/** ** Copyright 2007, The Android Open Source Project ** ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** ** http://www.apache.org/licenses/LICENSE-2.0 ** ** Unless required by applicable law or agreed to in writing, software ** distributed under the License is distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include "android_runtime/AndroidRuntime.h" #undef LOG_TAG #define LOG_TAG "OpenGLUtil" #include #include "utils/misc.h" #include "poly.h" namespace android { static jclass gIAEClass; static jclass gUOEClass; static jclass gAIOOBEClass; static inline void mx4transform(float x, float y, float z, float w, const float* pM, float* pDest) { pDest[0] = pM[0 + 4 * 0] * x + pM[0 + 4 * 1] * y + pM[0 + 4 * 2] * z + pM[0 + 4 * 3] * w; pDest[1] = pM[1 + 4 * 0] * x + pM[1 + 4 * 1] * y + pM[1 + 4 * 2] * z + pM[1 + 4 * 3] * w; pDest[2] = pM[2 + 4 * 0] * x + pM[2 + 4 * 1] * y + pM[2 + 4 * 2] * z + pM[2 + 4 * 3] * w; pDest[3] = pM[3 + 4 * 0] * x + pM[3 + 4 * 1] * y + pM[3 + 4 * 2] * z + pM[3 + 4 * 3] * w; } class MallocHelper { public: MallocHelper() { mData = 0; } ~MallocHelper() { if (mData != 0) { free(mData); } } void* alloc(size_t size) { mData = malloc(size); return mData; } private: void* mData; }; #if 0 static void print_poly(const char* label, Poly* pPoly) { LOGI("%s: %d verts", label, pPoly->n); for(int i = 0; i < pPoly->n; i++) { Poly_vert* pV = & pPoly->vert[i]; LOGI("[%d] %g, %g, %g %g", i, pV->sx, pV->sy, pV->sz, pV->sw); } } #endif static int visibilityTest(float* pWS, float* pPositions, int positionsLength, unsigned short* pIndices, int indexCount) { MallocHelper mallocHelper; int result = POLY_CLIP_OUT; float* pTransformed = 0; int transformedIndexCount = 0; if ( indexCount < 3 ) { return POLY_CLIP_OUT; } // Find out how many vertices we need to transform // We transform every vertex between the min and max indices, inclusive. // This is OK for the data sets we expect to use with this function, but // for other loads it might be better to use a more sophisticated vertex // cache of some sort. int minIndex = 65536; int maxIndex = -1; for(int i = 0; i < indexCount; i++) { int index = pIndices[i]; if ( index < minIndex ) { minIndex = index; } if ( index > maxIndex ) { maxIndex = index; } } if ( maxIndex * 3 > positionsLength) { return -1; } transformedIndexCount = maxIndex - minIndex + 1; pTransformed = (float*) mallocHelper.alloc(transformedIndexCount * 4 * sizeof(float)); if (pTransformed == 0 ) { return -2; } // Transform the vertices { const float* pSrc = pPositions + 3 * minIndex; float* pDst = pTransformed; for (int i = 0; i < transformedIndexCount; i++, pSrc += 3, pDst += 4) { mx4transform(pSrc[0], pSrc[1], pSrc[2], 1.0f, pWS, pDst); } } // Clip the triangles Poly poly; float* pDest = & poly.vert[0].sx; for (int i = 0; i < indexCount; i += 3) { poly.n = 3; memcpy(pDest , pTransformed + 4 * (pIndices[i ] - minIndex), 4 * sizeof(float)); memcpy(pDest + 4, pTransformed + 4 * (pIndices[i + 1] - minIndex), 4 * sizeof(float)); memcpy(pDest + 8, pTransformed + 4 * (pIndices[i + 2] - minIndex), 4 * sizeof(float)); result = poly_clip_to_frustum(&poly); if ( result != POLY_CLIP_OUT) { return result; } } return result; } template class ArrayHelper { public: ArrayHelper(JNIEnv* env, JArray ref, jint offset, jint minSize) { mEnv = env; mRef = ref; mOffset = offset; mMinSize = minSize; mBase = 