Esempio n. 1
0
 private Node constructMesh() {
   Node toReturn = new Node("MD3 File");
   for (int i = 0; i < head.numSurface; i++) {
     vkc = new KeyframeController();
     MD3Surface thisSurface = surfaces[i];
     TriMesh object = new TriMesh(thisSurface.name);
     object.setIndexBuffer(BufferUtils.createIntBuffer(thisSurface.triIndexes));
     object.setVertexBuffer(BufferUtils.createFloatBuffer(thisSurface.verts[0]));
     object.setNormalBuffer(BufferUtils.createFloatBuffer(thisSurface.norms[0]));
     object.setTextureCoords(TexCoords.makeNew(thisSurface.texCoords));
     toReturn.attachChild(object);
     vkc.setMorphingMesh(object);
     for (int j = 0; j < head.numFrames; j++) {
       TriMesh etm = new TriMesh();
       etm.setVertexBuffer(BufferUtils.createFloatBuffer(thisSurface.verts[j]));
       etm.setNormalBuffer(BufferUtils.createFloatBuffer(thisSurface.norms[j]));
       vkc.setKeyframe(j, etm);
     }
     vkc.setActive(true);
     vkc.setSpeed(5);
     object.addController(vkc);
     toReturn.addController(vkc);
   }
   nullAll();
   return toReturn;
 }
Esempio n. 2
0
 protected void duUpdateGeometryIndices() {
   setMode(TriMesh.Mode.Strip);
   if (getIndexBuffer() == null) {
     int[] indices = {1, 0, 4, 5, 7, 0, 3, 1, 2, 4, 6, 7, 2, 3};
     setIndexBuffer(BufferUtils.createIntBuffer(indices));
   }
 }
Esempio n. 3
0
 /** Process and setup the index buffer. */
 private void processIndex() {
   IntBuffer indexBuffer = BufferUtils.createIntBuffer(this.triangles.length * 3);
   indexBuffer.clear();
   for (ITriangle triangle : this.triangles) {
     for (int j = 0; j < 3; j++) {
       indexBuffer.put(triangle.getVertex(j).getIndex());
     }
   }
   indexBuffer.flip();
   this.setIndexBuffer(indexBuffer);
 }
  /**
   * Queries OpenGL for errors in the fragment program. Errors are logged as SEVERE, noting both the
   * line number and message.
   */
  private void checkProgramError() {
    if (GL11.glGetError() == GL11.GL_INVALID_OPERATION) {
      // retrieve the error position
      IntBuffer errorloc = BufferUtils.createIntBuffer(16);
      GL11.glGetInteger(ARBProgram.GL_PROGRAM_ERROR_POSITION_ARB, errorloc);

      logger.severe(
          "Error "
              + GL11.glGetString(ARBProgram.GL_PROGRAM_ERROR_STRING_ARB)
              + " in fragment program on line "
              + errorloc.get(0));
    }
  }
  private void create() {
    // first assert that the program is loaded
    if (program == null) {
      logger.severe("Attempted to apply unloaded fragment program state.");
      return;
    }

    IntBuffer buf = BufferUtils.createIntBuffer(1);

    ARBProgram.glGenProgramsARB(buf);
    ARBProgram.glBindProgramARB(ARBFragmentProgram.GL_FRAGMENT_PROGRAM_ARB, buf.get(0));
    ARBProgram.glProgramStringARB(
        ARBFragmentProgram.GL_FRAGMENT_PROGRAM_ARB,
        ARBProgram.GL_PROGRAM_FORMAT_ASCII_ARB,
        program);

    checkProgramError();

    programID = buf.get(0);
  }
  /**
   * <code>tessellate</code> generates the <code>BezierMesh</code> vertices from the supplied patch
   * and detail level. This method is called when patch is set, and therefore, should normally have
   * to be called. However, if patch is changed externally, and you wish to update the mesh, a call
   * to <code>tessellate</code> is appropriate.
   */
  public void tessellate() {
    if (patch == null) {
      return;
    }
    int u = 0, v;
    float py, px, pyold;
    int detailLevel = patch.getDetailLevel();

