/* * Copyright (c) 2011-2014, The Linux Foundation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of The Linux Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER 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. */ #include #include "overlay.h" #include "pipes/overlayGenPipe.h" #include "mdp_version.h" #include "qdMetaData.h" #include "qd_utils.h" namespace overlay { using namespace utils; using namespace qdutils; Overlay::Overlay() { int numPipes = qdutils::MDPVersion::getInstance().getTotalPipes(); PipeBook::NUM_PIPES = (numPipes <= utils::OV_MAX)? numPipes : utils::OV_MAX; for(int i = 0; i < PipeBook::NUM_PIPES; i++) { mPipeBook[i].init(); } initScalar(); setDMAMultiplexingSupported(); #ifdef USES_POST_PROCESSING initPostProc(); #endif } Overlay::~Overlay() { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { mPipeBook[i].destroy(); } destroyScalar(); #ifdef USES_POST_PROCESSING destroyPostProc(); #endif } void Overlay::configBegin() { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { //Mark as available for this round. PipeBook::resetUse(i); PipeBook::resetAllocation(i); } } void Overlay::configDone() { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if((PipeBook::isNotUsed(i) && !sessionInProgress((eDest)i)) || isSessionEnded((eDest)i)) { //Forces UNSET on pipes, flushes rotator memory and session, closes //fds mPipeBook[i].destroy(); } } PipeBook::save(); } int Overlay::getPipeId(utils::eDest dest) { return mPipeBook[(int)dest].mPipe->getPipeId(); } eDest Overlay::getDest(int pipeid) { eDest dest = OV_INVALID; // finding the dest corresponding to the given pipe for(int i=0; i < PipeBook::NUM_PIPES; ++i) { if(mPipeBook[i].valid() && mPipeBook[i].mPipe->getPipeId() == pipeid) { return (eDest)i; } } return dest; } eDest Overlay::reservePipe(int pipeid) { eDest dest = getDest(pipeid); PipeBook::setAllocation((int)dest); return dest; } eDest Overlay::nextPipe(eMdpPipeType type, const PipeSpecs& pipeSpecs) { eDest dest = OV_INVALID; int dpy = pipeSpecs.dpy; int mixer = pipeSpecs.mixer; int formatType = pipeSpecs.formatClass; for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if( (type == OV_MDP_PIPE_ANY || //Pipe type match type == PipeBook::getPipeType((eDest)i)) && (mPipeBook[i].mDisplay == DPY_UNUSED || //Free or same display mPipeBook[i].mDisplay == dpy) && (mPipeBook[i].mMixer == MIXER_UNUSED || //Free or same mixer mPipeBook[i].mMixer == mixer) && (mPipeBook[i].mFormatType == FORMAT_NONE || //Free or same format mPipeBook[i].mFormatType == formatType) && PipeBook::isNotAllocated(i) && //Free pipe ( (sDMAMultiplexingSupported && dpy) || !(sDMAMode == DMA_BLOCK_MODE && //DMA pipe in Line mode PipeBook::getPipeType((eDest)i) == OV_MDP_PIPE_DMA)) ){ //DMA-Multiplexing is only supported for WB on 8x26 dest = (eDest)i; PipeBook::setAllocation(i); break; } } if(dest != OV_INVALID) { int index = (int)dest; mPipeBook[index].mDisplay = dpy; mPipeBook[index].mMixer = mixer; mPipeBook[index].mFormatType = formatType; if(not mPipeBook[index].valid()) { mPipeBook[index].mPipe = new GenericPipe(dpy); mPipeBook[index].mSession = PipeBook::NONE; } } return dest; } utils::eDest Overlay::getPipe(const PipeSpecs& pipeSpecs) { if(MDPVersion::getInstance().is8x26()) { return