/* * Copyright (C) 2008 The Android Open Source Project * Copyright (c) 2010-2014, The Linux Foundation. All rights reserved. * Not a Contribution, Apache license notifications and license are retained * for attribution purposes only. * * 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 <math.h> #include "overlayUtils.h" #include "overlayRotator.h" #include "gr.h" namespace ovutils = overlay::utils; namespace overlay { MdpRot::MdpRot() { reset(); init(); } MdpRot::~MdpRot() { close(); } bool MdpRot::enabled() const { return mRotImgInfo.enable; } void MdpRot::setRotations(uint32_t r) { mRotImgInfo.rotations = (uint8_t)r; } int MdpRot::getSrcMemId() const { return mRotDataInfo.src.memory_id; } int MdpRot::getDstMemId() const { return mRotDataInfo.dst.memory_id; } uint32_t MdpRot::getSrcOffset() const { return mRotDataInfo.src.offset; } uint32_t MdpRot::getDstOffset() const { return mRotDataInfo.dst.offset; } uint32_t MdpRot::getDstFormat() const { return mRotImgInfo.dst.format; } //Added for completeness. Not expected to be called. utils::Whf MdpRot::getDstWhf() const { int alW = 0, alH = 0; int halFormat = ovutils::getHALFormat(mRotImgInfo.dst.format); getBufferSizeAndDimensions(mRotImgInfo.dst.width, mRotImgInfo.dst.height, halFormat, alW, alH); return utils::Whf(alW, alH, mRotImgInfo.dst.format); } //Added for completeness. Not expected to be called. utils::Dim MdpRot::getDstDimensions() const { int alW = 0, alH = 0; int halFormat = ovutils::getHALFormat(mRotImgInfo.dst.format); getBufferSizeAndDimensions(mRotImgInfo.dst.width, mRotImgInfo.dst.height, halFormat, alW, alH); return utils::Dim(0, 0, alW, alH); } uint32_t MdpRot::getSessId() const { return mRotImgInfo.session_id; } void MdpRot::setDownscale(int ds) { if ((utils::ROT_DS_EIGHTH == ds) && (mRotImgInfo.src_rect.h & 0xF)) { // Ensure src_rect.h is a multiple of 16 for 1/8 downscaling. // This is an undocumented MDP Rotator constraint. mRotImgInfo.src_rect.h = utils::aligndown(mRotImgInfo.src_rect.h, 16); } mRotImgInfo.downscale_ratio = ds; } void MdpRot::save() { mLSRotImgInfo = mRotImgInfo; } bool MdpRot::rotConfChanged() const { // 0 means same if(0 == ::memcmp(&mRotImgInfo, &mLSRotImgInfo, sizeof (msm_rotator_img_info))) { return false; } return true; } bool MdpRot::init() { if(!mFd.open(Res::rotPath, O_RDWR)){ ALOGE("MdpRot failed to init %s", Res::rotPath); return false; } return true; } void MdpRot::setSource(const overlay::utils::Whf& awhf) { utils::Whf whf(awhf); mRotImgInfo.src.format = whf.format; mRotImgInfo.src.width = whf.w; mRotImgInfo.src.height = whf.h; mRotImgInfo.src_rect.w = whf.w; mRotImgInfo.src_rect.h = whf.h; mRotImgInfo.dst.width = whf.w; mRotImgInfo.dst.height = whf.h; } void MdpRot::setCrop(const utils::Dim& /*crop*/) { // NO-OP for non-mdss rotator due to possible h/w limitations } void MdpRot::setFlags(const utils::eMdpFlags& flags) { mRotImgInfo.secure = 0; if(flags & utils::OV_MDP_SECURE_OVERLAY_SESSION) mRotImgInfo.secure = 1; } void MdpRot::setTransform(const utils::eTransform& rot) { int r = utils::getMdpOrient(rot); setRotations(r); mOrientation = static_cast<utils::eTransform>(r); ALOGE_IF(DEBUG_OVERLAY, "%s: r=%d", __FUNCTION__, r); } void MdpRot::doTransform() { if(mOrientation & utils::OVERLAY_TRANSFORM_ROT_90) utils::swap(mRotImgInfo.dst.width, mRotImgInfo.dst.height); } bool MdpRot::commit() { doTransform(); if(rotConfChanged()) { mRotImgInfo.enable = 1; if(!overlay::mdp_wrapper::startRotator(mFd.getFD(), mRotImgInfo)) { ALOGE("MdpRot commit failed"); dump(); mRotImgInfo.enable = 0; return false; } mRotDataInfo.session_id = mRotImgInfo.session_id; } return true; } uint32_t MdpRot::calcOutputBufSize() { ovutils::Whf destWhf(mRotImgInfo.dst.width, mRotImgInfo.dst.height, mRotImgInfo.dst.format); return Rotator::calcOutputBufSize(destWhf); } bool