renderModes, final int graphSampleCount, final int fsaaSampleCount) { return String.format((Locale)null, "%s-s%02d-fsaa%d", Region.getRenderModeString(renderModes), graphSampleCount, fsaaSampleCount); } protected Region(final int regionRenderModes, final boolean use_int32_idx) { this.renderModes = regionRenderModes; this.use_int32_idx = use_int32_idx; if( use_int32_idx ) { this.max_indices = GL_INT32_MAX / Buffers.SIZEOF_INT; // byte-size int32_t limit } else { this.max_indices = GL_UINT16_MAX; } this.quality = MAX_QUALITY; } /** Print implementation buffer stats like detailed and total size and capacity in bytes etc */ public abstract void printBufferStats(PrintStream out); /** * Returns true if implementation uses `int32_t` sized indices implying at least a {@link GLProfile#isGL2ES3()} alike context. * Otherwise method returns false on {@link GLProfile#isGLES2()} using `uint16_t` sized indices. */ public final boolean usesI32Idx() { return this.use_int32_idx; } /** * Allow the renderer buffers to pre-emptively grow for given vertices- and index counts. * @param verticesCount number of vertices to hold * @param indicesCount number of indices to hold * @see #setBufferCapacity(int, int) * @see #countOutlineShape(OutlineShape, int[]) * @see #countOutlineShapes(List, int[]) */ public abstract void growBuffer(int verticesCount, int indicesCount); /** * Set the renderer buffers pre-emptively for given vertices- and index counts. *
* If the buffers already exceeds given numbers, the buffers are unchanged. *
* @param verticesCount number of vertices to hold * @param indicesCount number of indices to hold * @see #growBuffer(int, int) * @see #countOutlineShape(OutlineShape, int[]) * @see #countOutlineShapes(List, int[]) */ public abstract void setBufferCapacity(int verticesCount, int indicesCount); protected abstract void pushVertex(final Vec3f coords, final Vec3f texParams, Vec4f rgba); protected abstract void pushVertices(final Vec3f coords1, final Vec3f coords2, final Vec3f coords3, final Vec3f texParams1, final Vec3f texParams2, final Vec3f texParams3, Vec4f rgba); protected abstract void pushIndex(int idx); protected abstract void pushIndices(int idx1, int idx2, int idx3); /** * Returns bit-field of render modes, see {@link GLRegion#create(GLProfile, int, TextureSequence) create(..)}. */ public final int getRenderModes() { return renderModes; } /** See {@link #MAX_QUALITY} */ public final int getQuality() { return quality; } /** See {@link #MAX_QUALITY} */ public final void setQuality(final int q) { quality=q; } protected void clearImpl() { dirty = DIRTY_SHAPE | DIRTY_STATE; numVertices = 0; box.reset(); } /** * Returns true if capable of two pass rendering - VBAA, otherwise false. * @see #getRenderModes() */ public final boolean isVBAA() { return Region.isVBAA(renderModes); } /** * Returns true if capable of two pass rendering - MSAA, otherwise false. * @see #getRenderModes() */ public final boolean isMSAA() { return Region.isMSAA(renderModes); } /** * Returns true if capable of variable weights, otherwise false. * @see #getRenderModes() */ public final boolean hasVariableWeight() { return Region.hasVariableWeight(renderModes); } /** * Returns true if {@link #getRenderModes()} has a color channel, i.e. {@link #COLORCHANNEL_RENDERING_BIT} is set. * Otherwise returns false. * @see #COLORCHANNEL_RENDERING_BIT * @see #getRenderModes() * @see #addOutlineShape(OutlineShape, AffineTransform, float[]) * @see com.jogamp.graph.curve.opengl.RegionRenderer#setColorStatic(com.jogamp.opengl.GL2ES2, float, float, float, float) */ public boolean hasColorChannel() { return Region.hasColorChannel(renderModes); } /** * Returns true if render mode has a color texture, * i.e. the bit {@link #COLORTEXTURE_RENDERING_BIT} is set, * otherwise false. * @see #getRenderModes() */ public boolean hasColorTexture() { return Region.hasColorTexture(renderModes); } /** See {@link #setFrustum(Frustum)} */ public final Frustum getFrustum() { return frustum; } /** * Set {@link Frustum} culling for {@link #addOutlineShape(OutlineShape, AffineTransform, float[])}. */ public final void setFrustum(final Frustum frustum) { this.frustum = frustum; } private void pushNewVertexImpl(final Vertex vertIn, final AffineTransform transform, final Vec4f rgba) { if( null != transform ) { final Vec3f coordsEx1 = transform.transform(vertIn.getCoord(), new Vec3f()); box.resize(coordsEx1); pushVertex(coordsEx1, vertIn.getTexCoord(), rgba); } else { box.resize(vertIn.getCoord()); pushVertex(vertIn.getCoord(), vertIn.getTexCoord(), rgba); } numVertices++; } private