    Vector3f[] temp = new Vector3f[4];
    Vector3f[] last = new Vector3f[detailLevel + 1];

    temp[0] = patch.getAnchor(0, 3);
    temp[1] = patch.getAnchor(1, 3);
    temp[2] = patch.getAnchor(2, 3);
    temp[3] = patch.getAnchor(3, 3);

    for (v = 0; v <= detailLevel; v++) {
      px = ((float) v) / ((float) detailLevel);
      last[v] = calcBerstein(px, temp);
    }

    u = 1;
    setVertexCount(((detailLevel * 2) + 2) * detailLevel);
    setVertexBuffer(BufferUtils.createVector3Buffer(getVertexCount()));
    setTextureCoords(new TexCoords(BufferUtils.createFloatBuffer(getVertexCount() * 2), 2), 0);
    setNormalBuffer(BufferUtils.createVector3Buffer(getVertexCount()));

    setTriangleQuantity(detailLevel * detailLevel * 6);
    setIndexBuffer(BufferUtils.createIntBuffer(getTriangleCount() * 3));

    getVertexBuffer().clear();
    FloatBuffer src = getTextureCoords().get(0).coords;
    src.clear();
    for (u = 1; u <= detailLevel; u++) {
      py = ((float) u) / ((float) detailLevel);
      pyold = (u - 1.0f) / (detailLevel);
      temp[0] = calcBerstein(py, patch.getAnchors()[0]);
      temp[1] = calcBerstein(py, patch.getAnchors()[1]);
      temp[2] = calcBerstein(py, patch.getAnchors()[2]);
      temp[3] = calcBerstein(py, patch.getAnchors()[3]);

      for (v = 0; v <= detailLevel; v++) {
        px = ((float) v) / ((float) detailLevel);
        src.put(pyold).put(px);
        getVertexBuffer().put(last[v].x).put(last[v].y).put(last[v].z);
        last[v] = calcBerstein(px, temp);
        src.put(py).put(px);
        getVertexBuffer().put(last[v].x).put(last[v].y).put(last[v].z);
      }
    }

    int index = -1;
    for (int i = 0; i < getTriangleCount(); i = i + 6) {

      index++;
      if (i > 0 && i % (detailLevel * 6) == 0) {
        index += 1;
      }

      getIndexBuffer().put(2 * index);
      getIndexBuffer().put((2 * index) + 1);
      getIndexBuffer().put((2 * index) + 2);

      getIndexBuffer().put((2 * index) + 3);
      getIndexBuffer().put((2 * index) + 2);
      getIndexBuffer().put((2 * index) + 1);
    }

    setNormalBuffer(BufferUtils.createVector3Buffer(getVertexCount()));
    Vector3f oppositePoint = new Vector3f();
    Vector3f adjacentPoint = new Vector3f();
    Vector3f rootPoint = new Vector3f();
    Vector3f tempNorm = new Vector3f();
    int adj = 0, opp = 0, normalIndex = 0;
    for (int i = 0; i < detailLevel; i++) {
      for (int j = 0; j < (detailLevel * 2) + 2; j++) {
        BufferUtils.populateFromBuffer(rootPoint, getVertexBuffer(), normalIndex);
        if (j % 2 == 0) {
          if (i == 0) {
            if (j < (detailLevel * 2)) {
              // right cross up
              adj = normalIndex + 1;
              opp = normalIndex + 2;
            } else {
              // down cross right
              adj = normalIndex - 1;
              opp = normalIndex + 1;
            }
          } else {
            int ind = normalIndex - (detailLevel * 2 + 1);
            getNormalBuffer().rewind();
            tempNorm.x = getNormalBuffer().get(ind * 3);
            tempNorm.y = getNormalBuffer().get(ind * 3 + 1);
            tempNorm.z = getNormalBuffer().get(ind * 3 + 2);
            tempNorm.normalizeLocal();
            BufferUtils.setInBuffer(tempNorm, getNormalBuffer(), normalIndex);
            normalIndex++;
            continue;
          }
        } else {
          if (j < (detailLevel * 2) + 1) {
            // up cross left
            adj = normalIndex + 2;
            opp = normalIndex - 1;
          } else {
            // left cross down
            adj = normalIndex - 1;
            opp = normalIndex - 2;
          }
        }
        BufferUtils.populateFromBuffer(adjacentPoint, getVertexBuffer(), adj);
        BufferUtils.populateFromBuffer(oppositePoint, getVertexBuffer(), opp);
        tempNorm
            .set(adjacentPoint)
            .subtractLocal(rootPoint)
            .crossLocal(oppositePoint.subtractLocal(rootPoint))
            .normalizeLocal();
        BufferUtils.setInBuffer(tempNorm, getNormalBuffer(), normalIndex);
        normalIndex++;
      }
    }
  }