getPipe_8x26(pipeSpecs); } else if(MDPVersion::getInstance().is8x16()) { return getPipe_8x16(pipeSpecs); } else if(MDPVersion::getInstance().is8x39()) { return getPipe_8x39(pipeSpecs); } else if(MDPVersion::getInstance().is8994()) { return getPipe_8994(pipeSpecs); } eDest dest = OV_INVALID; //The default behavior is to assume RGB and VG pipes have scalars if(pipeSpecs.formatClass == FORMAT_YUV) { return nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } else if(pipeSpecs.fb == false) { //RGB App layers if(not pipeSpecs.needsScaling) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); } if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } } else { //FB layer dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } //Some features can cause FB to have scaling as well. //If we ever come to this block with FB needing scaling, //the screen will be black for a frame, since the FB won't get a pipe //but atleast this will prevent a hang if(dest == OV_INVALID and (not pipeSpecs.needsScaling)) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } } return dest; } utils::eDest Overlay::getPipe_8x26(const PipeSpecs& pipeSpecs) { //Use this to hide all the 8x26 requirements that cannot be humanly //described in a generic way eDest dest = OV_INVALID; if(pipeSpecs.formatClass == FORMAT_YUV) { //video return nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } else if(pipeSpecs.fb == false) { //RGB app layers if((not pipeSpecs.needsScaling) and (not (pipeSpecs.numActiveDisplays > 1 && pipeSpecs.dpy == DPY_PRIMARY))) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); } if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } } else { //FB layer //For 8x26 Secondary we use DMA always for FB for inline rotation if(pipeSpecs.dpy == DPY_PRIMARY) { dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } } if(dest == OV_INVALID and (not pipeSpecs.needsScaling) and (not (pipeSpecs.numActiveDisplays > 1 && pipeSpecs.dpy == DPY_PRIMARY))) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } } return dest; } utils::eDest Overlay::getPipe_8x16(const PipeSpecs& pipeSpecs) { //Having such functions help keeping the interface generic but code specific //and rife with assumptions eDest dest = OV_INVALID; if(pipeSpecs.formatClass == FORMAT_YUV or pipeSpecs.needsScaling) { return nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } else { //Since this is a specific func, we can assume stuff like RGB pipe not //having scalar blocks dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } } return dest; } utils::eDest Overlay::getPipe_8x39(const PipeSpecs& pipeSpecs) { //8x16 & 8x36 has same number of pipes, pipe-types & scaling capabilities. //Rely on 8x16 until we see a need to change. return getPipe_8x16(pipeSpecs); } utils::eDest Overlay::getPipe_8994(const PipeSpecs& pipeSpecs) { //If DMA pipes need to be used in block mode for downscale, there could be //cases where consecutive rounds need separate modes, which cannot be //supported since we at least need 1 round in between where the DMA is //unused eDest dest = OV_INVALID; if(pipeSpecs.formatClass == FORMAT_YUV) { return nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } else { dest = nextPipe(OV_MDP_PIPE_RGB, pipeSpecs); if(dest == OV_INVALID) { dest = nextPipe(OV_MDP_PIPE_VG, pipeSpecs); } if(dest == OV_INVALID and not pipeSpecs.needsScaling) { dest = nextPipe(OV_MDP_PIPE_DMA, pipeSpecs); } } return dest; } void Overlay::endAllSessions() { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if(mPipeBook[i].valid() && mPipeBook[i].mSession==PipeBook::START) mPipeBook[i].mSession = PipeBook::END; } } bool Overlay::isPipeTypeAttached(eMdpPipeType type) { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if(type == PipeBook::getPipeType((eDest)i) && mPipeBook[i].mDisplay != DPY_UNUSED) { return true; } } return false; } bool Overlay::needsPrioritySwap(utils::eDest pipe1Index, utils::eDest pipe2Index) { validate((int)pipe1Index); validate((int)pipe2Index); uint8_t pipe1Prio = mPipeBook[(int)pipe1Index].mPipe->getPriority(); uint8_t pipe2Prio = mPipeBook[(int)pipe2Index].mPipe->getPriority(); int pipe1Id = mPipeBook[(int)pipe1Index].mPipe->getPipeId(); int pipe2Id = mPipeBook[(int)pipe2Index].mPipe->getPipeId(); utils::eMdpPipeType leftType = PipeBook::getPipeType(pipe1Index); utils::eMdpPipeType rightType = PipeBook::getPipeType(pipe2Index); if(pipe1Id >=0 && pipe2Id >=0) { // LEFT priority should be higher then RIGHT return (pipe1Prio > pipe2Prio); } else if(pipe1Id < 0 && pipe2Id < 0) { // If we are here, Source Split is enabled and both pipes are // new requests. In this case left type should be of higher prio // than right type if(leftType == rightType) { //Safe. Onus on driver to assign correct pipes within same type return false; } else { //This check takes advantage of having only 3 types and avoids 3 //different failure combination checks. // Swap IF: // ---------------- // | Left | Right | // ================ // | DMA | ViG | // ---------------- // | DMA | RGB | // ---------------- // | RGB | ViG | // ---------------- return (leftType == OV_MDP_PIPE_DMA or rightType == OV_MDP_PIPE_VG); } } else if(pipe1Id < 0) { //LEFT needs new allocation. if(leftType == rightType) { // If RIGHT has highest priority(lowest id), swap it. return (pipe2Id == PipeBook::pipeMinID[leftType]); } else { return (leftType == OV_MDP_PIPE_DMA or rightType == OV_MDP_PIPE_VG); } } else { /* if (pipe2Id < 0) */ // RIGHT needs new allocation. if(leftType == rightType) { // If LEFT has lowest priority(highest id), swap it. return (pipe1Id == PipeBook::pipeMaxID[leftType]); } else { return (leftType == OV_MDP_PIPE_DMA or rightType == OV_MDP_PIPE_VG); } } } bool Overlay::commit(utils::eDest dest) { bool ret = false; validate((int)dest); if(mPipeBook[dest].mPipe->commit()) { ret = true; PipeBook::setUse((int)dest); } else { clear(mPipeBook[dest].mDisplay); } return ret; } bool Overlay::queueBuffer(int fd, uint32_t offset, utils::eDest dest) { bool ret = false; validate((int)dest); //Queue only if commit() has succeeded (and the bit set) if(PipeBook::isUsed((int)dest)) { ret = mPipeBook[dest].mPipe->queueBuffer(fd, offset); } return ret; } void Overlay::setCrop(const utils::Dim& d, utils::eDest dest) { validate((int)dest); mPipeBook[dest].mPipe->setCrop(d); } void Overlay::setColor(const uint32_t color, utils::eDest