0; mReleaseParam = JNI_ABORT; } ~ArrayHelper() { if (mBase) { mEnv->ReleasePrimitiveArrayCritical(mRef, mBase, mReleaseParam); } } // We seperate the bounds check from the initialization because we want to // be able to bounds-check multiple arrays, and we can't throw an exception // after we've called GetPrimitiveArrayCritical. // Return true if the bounds check succeeded // Else instruct the runtime to throw an exception bool check() { if ( ! mRef) { mEnv->ThrowNew(gIAEClass, "array == null"); return false; } if ( mOffset < 0) { mEnv->ThrowNew(gIAEClass, "offset < 0"); return false; } mLength = mEnv->GetArrayLength(mRef) - mOffset; if (mLength < mMinSize ) { mEnv->ThrowNew(gIAEClass, "length - offset < n"); return false; } return true; } // Bind the array. void bind() { mBase = (T*) mEnv->GetPrimitiveArrayCritical(mRef, (jboolean *) 0); mData = mBase + mOffset; } void commitChanges() { mReleaseParam = 0; } T* mData; int mLength; private: T* mBase; JNIEnv* mEnv; JArray mRef; jint mOffset; jint mMinSize; int mReleaseParam; }; typedef ArrayHelper FloatArrayHelper; typedef ArrayHelper UnsignedShortArrayHelper; typedef ArrayHelper IntArrayHelper; typedef ArrayHelper ByteArrayHelper; inline float distance2(float x, float y, float z) { return x * x + y * y + z * z; } inline float distance(float x, float y, float z) { return sqrtf(distance2(x, y, z)); } static void util_computeBoundingSphere(JNIEnv *env, jclass clazz, jfloatArray positions_ref, jint positionsOffset, jint positionsCount, jfloatArray sphere_ref, jint sphereOffset) { FloatArrayHelper positions(env, positions_ref, positionsOffset, 0); FloatArrayHelper sphere(env, sphere_ref, sphereOffset, 4); bool checkOK = positions.check() && sphere.check(); if (! checkOK) { return; } positions.bind(); sphere.bind(); if ( positionsCount < 1 ) { env->ThrowNew(gIAEClass, "positionsCount < 1"); return; } const float* pSrc = positions.mData; // find bounding box float x0 = *pSrc++; float x1 = x0; float y0 = *pSrc++; float y1 = y0; float z0 = *pSrc++; float z1 = z0; for(int i = 1; i < positionsCount; i++) { { float x = *pSrc++; if (x < x0) { x0 = x; } else if (x > x1) { x1 = x; } } { float y = *pSrc++; if (y < y0) { y0 = y; } else if (y > y1) { y1 = y; } } { float z = *pSrc++; if (z < z0) { z0 = z; } else if (z > z1) { z1 = z; } } } // Because we know our input meshes fit pretty well into bounding boxes, // just take the diagonal of the box as defining our sphere. float* pSphere = sphere.mData; float dx = x1 - x0; float dy = y1 - y0; float dz = z1 - z0; *pSphere++ = x0 + dx * 0.5f; *pSphere++ = y0 + dy * 0.5f; *pSphere++ = z0 + dz * 0.5f; *pSphere++ = distance(dx, dy, dz) * 0.5f; sphere.commitChanges(); } static void normalizePlane(float* p) { float rdist = 1.0f / distance(p[0], p[1], p[2]); for(int i = 0; i < 4; i++) { p[i] *= rdist; } } static inline float dot3(float x0, float y0, float z0, float x1, float y1, float z1) { return x0 * x1 + y0 * y1 + z0 * z1; } static inline float signedDistance(const float* pPlane, float x, float y, float z) { return dot3(pPlane[0], pPlane[1], pPlane[2], x, y, z) + pPlane[3]; } // Return true if the sphere intersects or is inside the frustum static bool sphereHitsFrustum(const float* pFrustum, const float* pSphere) { float x = pSphere[0]; float y = pSphere[1]; float z = pSphere[2]; float negRadius = -pSphere[3]; for (int i = 0; i < 6; i++, pFrustum += 4) { if (signedDistance(pFrustum, x, y, z) <= negRadius) { return false; } } return true; } static void computeFrustum(const float* m, float* f) { float m3 = m[3]; float m7 = m[7]; float m11 = m[11]; float m15 = m[15]; // right f[0] = m3 - m[0]; f[1] = m7 - m[4]; f[2] = m11 - m[8]; f[3] = m15 - m[12]; normalizePlane(f); f+= 4; // left f[0] = m3 + m[0]; f[1] = m7 + m[4]; f[2] = m11 + m[8]; f[3] = m15 + m[12]; normalizePlane(f); f+= 4; // top f[0] = m3 - m[1]; f[1] = m7 - m[5]; f[2] = m11 - m[9]; f[3] = m15 - m[13]; normalizePlane(f); f+= 4; // bottom f[0] = m3 + m[1]; f[1] = m7 + m[5]; f[2] = m11 + m[9]; f[3] = m15 + m[13]; normalizePlane(f); f+= 4; // far f[0] = m3 - m[2]; f[1] = m7 - m[6]; f[2] = m11 - m[10]; f[3] = m15 - m[14]; normalizePlane(f); f+= 4; // near f[0] = m3 + m[2]; f[1] = m7 + m[6]; f[2] = m11 + m[10]; f[3] = m15 + m[14]; normalizePlane(f); } static int util_frustumCullSpheres(JNIEnv *env, jclass clazz, jfloatArray mvp_ref, jint mvpOffset, jfloatArray spheres_ref, jint spheresOffset, jint spheresCount, jintArray results_ref, jint resultsOffset, jint resultsCapacity) { float frustum[6*4]; int outputCount; int* pResults; float* pSphere; FloatArrayHelper mvp(env, mvp_ref, mvpOffset, 16); FloatArrayHelper spheres(env, spheres_ref, spheresOffset, spheresCount * 4); IntArrayHelper results(env, results_ref, resultsOffset, resultsCapacity); bool initializedOK = mvp.check() && spheres.check() && results.check(); if (! initializedOK) { return -1; } mvp.bind(); spheres.bind(); results.bind(); computeFrustum(mvp.mData, frustum); // Cull the spheres pSphere = spheres.mData; pResults = results.mData; outputCount = 0; for(int i = 0; i < spheresCount; i++, pSphere += 4) { if (sphereHitsFrustum(frustum, pSphere)) { if (outputCount < resultsCapacity) { *pResults++ = i; } outputCount++; } } results.commitChanges(); return outputCount; } /* public native int visibilityTest(float[] ws, int wsOffset, float[] positions, int positionsOffset, char[] indices, int indicesOffset, int indexCount); */ static int util_visibilityTest(JNIEnv *env, jclass clazz, jfloatArray ws_ref, jint wsOffset, jfloatArray positions_ref, jint positionsOffset, jcharArray indices_ref, jint indicesOffset, jint indexCount) { FloatArrayHelper ws(env, ws_ref, wsOffset, 16); FloatArrayHelper positions(env, positions_ref, positionsOffset, 0); UnsignedShortArrayHelper indices(env, indices_ref, indicesOffset, 0); bool checkOK = ws.check() && positions.check() && indices.check(); if (! checkOK) { // Return value will be ignored, because an exception has been thrown. return -1; } if (indices.mLength < indexCount) { env->ThrowNew(gIAEClass, "length < offset + indexCount"); // Return value will be ignored, because an exception has been thrown. return -1; } ws.bind(); positions.bind(); indices.bind(); return visibilityTest(ws.mData, positions.mData, positions.mLength, indices.mData, indexCount); } #define I(_i, _j) ((_j)+ 4*(_i)) static void multiplyMM(float* r, const float* lhs, const float* rhs) { for (int i=0 ; i<4 ; i++) { register const float rhs_i0 = rhs[ I(i,0) ]; register float ri0 = lhs[ I(0,0) ] * rhs_i0; register float ri1 = lhs[ I(0,1) ] * rhs_i0; register float ri2 = lhs[ I(0,2) ] * rhs_i0; register float ri3 = lhs[ I(0,3) ] * rhs_i0; for (int j=1 ; j<4 ; j++) { register const float rhs_ij = rhs[ I(i,j) ]; ri0 += lhs[ I(j,0) ] * rhs_ij; ri1 += lhs[ I(j,1) ] * rhs_ij; ri2 += lhs[ I(j,2) ] * rhs_ij; ri3 += lhs[ I(j,3) ] * rhs_ij; } r[ I(i,0) ] = ri0; r[ I(i,1) ] = ri1; r[ I(i,2) ] = ri2; r[ I(i,3) ] = ri3; } } static void util_multiplyMM(JNIEnv *env, jclass clazz, jfloatArray result_ref, jint resultOffset, jfloatArray lhs_ref, jint lhsOffset, jfloatArray rhs_ref, jint rhsOffset) { FloatArrayHelper resultMat(env, result_ref, resultOffset, 16); FloatArrayHelper lhs(env, lhs_ref, lhsOffset, 16); FloatArrayHelper rhs(env, rhs_ref, rhsOffset, 16); bool checkOK = resultMat.check() && lhs.check() && rhs.check(); if ( !checkOK ) { return; } resultMat.bind(); lhs.bind(); rhs.bind(); multiplyMM(resultMat.mData, lhs.mData, rhs.mData); resultMat.commitChanges(); } static void multiplyMV(float* r, const float* lhs, const float* rhs) { mx4transform(rhs[0], rhs[1], rhs[2], rhs[3], lhs, r); } static void util_multiplyMV(JNIEnv *env, jclass clazz, jfloatArray result_ref, jint resultOffset, jfloatArray lhs_ref, jint lhsOffset, jfloatArray rhs_ref, jint rhsOffset) { FloatArrayHelper resultV(env, result_ref, resultOffset, 4); FloatArrayHelper lhs(env, lhs_ref, lhsOffset, 16); FloatArrayHelper rhs(env, rhs_ref, rhsOffset, 4); bool checkOK = resultV.check() && lhs.check() && rhs.check(); if ( !checkOK ) { return; } resultV.bind(); lhs.bind(); rhs.bind(); multiplyMV(resultV.mData, lhs.mData, rhs.mData); resultV.commitChanges(); } // --------------------------------------------------------------------------- static jfieldID nativeBitmapID = 0; void nativeUtilsClassInit(JNIEnv *env, jclass clazz) { jclass bitmapClass = env->FindClass("android/graphics/Bitmap"); nativeBitmapID = env->GetFieldID(bitmapClass, "mNativeBitmap", "I"); } static int checkFormat(SkBitmap::Config config, int format, int type) { switch(config) { case SkBitmap::kIndex8_Config: if (format == GL_PALETTE8_RGBA8_OES) return 0; case SkBitmap::kARGB_8888_Config: case SkBitmap::kA8_Config: if (type == GL_UNSIGNED_BYTE) return 0; case SkBitmap::kARGB_4444_Config: case SkBitmap::kRGB_565_Config: switch (type) { case GL_UNSIGNED_SHORT_4_4_4_4: case GL_UNSIGNED_SHORT_5_6_5: case GL_UNSIGNED_SHORT_5_5_5_1: return 0; case GL_UNSIGNED_BYTE: if (format == GL_LUMINANCE_ALPHA) return 0; } break; default: break; } return -1; } static int getInternalFormat(SkBitmap::Config config) { switch(config) { case SkBitmap::kA8_Config: return GL_ALPHA; case SkBitmap::kARGB_4444_Config: return GL_RGBA; case SkBitmap::kARGB_8888_Config: return GL_RGBA; case SkBitmap::kIndex8_Config: return GL_PALETTE8_RGBA8_OES; case SkBitmap::kRGB_565_Config: return GL_RGB; default: return -1; } } static int getType(SkBitmap::Config config) { switch(config) { case SkBitmap::kA8_Config: return GL_UNSIGNED_BYTE; case SkBitmap::kARGB_4444_Config: return GL_UNSIGNED_SHORT_4_4_4_4; case SkBitmap::kARGB_8888_Config: return GL_UNSIGNED_BYTE; case SkBitmap::kIndex8_Config: return -1; // No type for compressed data. case SkBitmap::kRGB_565_Config: return GL_UNSIGNED_SHORT_5_6_5; default: return -1; } } static jint util_getInternalFormat(JNIEnv *env, jclass clazz, jobject jbitmap) { SkBitmap const * nativeBitmap = (SkBitmap const *)env->GetIntField(jbitmap, nativeBitmapID); const SkBitmap& bitmap(*nativeBitmap); SkBitmap::Config config = bitmap.getConfig(); return getInternalFormat(config); } static jint util_getType(JNIEnv *env, jclass clazz, jobject