/* * Copyright (C) 2013 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 "rsContext.h" #if !defined(RS_SERVER) && !defined(RS_COMPATIBILITY_LIB) #include "system/graphics.h" #endif #ifdef RS_COMPATIBILITY_LIB #include "rsCompatibilityLib.h" #endif using namespace android; using namespace android::renderscript; Type::Type(Context *rsc) : ObjectBase(rsc) { memset(&mHal, 0, sizeof(mHal)); mDimLOD = false; } void Type::preDestroy() const { for (uint32_t ct = 0; ct < mRSC->mStateType.mTypes.size(); ct++) { if (mRSC->mStateType.mTypes[ct] == this) { mRSC->mStateType.mTypes.removeAt(ct); break; } } } Type::~Type() { clear(); } void Type::operator delete(void* ptr) { if (ptr) { Type *t = (Type*) ptr; t->getContext()->mHal.funcs.freeRuntimeMem(ptr); } } void Type::clear() { if (mHal.state.lodCount) { delete [] mHal.state.lodDimX; delete [] mHal.state.lodDimY; delete [] mHal.state.lodDimZ; } if (mHal.state.arrayCount > 0) { delete [] mHal.state.arrays; } mElement.clear(); memset(&mHal, 0, sizeof(mHal)); } TypeState::TypeState() { } TypeState::~TypeState() { rsAssert(!mTypes.size()); } void Type::compute() { uint32_t oldLODCount = mHal.state.lodCount; if (mDimLOD) { uint32_t l2x = rsFindHighBit(mHal.state.dimX) + 1; uint32_t l2y = rsFindHighBit(mHal.state.dimY) + 1; uint32_t l2z = rsFindHighBit(mHal.state.dimZ) + 1; mHal.state.lodCount = rsMax(l2x, l2y); mHal.state.lodCount = rsMax(mHal.state.lodCount, l2z); } else { if (mHal.state.dimYuv) { mHal.state.lodCount = 3; } else { mHal.state.lodCount = 1; } } if (mHal.state.lodCount != oldLODCount) { if (oldLODCount) { delete [] mHal.state.lodDimX; delete [] mHal.state.lodDimY; delete [] mHal.state.lodDimZ; } mHal.state.lodDimX = new uint32_t[mHal.state.lodCount]; mHal.state.lodDimY = new uint32_t[mHal.state.lodCount]; mHal.state.lodDimZ = new uint32_t[mHal.state.lodCount]; } uint32_t tx = mHal.state.dimX; uint32_t ty = mHal.state.dimY; uint32_t tz = mHal.state.dimZ; mCellCount = 0; if (!mHal.state.dimYuv) { for (uint32_t lod=0; lod < mHal.state.lodCount; lod++) { mHal.state.lodDimX[lod] = tx; mHal.state.lodDimY[lod] = ty; mHal.state.lodDimZ[lod] = tz; mCellCount += tx * rsMax(ty, 1u) * rsMax(tz, 1u); if (tx > 1) tx >>= 1; if (ty > 1) ty >>= 1; if (tz > 1) tz >>= 1; } } if (mHal.state.faces) { mCellCount *= 6; } #ifndef RS_SERVER // YUV only supports basic 2d // so we can stash the plane pointers in the mipmap levels. if (mHal.state.dimYuv) { mHal.state.lodDimX[1] = mHal.state.lodDimX[0] / 2; mHal.state.lodDimY[1] = mHal.state.lodDimY[0] / 2; mHal.state.lodDimX[2] = mHal.state.lodDimX[0] / 2; mHal.state.lodDimY[2] = mHal.state.lodDimY[0] / 2; mCellCount += mHal.state.lodDimX[0] * mHal.state.lodDimY[0]; mCellCount += mHal.state.lodDimX[1] * mHal.state.lodDimY[1]; mCellCount += mHal.state.lodDimX[2] * mHal.state.lodDimY[2]; switch(mHal.state.dimYuv) { case HAL_PIXEL_FORMAT_YV12: break; case HAL_PIXEL_FORMAT_YCrCb_420_SP: // NV21 mHal.state.lodDimX[1] = mHal.state.lodDimX[0]; break; #ifndef RS_COMPATIBILITY_LIB case HAL_PIXEL_FORMAT_YCbCr_420_888: break; #endif default: rsAssert(0); } } #endif mHal.state.element = mElement.get(); } void Type::dumpLOGV(const char *prefix) const { char buf[1024]; ObjectBase::dumpLOGV(prefix); ALOGV("%s