void pushNewVerticesImpl(final Vertex vertIn1, final Vertex vertIn2, final Vertex vertIn3, final AffineTransform transform, final Vec4f rgba) { if( null != transform ) { final Vec3f coordsEx1 = transform.transform(vertIn1.getCoord(), new Vec3f()); final Vec3f coordsEx2 = transform.transform(vertIn2.getCoord(), new Vec3f()); final Vec3f coordsEx3 = transform.transform(vertIn3.getCoord(), new Vec3f()); box.resize(coordsEx1); box.resize(coordsEx2); box.resize(coordsEx3); pushVertices(coordsEx1, coordsEx2, coordsEx3, vertIn1.getTexCoord(), vertIn2.getTexCoord(), vertIn3.getTexCoord(), rgba); } else { box.resize(vertIn1.getCoord()); box.resize(vertIn2.getCoord()); box.resize(vertIn3.getCoord()); pushVertices(vertIn1.getCoord(), vertIn2.getCoord(), vertIn3.getCoord(), vertIn1.getTexCoord(), vertIn2.getTexCoord(), vertIn3.getTexCoord(), rgba); } numVertices+=3; } @SuppressWarnings("unused") private void pushNewVertexIdxImpl(final Vertex vertIn, final AffineTransform transform, final Vec4f rgba) { pushIndex(numVertices); pushNewVertexImpl(vertIn, transform, rgba); } private void pushNewVerticesIdxImpl(final Vertex vertIn1, final Vertex vertIn2, final Vertex vertIn3, final AffineTransform transform, final Vec4f rgba) { pushIndices(numVertices, numVertices+1, numVertices+2); pushNewVerticesImpl(vertIn1, vertIn2, vertIn3, transform, rgba); } protected static void put3i(final IntBuffer b, final int v1, final int v2, final int v3) { b.put(v1); b.put(v2); b.put(v3); } protected static void put3s(final ShortBuffer b, final short v1, final short v2, final short v3) { b.put(v1); b.put(v2); b.put(v3); } protected static void put3f(final FloatBuffer b, final Vec3f v) { b.put(v.x()); b.put(v.y()); b.put(v.z()); } protected static void put4f(final FloatBuffer b, final float v1, final float v2, final float v3, final float v4) { b.put(v1); b.put(v2); b.put(v3); b.put(v4); } protected static void put4f(final FloatBuffer b, final Vec4f v) { b.put(v.x()); b.put(v.y()); b.put(v.z()); b.put(v.w()); } private final AABBox tmpBox = new AABBox(); protected static final int GL_UINT16_MAX = 0xffff; // 65,535 protected static final int GL_INT32_MAX = 0x7fffffff; // 2,147,483,647 static class Perf { // all td_ values are in [ns] long td_vertices = 0; long td_tri_push_idx = 0; long td_tri_push_vertidx = 0; long td_tri_misc = 0; long td_tri_total = 0; // incl tac_ns_tri_push_vertidx + tac_ns_tri_push_idx + tac_ns_tri_misc long td_total = 0; // incl tac_ns_triangles + tac_ns_vertices long count = 0; public void print(final PrintStream out) { final long tac_ns_triangles_self = td_tri_total - td_tri_push_vertidx - td_tri_push_idx - td_tri_misc; final long tac_ns_total_self = td_total - td_tri_total - td_vertices; out.printf("Region.add(): count %,3d, total %,5d [ms], per-add %,4.2f [ns]%n", count, TimeUnit.NANOSECONDS.toMillis(td_total), ((double)td_total/count)); out.printf(" total self %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(tac_ns_total_self), ((double)tac_ns_total_self/count)); out.printf(" vertices %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(td_vertices), ((double)td_vertices/count)); out.printf(" triangles total %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(td_tri_total), ((double)td_tri_total/count)); out.printf(" triangles self %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(tac_ns_triangles_self), ((double)tac_ns_triangles_self/count)); out.printf(" tri misc %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(td_tri_misc), ((double)td_tri_misc/count)); out.printf(" tri p-idx %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(td_tri_push_idx), ((double)td_tri_push_idx/count)); out.printf(" tri p-vertidx %,5d [ms], per-add %,4.2f [ns]%n", TimeUnit.NANOSECONDS.toMillis(td_tri_push_vertidx), ((double)td_tri_push_vertidx/count)); } public void clear() { td_vertices = 0; td_tri_push_idx = 0; td_tri_push_vertidx = 0; td_tri_misc = 0; td_tri_total = 0; td_total = 0; count = 0; } } private Perf perf = null; private final PerfCounterCtrl perfCounterCtrl = new PerfCounterCtrl() { @Override public void enable(final boolean enable) { if( enable ) { if( null != perf ) { perf.clear(); } else { perf = new Perf(); } } else { perf = null; } } @Override public void clear() { if( null != perf ) { perf.clear(); } } @Override public long getTotalDuration() { if( null != perf ) { return perf.td_total; } else { return 0; } } @Override public void print(final PrintStream out) { if( null != perf ) { perf.print(out); } } }; public PerfCounterCtrl perfCounter() { return perfCounterCtrl; } /** * Count required number of vertices and indices adding to given int[2] `vertIndexCount` array. ** The region's buffer can be either set using {@link Region#setBufferCapacity(int, int)}, * {@link GLRegion#create(GLProfile, int, TextureSequence, int, int) GLRegion ctor w/ initial capacities} * or grown using {@link Region#growBuffer(int, int)}. *