jbitmap) { SkBitmap const * nativeBitmap = (SkBitmap const *)env->GetIntField(jbitmap, nativeBitmapID); const SkBitmap& bitmap(*nativeBitmap); SkBitmap::Config config = bitmap.getConfig(); return getType(config); } static jint util_texImage2D(JNIEnv *env, jclass clazz, jint target, jint level, jint internalformat, jobject jbitmap, jint type, jint border) { SkBitmap const * nativeBitmap = (SkBitmap const *)env->GetIntField(jbitmap, nativeBitmapID); const SkBitmap& bitmap(*nativeBitmap); SkBitmap::Config config = bitmap.getConfig(); if (internalformat < 0) { internalformat = getInternalFormat(config); } if (type < 0) { type = getType(config); } int err = checkFormat(config, internalformat, type); if (err) return err; bitmap.lockPixels(); const int w = bitmap.width(); const int h = bitmap.height(); const void* p = bitmap.getPixels(); if (internalformat == GL_PALETTE8_RGBA8_OES) { if (sizeof(SkPMColor) != sizeof(uint32_t)) { err = -1; goto error; } const size_t size = bitmap.getSize(); const size_t palette_size = 256*sizeof(SkPMColor); const size_t imageSize = size + palette_size; void* const data = malloc(imageSize); if (data) { void* const pixels = (char*)data + palette_size; SkColorTable* ctable = bitmap.getColorTable(); memcpy(data, ctable->lockColors(), ctable->count() * sizeof(SkPMColor)); memcpy(pixels, p, size); ctable->unlockColors(false); glCompressedTexImage2D(target, level, internalformat, w, h, border, imageSize, data); free(data); } else { err = -1; } } else { glTexImage2D(target, level, internalformat, w, h, border, internalformat, type, p); } error: bitmap.unlockPixels(); return err; } static jint util_texSubImage2D(JNIEnv *env, jclass clazz, jint target, jint level, jint xoffset, jint yoffset, jobject jbitmap, jint format, jint type) { SkBitmap const * nativeBitmap = (SkBitmap const *)env->GetIntField(jbitmap, nativeBitmapID); const SkBitmap& bitmap(*nativeBitmap); SkBitmap::Config config = bitmap.getConfig(); if (format < 0) { format = getInternalFormat(config); if (format == GL_PALETTE8_RGBA8_OES) return -1; // glCompressedTexSubImage2D() not supported } int err = checkFormat(config, format, type); if (err) return err; bitmap.lockPixels(); const int w = bitmap.width(); const int h = bitmap.height(); const void* p = bitmap.getPixels(); glTexSubImage2D(target, level, xoffset, yoffset, w, h, format, type, p); bitmap.unlockPixels(); return 0; } /* * ETC1 methods. */ static jclass nioAccessClass; static jclass bufferClass; static jmethodID getBasePointerID; static jmethodID getBaseArrayID; static jmethodID getBaseArrayOffsetID; static jfieldID positionID; static jfieldID limitID; static jfieldID elementSizeShiftID; /* Cache method IDs each time the class is loaded. */ static void nativeClassInitBuffer(JNIEnv *_env) { jclass nioAccessClassLocal = _env->FindClass("java/nio/NIOAccess"); nioAccessClass = (jclass) _env->NewGlobalRef(nioAccessClassLocal); jclass bufferClassLocal = _env->FindClass("java/nio/Buffer"); bufferClass = (jclass) _env->NewGlobalRef(bufferClassLocal); getBasePointerID = _env->GetStaticMethodID(nioAccessClass, "getBasePointer", "(Ljava/nio/Buffer;)J"); getBaseArrayID = _env->GetStaticMethodID(nioAccessClass, "getBaseArray", "(Ljava/nio/Buffer;)Ljava/lang/Object;"); getBaseArrayOffsetID = _env->GetStaticMethodID(nioAccessClass, "getBaseArrayOffset", "(Ljava/nio/Buffer;)I"); positionID = _env->GetFieldID(bufferClass, "position", "I"); limitID = _env->GetFieldID(bufferClass, "limit", "I"); elementSizeShiftID = _env->GetFieldID(bufferClass, "_elementSizeShift", "I"); } static void * getPointer(JNIEnv *_env, jobject buffer, jint *remaining) { jint position; jint limit; jint elementSizeShift; jlong pointer; jint offset; void *data; position = _env->GetIntField(buffer, positionID); limit = _env->GetIntField(buffer, limitID); elementSizeShift = _env->GetIntField(buffer, elementSizeShiftID); *remaining = (limit - position) << elementSizeShift; pointer = _env->CallStaticLongMethod(nioAccessClass, getBasePointerID, buffer); if (pointer != 0L) { return (void *) (jint) pointer; } return NULL; } class BufferHelper { public: BufferHelper(JNIEnv *env, jobject buffer) { mEnv = env; mBuffer = buffer; mData = NULL; mRemaining = 0; } bool checkPointer(const char* errorMessage) { if (mBuffer) { mData = getPointer(mEnv, mBuffer, &mRemaining); if (mData == NULL) { mEnv->ThrowNew(gIAEClass, errorMessage); } return mData != NULL; } else { mEnv->ThrowNew(gIAEClass, errorMessage); return false; } } inline void* getData() { return mData; } inline jint remaining() { return mRemaining; } private: JNIEnv* mEnv; jobject mBuffer; void* mData; jint mRemaining; }; /** * Encode a block of pixels. * * @param in a pointer to a ETC1_DECODED_BLOCK_SIZE array of bytes that represent a * 4 x 4 square of 3-byte pixels in form R, G, B. Byte (3 * (x + 4 * y) is the R * value of pixel (x, y). * * @param validPixelMask is a 16-bit mask where bit (1 << (x + y * 4)) indicates whether * the corresponding (x,y) pixel is valid. Invalid pixel color values are ignored when compressing. * * @param out an ETC1 compressed version of the data. * */ static void etc1_encodeBlock(JNIEnv *env, jclass clazz, jobject in, jint validPixelMask, jobject out) { if (validPixelMask < 0 || validPixelMask > 15) { env->ThrowNew(gIAEClass, "validPixelMask"); return; } BufferHelper inB(env, in); BufferHelper outB(env, out); if (inB.checkPointer("in") && outB.checkPointer("out")) { if (inB.remaining() < ETC1_DECODED_BLOCK_SIZE) { env->ThrowNew(gIAEClass, "in's remaining data < DECODED_BLOCK_SIZE"); } else if (outB.remaining() < ETC1_ENCODED_BLOCK_SIZE) { env->ThrowNew(gIAEClass, "out's remaining data < ENCODED_BLOCK_SIZE"); } else { etc1_encode_block((etc1_byte*) inB.getData(), validPixelMask, (etc1_byte*) outB.getData()); } } } /** * Decode a block of pixels. * * @param in an ETC1 compressed version of the data. * * @param out a pointer to a ETC_DECODED_BLOCK_SIZE array of bytes that represent a * 4 x 4 square of 3-byte pixels in form R, G, B. Byte (3 * (x + 4 * y) is the R * value of pixel (x, y). */ static void etc1_decodeBlock(JNIEnv *env, jclass clazz, jobject in, jobject out){ BufferHelper inB(env, in); BufferHelper outB(env, out); if (inB.checkPointer("in") && outB.checkPointer("out")) { if (inB.remaining() < ETC1_ENCODED_BLOCK_SIZE) { env->ThrowNew(gIAEClass, "in's remaining data < ENCODED_BLOCK_SIZE"); } else if (outB.remaining() < ETC1_DECODED_BLOCK_SIZE) { env->ThrowNew(gIAEClass, "out's remaining data < DECODED_BLOCK_SIZE"); } else { etc1_decode_block((etc1_byte*) inB.getData(), (etc1_byte*) outB.getData()); } } } /** * Return the size of the encoded image data (does not include size of PKM header). */ static jint etc1_getEncodedDataSize(JNIEnv *env, jclass