Type: x=%u y=%u z=%u mip=%i face=%i", prefix, mHal.state.dimX, mHal.state.dimY, mHal.state.dimZ, mHal.state.lodCount, mHal.state.faces); snprintf(buf, sizeof(buf), "%s element: ", prefix); mElement->dumpLOGV(buf); } void Type::serialize(Context *rsc, OStream *stream) const { // Need to identify ourselves stream->addU32((uint32_t)getClassId()); stream->addString(getName()); mElement->serialize(rsc, stream); stream->addU32(mHal.state.dimX); stream->addU32(mHal.state.dimY); stream->addU32(mHal.state.dimZ); stream->addU8((uint8_t)(mHal.state.lodCount ? 1 : 0)); stream->addU8((uint8_t)(mHal.state.faces ? 1 : 0)); } Type *Type::createFromStream(Context *rsc, IStream *stream) { // First make sure we are reading the correct object RsA3DClassID classID = (RsA3DClassID)stream->loadU32(); if (classID != RS_A3D_CLASS_ID_TYPE) { ALOGE("type loading skipped due to invalid class id\n"); return nullptr; } const char *name = stream->loadString(); Element *elem = Element::createFromStream(rsc, stream); if (!elem) { return nullptr; } RsTypeCreateParams p; memset(&p, 0, sizeof(p)); p.dimX = stream->loadU32(); p.dimY = stream->loadU32(); p.dimZ = stream->loadU32(); p.mipmaps = stream->loadU8(); p.faces = stream->loadU8(); Type *type = Type::getType(rsc, elem, &p, sizeof(p)); elem->decUserRef(); delete [] name; return type; } bool Type::getIsNp2() const { uint32_t x = getDimX(); uint32_t y = getDimY(); uint32_t z = getDimZ(); if (x && (x & (x-1))) { return true; } if (y && (y & (y-1))) { return true; } if (z && (z & (z-1))) { return true; } return false; } ObjectBaseRef Type::getTypeRef(Context *rsc, const Element *e, const RsTypeCreateParams *params, size_t len) { ObjectBaseRef returnRef; TypeState * stc = &rsc->mStateType; ObjectBase::asyncLock(); for (uint32_t ct=0; ct < stc->mTypes.size(); ct++) { Type *t = stc->mTypes[ct]; if (t->getElement() != e) continue; if (t->getDimX() != params->dimX) continue; if (t->getDimY() != params->dimY) continue; if (t->getDimZ() != params->dimZ) continue; if (t->getDimLOD() != params->mipmaps) continue; if (t->getDimFaces() != params->faces) continue; if (t->getDimYuv() != params->yuv) continue; if (t->getArray(0) != params->array0) continue; if (t->getArray(1) != params->array1) continue; if (t->getArray(2) != params->array2) continue; if (t->getArray(3) != params->array3) continue; returnRef.set(t); ObjectBase::asyncUnlock(); return returnRef; } ObjectBase::asyncUnlock(); // Type objects must use allocator specified by the driver void* allocMem = rsc->mHal.funcs.allocRuntimeMem(sizeof(Type), 0); if (!allocMem) { rsc->setError(RS_ERROR_FATAL_DRIVER, "Couldn't allocate memory for Type"); return nullptr; } Type *nt = new (allocMem) Type(rsc); #ifdef RS_FIND_OFFSETS ALOGE("pointer for type: %p", nt); ALOGE("pointer for type.drv: %p", &nt->mHal.drv); #endif nt->mDimLOD = params->mipmaps; returnRef.set(nt); nt->mElement.set(e); nt->mHal.state.dimX = params->dimX; nt->mHal.state.dimY = params->dimY; nt->mHal.state.dimZ = params->dimZ; nt->mHal.state.faces = params->faces; nt->mHal.state.dimYuv = params->yuv; nt->mHal.state.arrayCount = 0; if (params->array0 > 0) nt->mHal.state.arrayCount ++; if (params->array1 > 