MdpRot::open_i(uint32_t numbufs, uint32_t bufsz) { OvMem mem; OVASSERT(MAP_FAILED == mem.addr(), "MAP failed in open_i"); if(!mem.open(numbufs, bufsz, mRotImgInfo.secure)){ ALOGE("%s: Failed to open", __func__); mem.close(); return false; } OVASSERT(MAP_FAILED != mem.addr(), "MAP failed"); OVASSERT(mem.getFD() != -1, "getFd is -1"); mRotDataInfo.dst.memory_id = mem.getFD(); mRotDataInfo.dst.offset = 0; mMem.mem = mem; return true; } bool MdpRot::close() { bool success = true; if(mFd.valid() && (getSessId() != 0)) { if(!mdp_wrapper::endRotator(mFd.getFD(), getSessId())) { ALOGE("Mdp Rot error endRotator, fd=%d sessId=%u", mFd.getFD(), getSessId()); success = false; } } if (!mFd.close()) { ALOGE("Mdp Rot error closing fd"); success = false; } if (!mMem.close()) { ALOGE("Mdp Rot error closing mem"); success = false; } reset(); return success; } bool MdpRot::remap(uint32_t numbufs) { // if current size changed, remap uint32_t opBufSize = calcOutputBufSize(); if(opBufSize == mMem.size()) { ALOGE_IF(DEBUG_OVERLAY, "%s: same size %d", __FUNCTION__, opBufSize); return true; } if(!mMem.close()) { ALOGE("%s error in closing prev rot mem", __FUNCTION__); return false; } ALOGE_IF(DEBUG_OVERLAY, "%s: size changed - remapping", __FUNCTION__); if(!open_i(numbufs, opBufSize)) { ALOGE("%s Error could not open", __FUNCTION__); return false; } for (uint32_t i = 0; i < numbufs; ++i) { mMem.mRotOffset[i] = i * opBufSize; } return true; } void MdpRot::reset() { ovutils::memset0(mRotImgInfo); ovutils::memset0(mLSRotImgInfo); ovutils::memset0(mRotDataInfo); ovutils::memset0(mMem.mRotOffset); mMem.mCurrIndex = 0; mOrientation = utils::OVERLAY_TRANSFORM_0; } bool MdpRot::queueBuffer(int fd, uint32_t offset) { if(enabled() and (not isRotCached(fd,offset))) { int prev_fd = getSrcMemId(); uint32_t prev_offset = getSrcOffset(); mRotDataInfo.src.memory_id = fd; mRotDataInfo.src.offset = offset; if(false == remap(RotMem::ROT_NUM_BUFS)) { ALOGE("%s Remap failed, not queueing", __FUNCTION__); return false; } mRotDataInfo.dst.offset = mMem.mRotOffset[mMem.mCurrIndex]; if(!overlay::mdp_wrapper::rotate(mFd.getFD(), mRotDataInfo)) { ALOGE("MdpRot failed rotate"); dump(); mRotDataInfo.src.memory_id = prev_fd; mRotDataInfo.src.offset = prev_offset; return false; } save(); mMem.mCurrIndex = (mMem.mCurrIndex + 1) % mMem.mem.numBufs(); } return true; } void MdpRot::dump() const { ALOGE("== Dump MdpRot start =="); mFd.dump(); mMem.mem.dump(); mdp_wrapper::dump("mRotImgInfo", mRotImgInfo); mdp_wrapper::dump("mRotDataInfo", mRotDataInfo); ALOGE("== Dump MdpRot end =="); } void MdpRot::getDump(char *buf, size_t len) const { ovutils::getDump(buf, len, "MdpRotCtrl", mRotImgInfo); ovutils::getDump(buf, len, "MdpRotData", mRotDataInfo); } int MdpRot::getDownscaleFactor(const int& src_w, const int& src_h, const int& dst_w, const int& dst_h, const uint32_t& /*mdpFormat*/, const bool& /*isInterlaced*/) { int dscale_factor = utils::ROT_DS_NONE; // We need this check to engage the rotator whenever possible to assist MDP // in performing video downscale. // This saves bandwidth and avoids causing the driver to make too many panel // -mode switches between BLT (writeback) and non-BLT (Direct) modes. // Use-case: Video playback [with downscaling and rotation]. if (dst_w && dst_h) { float fDscale = (float)(src_w * src_h) / (float)(dst_w * dst_h); uint32_t dscale = (int)sqrtf(fDscale); if(dscale < 2) { // Down-scale to > 50% of orig. dscale_factor = utils::ROT_DS_NONE; } else if(dscale < 4) { // Down-scale to between > 25% to <= 50% of orig. dscale_factor = utils::ROT_DS_HALF; } else if(dscale < 8) { // Down-scale to between > 12.5% to <= 25% of orig. dscale_factor = utils::ROT_DS_FOURTH; } else { // Down-scale to <= 12.5% of orig. dscale_factor = utils::ROT_DS_EIGHTH; } } return dscale_factor; } } // namespace overlay