dest) { validate((int)dest); mPipeBook[dest].mPipe->setColor(color); } void Overlay::setPosition(const utils::Dim& d, utils::eDest dest) { validate((int)dest); mPipeBook[dest].mPipe->setPosition(d); } void Overlay::setTransform(const int orient, utils::eDest dest) { validate((int)dest); utils::eTransform transform = static_cast(orient); mPipeBook[dest].mPipe->setTransform(transform); } void Overlay::setSource(const utils::PipeArgs args, utils::eDest dest) { validate((int)dest); setPipeType(dest, PipeBook::getPipeType(dest)); mPipeBook[dest].mPipe->setSource(args); } void Overlay::setVisualParams(const MetaData_t& metadata, utils::eDest dest) { validate((int)dest); mPipeBook[dest].mPipe->setVisualParams(metadata); } void Overlay::setPipeType(utils::eDest pipeIndex, const utils::eMdpPipeType pType) { mPipeBook[pipeIndex].mPipe->setPipeType(pType); } Overlay* Overlay::getInstance() { if(sInstance == NULL) { sInstance = new Overlay(); } return sInstance; } // Clears any VG pipes allocated to the fb devices // Generates a LUT for pipe types. int Overlay::initOverlay() { int mdpVersion = qdutils::MDPVersion::getInstance().getMDPVersion(); int numPipesXType[OV_MDP_PIPE_ANY] = {0}; numPipesXType[OV_MDP_PIPE_RGB] = qdutils::MDPVersion::getInstance().getRGBPipes(); numPipesXType[OV_MDP_PIPE_VG] = qdutils::MDPVersion::getInstance().getVGPipes(); numPipesXType[OV_MDP_PIPE_DMA] = qdutils::MDPVersion::getInstance().getDMAPipes(); int index = 0; for(int X = 0; X < (int)OV_MDP_PIPE_ANY; X++) { //iterate over types for(int j = 0; j < numPipesXType[X]; j++) { //iterate over num PipeBook::pipeTypeLUT[index] = (utils::eMdpPipeType)X; index++; } } PipeBook::pipeMinID[OV_MDP_PIPE_RGB] = 8; PipeBook::pipeMaxID[OV_MDP_PIPE_RGB] = (numPipesXType[OV_MDP_PIPE_RGB] == 3)? 32 : 512; PipeBook::pipeMinID[OV_MDP_PIPE_VG] = 1; PipeBook::pipeMaxID[OV_MDP_PIPE_VG] = (numPipesXType[OV_MDP_PIPE_VG] == 3)? 4 : 256; PipeBook::pipeMinID[OV_MDP_PIPE_DMA] = 64; PipeBook::pipeMaxID[OV_MDP_PIPE_DMA] = 128; FILE *displayDeviceFP = NULL; char fbType[MAX_FRAME_BUFFER_NAME_SIZE]; char msmFbTypePath[MAX_FRAME_BUFFER_NAME_SIZE]; const char *strDtvPanel = "dtv panel"; const char *strWbPanel = "writeback panel"; for(int num = 1; num < MAX_FB_DEVICES; num++) { snprintf (msmFbTypePath, sizeof(msmFbTypePath), "/sys/class/graphics/fb%d/msm_fb_type", num); displayDeviceFP = fopen(msmFbTypePath, "r"); if(displayDeviceFP){ fread(fbType, sizeof(char), MAX_FRAME_BUFFER_NAME_SIZE, displayDeviceFP); if(strncmp(fbType, strDtvPanel, strlen(strDtvPanel)) == 0) { sDpyFbMap[DPY_EXTERNAL] = num; } else if(strncmp(fbType, strWbPanel, strlen(strWbPanel)) == 0) { sDpyFbMap[DPY_WRITEBACK] = num; } fclose(displayDeviceFP); } } return 0; } bool Overlay::displayCommit(const int& fd) { utils::Dim lRoi, rRoi; return displayCommit(fd, lRoi, rRoi); } bool Overlay::displayCommit(const int& fd, const utils::Dim& lRoi, const utils::Dim& rRoi) { //Commit struct mdp_display_commit info; memset(&info, 0, sizeof(struct mdp_display_commit)); info.flags = MDP_DISPLAY_COMMIT_OVERLAY; info.l_roi.x = lRoi.x; info.l_roi.y = lRoi.y; info.l_roi.w = lRoi.w; info.l_roi.h = lRoi.h; info.r_roi.x = rRoi.x; info.r_roi.y = rRoi.y; info.r_roi.w = rRoi.w; info.r_roi.h = rRoi.h; if(!mdp_wrapper::displayCommit(fd, info)) { ALOGE("%s: commit failed", __func__); return false; } return true; } void Overlay::getDump(char *buf, size_t len) { int totalPipes = 0; const char *str = "\nOverlay State\n\n"; strlcat(buf, str, len); for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if(mPipeBook[i].valid()) { mPipeBook[i].mPipe->getDump(buf, len); char str[64] = {'\0'}; snprintf(str, 64, "Display=%d\n\n", mPipeBook[i].mDisplay); strlcat(buf, str, len); totalPipes++; } } char str_pipes[64] = {'\0'}; snprintf(str_pipes, 64, "Pipes=%d\n\n", totalPipes); strlcat(buf, str_pipes, len); } void Overlay::clear(int dpy) { for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if (mPipeBook[i].mDisplay == dpy) { // Mark as available for this round PipeBook::resetUse(i); PipeBook::resetAllocation(i); if(getPipeId((utils::eDest)i) == -1) { mPipeBook[i].destroy(); } } } } bool Overlay::validateAndSet(const int& dpy, const int& fbFd) { GenericPipe* pipeArray[PipeBook::NUM_PIPES]; memset(pipeArray, 0, sizeof(GenericPipe*)*(PipeBook::NUM_PIPES)); int num = 0; for(int i = 0; i < PipeBook::NUM_PIPES; i++) { if(PipeBook::isUsed(i) && mPipeBook[i].valid() && mPipeBook[i].mDisplay == dpy) { pipeArray[num++] = mPipeBook[i].mPipe; } } //Protect against misbehaving clients return num ? GenericPipe::validateAndSet(pipeArray, num, fbFd) : true; } void Overlay::initScalar() { if(sLibScaleHandle == NULL) { sLibScaleHandle = dlopen("libscale.so", RTLD_NOW); if(sLibScaleHandle) { *(void **) &sFnProgramScale = dlsym(sLibScaleHandle, "programScale"); } } } void Overlay::destroyScalar() { if(sLibScaleHandle) { dlclose(sLibScaleHandle); sLibScaleHandle = NULL; } } void Overlay::initPostProc() { sLibAblHandle = dlopen("libmm-abl.so", RTLD_NOW); if (sLibAblHandle) { *(void **)&sFnppParams = dlsym(sLibAblHandle, "display_pp_compute_params"); } else { ALOGE("%s: Not able to load libmm-abl.so", __FUNCTION__); } } void Overlay::destroyPostProc() { if (sLibAblHandle) { dlclose(sLibAblHandle); sLibAblHandle = NULL; } } void Overlay::PipeBook::init() { mPipe = NULL; mDisplay = DPY_UNUSED; mMixer = MIXER_UNUSED; mFormatType = FORMAT_NONE; } void Overlay::PipeBook::destroy() { if(mPipe) { delete mPipe; mPipe = NULL; } mDisplay = DPY_UNUSED; mMixer = MIXER_UNUSED; mFormatType = FORMAT_NONE; mSession = NONE; } Overlay* Overlay::sInstance = 0; int Overlay::sDpyFbMap[DPY_MAX] = {0, -1, -1}; int Overlay::sDMAMode = DMA_LINE_MODE; bool Overlay::sDMAMultiplexingSupported = false; bool Overlay::sDebugPipeLifecycle = false; int Overlay::PipeBook::NUM_PIPES = 0; int Overlay::PipeBook::sPipeUsageBitmap = 0; int Overlay::PipeBook::sLastUsageBitmap = 0; int Overlay::PipeBook::sAllocatedBitmap = 0; utils::eMdpPipeType Overlay::PipeBook::pipeTypeLUT[utils::OV_MAX] = {utils::OV_MDP_PIPE_ANY}; int Overlay::PipeBook::pipeMinID[utils::OV_MDP_PIPE_ANY] = {0}; int Overlay::PipeBook::pipeMaxID[utils::OV_MDP_PIPE_ANY] = {0}; void *Overlay::sLibScaleHandle = NULL; int (*Overlay::sFnProgramScale)(struct mdp_overlay_list *) = NULL; /* Dynamically link ABL library */ void *Overlay::sLibAblHandle = NULL; int (*Overlay::sFnppParams)(const struct compute_params *, struct mdp_overlay_pp_params *) = NULL; }; // namespace overlay