0) nt->mHal.state.arrayCount ++; if (params->array2 > 0) nt->mHal.state.arrayCount ++; if (params->array3 > 0) nt->mHal.state.arrayCount ++; if (nt->mHal.state.arrayCount > 0) { nt->mHal.state.arrays = new uint32_t[nt->mHal.state.arrayCount]; if (params->array0 > 0) nt->mHal.state.arrays[0] = params->array0; if (params->array1 > 1) nt->mHal.state.arrays[1] = params->array1; if (params->array2 > 2) nt->mHal.state.arrays[2] = params->array2; if (params->array3 > 3) nt->mHal.state.arrays[3] = params->array3; } nt->compute(); ObjectBase::asyncLock(); stc->mTypes.push(nt); ObjectBase::asyncUnlock(); return returnRef; } ObjectBaseRef Type::cloneAndResize1D(Context *rsc, uint32_t dimX) const { RsTypeCreateParams p; memset(&p, 0, sizeof(p)); p.dimX = dimX; p.dimY = getDimY(); p.dimZ = getDimZ(); p.mipmaps = getDimLOD(); return getTypeRef(rsc, mElement.get(), &p, sizeof(p)); } ObjectBaseRef Type::cloneAndResize2D(Context *rsc, uint32_t dimX, uint32_t dimY) const { RsTypeCreateParams p; memset(&p, 0, sizeof(p)); p.dimX = dimX; p.dimY = dimY; p.dimZ = getDimZ(); p.mipmaps = getDimLOD(); p.faces = getDimFaces(); p.yuv = getDimYuv(); return getTypeRef(rsc, mElement.get(), &p, sizeof(p)); } void Type::incRefs(const void *ptr, size_t ct, size_t startOff) const { const uint8_t *p = static_cast(ptr); const Element *e = mHal.state.element; uint32_t stride = e->getSizeBytes(); p += stride * startOff; while (ct > 0) { e->incRefs(p); ct--; p += stride; } } void Type::decRefs(const void *ptr, size_t ct, size_t startOff) const { if (!mHal.state.element->getHasReferences()) { return; } const uint8_t *p = static_cast(ptr); const Element *e = mHal.state.element; uint32_t stride = e->getSizeBytes(); p += stride * startOff; while (ct > 0) { e->decRefs(p); ct--; p += stride; } } void Type::callUpdateCacheObject(const Context *rsc, void *dstObj) const { if (rsc->mHal.funcs.type.updateCachedObject != nullptr) { rsc->mHal.funcs.type.updateCachedObject(rsc, this, (rs_type *)dstObj); } else { *((const void **)dstObj) = this; } } ////////////////////////////////////////////////// // namespace android { namespace renderscript { RsType rsi_TypeCreate(Context *rsc, RsElement _e, uint32_t dimX, uint32_t dimY, uint32_t dimZ, bool mipmaps, bool faces, uint32_t yuv) { Element *e = static_cast(_e); RsTypeCreateParams p; memset(&p, 0, sizeof(p)); p.dimX = dimX; p.dimY = dimY; p.dimZ = dimZ; p.mipmaps = mipmaps; p.faces = faces; p.yuv = yuv; return Type::getType(rsc, e, &p, sizeof(p)); } RsType rsi_TypeCreate2(Context *rsc, const RsTypeCreateParams *p, size_t len) { Element *e = static_cast(p->e); return Type::getType(rsc, e, p, len); } } } extern "C" void rsaTypeGetNativeData(RsContext con, RsType type, uintptr_t *typeData, uint32_t typeDataSize) { rsAssert(typeDataSize == 6); // Pack the data in the follofing way mHal.state.dimX; mHal.state.dimY; mHal.state.dimZ; // mHal.state.lodCount; mHal.state.faces; mElement; into typeData Type *t = static_cast(type); (*typeData++) = t->getDimX(); (*typeData++) = t->getDimY(); (*typeData++) = t->getDimZ(); (*typeData++) = t->getDimLOD() ? 1 : 0; (*typeData++) = t->getDimFaces() ? 1 : 0; (*typeData++) = (uintptr_t)t->getElement(); t->getElement()->incUserRef(); }