clazz, jint width, jint height) { return etc1_get_encoded_data_size(width, height); } /** * Encode an entire image. * @param in pointer to the image data. Formatted such that * pixel (x,y) is at pIn + pixelSize * x + stride * y + redOffset; * @param out pointer to encoded data. Must be large enough to store entire encoded image. */ static void etc1_encodeImage(JNIEnv *env, jclass clazz, jobject in, jint width, jint height, jint pixelSize, jint stride, jobject out) { if (pixelSize < 2 || pixelSize > 3) { env->ThrowNew(gIAEClass, "pixelSize must be 2 or 3"); return; } BufferHelper inB(env, in); BufferHelper outB(env, out); if (inB.checkPointer("in") && outB.checkPointer("out")) { jint imageSize = stride * height; jint encodedImageSize = etc1_get_encoded_data_size(width, height); if (inB.remaining() < imageSize) { env->ThrowNew(gIAEClass, "in's remaining data < image size"); } else if (outB.remaining() < encodedImageSize) { env->ThrowNew(gIAEClass, "out's remaining data < encoded image size"); } else { int result = etc1_encode_image((etc1_byte*) inB.getData(), width, height, pixelSize, stride, (etc1_byte*) outB.getData()); } } } /** * Decode an entire image. * @param in the encoded data. * @param out pointer to the image data. Will be written such that * pixel (x,y) is at pIn + pixelSize * x + stride * y. Must be * large enough to store entire image. */ static void etc1_decodeImage(JNIEnv *env, jclass clazz, jobject in, jobject out, jint width, jint height, jint pixelSize, jint stride) { if (pixelSize < 2 || pixelSize > 3) { env->ThrowNew(gIAEClass, "pixelSize must be 2 or 3"); return; } BufferHelper inB(env, in); BufferHelper outB(env, out); if (inB.checkPointer("in") && outB.checkPointer("out")) { jint imageSize = stride * height; jint encodedImageSize = etc1_get_encoded_data_size(width, height); if (inB.remaining() < encodedImageSize) { env->ThrowNew(gIAEClass, "in's remaining data < encoded image size"); } else if (outB.remaining() < imageSize) { env->ThrowNew(gIAEClass, "out's remaining data < image size"); } else { int result = etc1_decode_image((etc1_byte*) inB.getData(), (etc1_byte*) outB.getData(), width, height, pixelSize, stride); } } } /** * Format a PKM header */ static void etc1_formatHeader(JNIEnv *env, jclass clazz, jobject header, jint width, jint height) { BufferHelper headerB(env, header); if (headerB.checkPointer("header") ){ if (headerB.remaining() < ETC_PKM_HEADER_SIZE) { env->ThrowNew(gIAEClass, "header's remaining data < ETC_PKM_HEADER_SIZE"); } else { etc1_pkm_format_header((etc1_byte*) headerB.getData(), width, height); } } } /** * Check if a PKM header is correctly formatted. */ static jboolean etc1_isValid(JNIEnv *env, jclass clazz, jobject header) { jboolean result = false; BufferHelper headerB(env, header); if (headerB.checkPointer("header") ){ if (headerB.remaining() < ETC_PKM_HEADER_SIZE) { env->ThrowNew(gIAEClass, "header's remaining data < ETC_PKM_HEADER_SIZE"); } else { result = etc1_pkm_is_valid((etc1_byte*) headerB.getData()); } } return result; } /** * Read the image width from a PKM header */ static jint etc1_getWidth(JNIEnv *env, jclass clazz, jobject header) { jint result = 0; BufferHelper headerB(env, header); if (headerB.checkPointer("header") ){ if (headerB.remaining() < ETC_PKM_HEADER_SIZE) { env->ThrowNew(gIAEClass, "header's remaining data < ETC_PKM_HEADER_SIZE"); } else { result = etc1_pkm_get_width((etc1_byte*) headerB.getData()); } } return result; } /** * Read the image height from a PKM header */ static int etc1_getHeight(JNIEnv *env, jclass clazz, jobject header) { jint result = 0; BufferHelper headerB(env, header); if (headerB.checkPointer("header") ){ if (headerB.remaining() < ETC_PKM_HEADER_SIZE) { env->ThrowNew(gIAEClass, "header's remaining data < ETC_PKM_HEADER_SIZE"); } else { result = etc1_pkm_get_height((etc1_byte*) headerB.getData()); } } return result; } /* * JNI registration */ static void lookupClasses(JNIEnv* env) { gIAEClass = (jclass) env->NewGlobalRef( env->FindClass("java/lang/IllegalArgumentException")); gUOEClass = (jclass) env->NewGlobalRef( env->FindClass("java/lang/UnsupportedOperationException")); gAIOOBEClass = (jclass) env->NewGlobalRef( env->FindClass("java/lang/ArrayIndexOutOfBoundsException")); } static JNINativeMethod gMatrixMethods[] = { { "multiplyMM", "([FI[FI[FI)V", (void*)util_multiplyMM }, { "multiplyMV", "([FI[FI[FI)V", (void*)util_multiplyMV }, }; static JNINativeMethod gVisiblityMethods[] = { { "computeBoundingSphere", "([FII[FI)V", (void*)util_computeBoundingSphere }, { "frustumCullSpheres", "([FI[FII[III)I", (void*)util_frustumCullSpheres }, { "visibilityTest", "([FI[FI[CII)I", (void*)util_visibilityTest }, }; static JNINativeMethod gUtilsMethods[] = { {"nativeClassInit", "()V", (void*)nativeUtilsClassInit }, { "native_getInternalFormat", "(Landroid/graphics/Bitmap;)I", (void*) util_getInternalFormat }, { "native_getType", "(Landroid/graphics/Bitmap;)I", (void*) util_getType }, { "native_texImage2D", "(IIILandroid/graphics/Bitmap;II)I", (void*)util_texImage2D }, { "native_texSubImage2D", "(IIIILandroid/graphics/Bitmap;II)I", (void*)util_texSubImage2D }, }; static JNINativeMethod gEtc1Methods[] = { { "encodeBlock", "(Ljava/nio/Buffer;ILjava/nio/Buffer;)V", (void*) etc1_encodeBlock }, { "decodeBlock", "(Ljava/nio/Buffer;Ljava/nio/Buffer;)V", (void*) etc1_decodeBlock }, { "getEncodedDataSize", "(II)I", (void*) etc1_getEncodedDataSize }, { "encodeImage", "(Ljava/nio/Buffer;IIIILjava/nio/Buffer;)V", (void*) etc1_encodeImage }, { "decodeImage", "(Ljava/nio/Buffer;Ljava/nio/Buffer;IIII)V", (void*) etc1_decodeImage }, { "formatHeader", "(Ljava/nio/Buffer;II)V", (void*) etc1_formatHeader }, { "isValid", "(Ljava/nio/Buffer;)Z", (void*) etc1_isValid }, { "getWidth", "(Ljava/nio/Buffer;)I", (void*) etc1_getWidth }, { "getHeight", "(Ljava/nio/Buffer;)I", (void*) etc1_getHeight }, }; typedef struct _ClassRegistrationInfo { const char* classPath; JNINativeMethod* methods; size_t methodCount; } ClassRegistrationInfo; static ClassRegistrationInfo gClasses[] = { {"android/opengl/Matrix", gMatrixMethods, NELEM(gMatrixMethods)}, {"android/opengl/Visibility", gVisiblityMethods, NELEM(gVisiblityMethods)}, {"android/opengl/GLUtils", gUtilsMethods, NELEM(gUtilsMethods)}, {"android/opengl/ETC1", gEtc1Methods, NELEM(gEtc1Methods)}, }; int register_android_opengl_classes(JNIEnv* env) { lookupClasses(env); nativeClassInitBuffer(env); int result = 0; for (int i = 0; i < NELEM(gClasses); i++) { ClassRegistrationInfo* cri = &gClasses[i]; result = AndroidRuntime::registerNativeMethods(env, cri->classPath, cri->methods, cri->methodCount); if (result < 0) { LOGE("Failed to register %s: %d", cri->classPath, result); break; } } return result; } } // namespace android