** Method is utilized in {@link GLRegion#create(GLProfile, int, TextureSequence, com.jogamp.graph.font.Font, CharSequence) GLRegion ctor w/ font + text}, * computing the initial capacity. *
* @param shape the {@link OutlineShape} to count * @param vertIndexCount the int[2] storage where the counted vertices and indices are added, vertices at [0] and indices at [1] * @see #setBufferCapacity(int, int) * @see #growBuffer(int, int) */ public static final void countOutlineShape(final OutlineShape shape, final int[/*2*/] vertIndexCount) { final List* The region's buffer can be either set using {@link Region#setBufferCapacity(int, int)}, * {@link GLRegion#create(GLProfile, int, TextureSequence, int, int) GLRegion ctor w/ initial capacities} * or grown using {@link Region#growBuffer(int, int)}. *
* @param shapes list of {@link OutlineShape} to count * @param vertIndexCount the int[2] storage where the counted vertices and indices are added, vertices at [0] and indices at [1] * @see #setBufferCapacity(int, int) * @see #growBuffer(int, int) */ public static final void countOutlineShapes(final List* In case {@link #setFrustum(Frustum) frustum culling is set}, the {@link OutlineShape} * is dropped if it's {@link OutlineShape#getBounds() bounding-box} is fully outside of the frustum. * The optional {@link AffineTransform} is applied to the bounding-box beforehand. *
* @param shape the {@link OutlineShape} to add * @param t the optional {@link AffineTransform} to be applied on each vertex * @param rgbaColor if {@link #hasColorChannel()} RGBA color must be passed, otherwise value is ignored. */ public final void addOutlineShape(final OutlineShape shape, final AffineTransform t, final Vec4f rgbaColor) { if( null != frustum ) { final AABBox shapeBox = shape.getBounds(); final AABBox shapeBoxT; if( null != t ) { t.transform(shapeBox, tmpBox); shapeBoxT = tmpBox; } else { shapeBoxT = shapeBox; } if( frustum.isAABBoxOutside(shapeBoxT) ) { return; } } if( null == perf && !DEBUG_INSTANCE ) { addOutlineShape0(shape, t, rgbaColor); } else { if( null == perf ) { perfCounter().enable(true); } addOutlineShape1(shape, t, rgbaColor); } markShapeDirty(); } private final void addOutlineShape0(final OutlineShape shape, final AffineTransform t, final Vec4f rgbaColor) { final List* In case {@link #setFrustum(Frustum) frustum culling is set}, the {@link OutlineShape}s * are dropped if it's {@link OutlineShape#getBounds() bounding-box} is fully outside of the frustum. * The optional {@link AffineTransform} is applied to the bounding-box beforehand. *
* @param shapes list of {@link OutlineShape} to add * @param t the optional {@link AffineTransform} to be applied on each vertex * @param rgbaColor if {@link #hasColorChannel()} RGBA color must be passed, otherwise value is ignored. */ public final void addOutlineShapes(final List* The data will be re-uploaded to the GPU at next {@link GLRegion#draw(com.jogamp.opengl.GL2ES2, com.jogamp.graph.curve.opengl.RegionRenderer, int[]) draw(..)}. *
** In 2-pass mode, this implies updating the FBO itself as well. *
*/ public final void markShapeDirty() { dirty |= DIRTY_SHAPE; } /** Returns true if this region's shape are dirty, see {@link #markShapeDirty()}. */ public final boolean isShapeDirty() { return 0 != ( dirty & DIRTY_SHAPE ) ; } /** * Mark this region's render-state dirty, i.e. re-selecting a shader program regarding color-texture and -channel, * and rendering the region into the FBO in 2-pass mode. ** In 1-pass mode, re-selection of the shader-program is based on color-texture and -channel only. *
*/ public final void markStateDirty() { dirty |= DIRTY_STATE; } /** Returns true if this region's state is dirty, see {@link #markStateDirty()}. */ public final boolean isStateDirty() { return 0 != ( dirty & DIRTY_STATE ) ; } /** * See {@link #markShapeDirty()} and {@link #markStateDirty()}. */ protected final void clearDirtyBits(final int v) { dirty &= ~v; } protected final int getDirtyBits() { return dirty; } @Override public String toString() { return "Region["+getRenderModeString(this.renderModes)+", q "+quality+", dirty "+dirty+", vertices "+numVertices+", box "+box+"]"; } }