/* * Copyright (c) 2019 Rockchip Corporation * * 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 "RkAiqManager.h" #include "isp20/Isp20_module_dbg.h" #include "isp20/CamHwIsp20.h" #include "isp21/CamHwIsp21.h" #include #include using namespace XCam; namespace RkCam { #define RKAIQMNG_CHECK_RET(ret, format, ...) \ if (ret) { \ LOGE(format, ##__VA_ARGS__); \ return ret; \ } bool RkAiqMngCmdThread::loop () { ENTER_XCORE_FUNCTION(); const static int32_t timeout = -1; XCamReturn ret = XCAM_RETURN_NO_ERROR; SmartPtr msg = mAiqCmdQueue.pop (timeout); if (!msg.ptr()) { XCAM_LOG_WARNING("RkAiqMngCmdThread got empty result, stop thread"); return false; } XCAM_ASSERT (mAiqMng); switch (msg->cmd) { case MSG_CMD_SW_WORKING_MODE: if (msg->sync) msg->mutex->lock(); mAiqMng->swWorkingModeDyn(msg->data.sw_wk_mode.mode); mAiqMng->mWkSwitching = false; if (msg->sync) { msg->cond->broadcast (); msg->mutex->unlock(); } break; default: break; } // always true return true; } bool RkAiqRstApplyThread::loop () { ENTER_XCORE_FUNCTION(); const static int32_t timeout = -1; XCamReturn ret = XCAM_RETURN_NO_ERROR; SmartPtr results = mAiqRstQueue.pop (timeout); XCAM_ASSERT (mAiqMng); if (!results.ptr()) { XCAM_LOG_WARNING("RkAiqRstApplyThread got empty result, stop thread"); return false; } #ifdef RUNTIME_MODULE_DEBUG #ifndef RK_SIMULATOR_HW if (g_apply_init_params_only) goto out; #endif #endif ret = mAiqMng->applyAnalyzerResult(results); if (ret == XCAM_RETURN_NO_ERROR) return true; EXIT_XCORE_FUNCTION(); out: // always true return true; } RkAiqManager::RkAiqManager(const char* sns_ent_name, rk_aiq_error_cb err_cb, rk_aiq_metas_cb metas_cb) : mCamHw(NULL) , mRkAiqAnalyzer(NULL) , mRkLumaAnalyzer(NULL) , mAiqRstAppTh(new RkAiqRstApplyThread(this)) , mAiqMngCmdTh(new RkAiqMngCmdThread(this)) , mErrCb(err_cb) , mMetasCb(metas_cb) , mSnsEntName(sns_ent_name) , mWorkingMode(RK_AIQ_WORKING_MODE_NORMAL) , mOldWkModeForGray(RK_AIQ_WORKING_MODE_NORMAL) , mWkSwitching(false) , mCalibDb(NULL) , mCalibDbV2(NULL) , _state(AIQ_STATE_INVALID) , mCurMirror(false) , mCurFlip(false) { ENTER_XCORE_FUNCTION(); EXIT_XCORE_FUNCTION(); } RkAiqManager::~RkAiqManager() { ENTER_XCORE_FUNCTION(); EXIT_XCORE_FUNCTION(); } void RkAiqManager::setCamHw(SmartPtr& camhw) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (!mCamHw.ptr()); mCamHw = camhw; EXIT_XCORE_FUNCTION(); } void RkAiqManager::setAnalyzer(SmartPtr analyzer) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (!mRkAiqAnalyzer.ptr()); mRkAiqAnalyzer = analyzer; EXIT_XCORE_FUNCTION(); } void RkAiqManager::setLumaAnalyzer(SmartPtr analyzer) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (!mRkLumaAnalyzer.ptr()); mRkLumaAnalyzer = analyzer; EXIT_XCORE_FUNCTION(); } void RkAiqManager::setAiqCalibDb(const CamCalibDbContext_t* calibDb) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (!mCalibDb); mCalibDb = calibDb; EXIT_XCORE_FUNCTION(); } void RkAiqManager::setAiqCalibDb(const CamCalibDbV2Context_t* calibDb) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (!mCalibDbV2); mCalibDbV2 = new CamCalibDbV2Context_t(); *mCalibDbV2 = *calibDb; EXIT_XCORE_FUNCTION(); } XCamReturn RkAiqManager::init() { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; XCAM_ASSERT (mSnsEntName); XCAM_ASSERT (mRkAiqAnalyzer.ptr()); XCAM_ASSERT (mCamHw.ptr()); XCAM_ASSERT (mCalibDbV2); mRkAiqAnalyzer->setAnalyzeResultCb(this); // set hw infos struct RkAiqHwInfo hw_info; xcam_mem_clear(hw_info); #ifndef RK_SIMULATOR_HW rk_aiq_static_info_t* s_info = CamHwIsp20::getStaticCamHwInfo(mSnsEntName); hw_info.fl_supported = s_info->has_fl; hw_info.irc_supported = s_info->has_irc; hw_info.lens_supported = s_info->has_lens_vcm; hw_info.fl_strth_adj = s_info->fl_strth_adj_sup; hw_info.fl_ir_strth_adj = s_info->fl_ir_strth_adj_sup; mIspHwVer = s_info->isp_hw_ver; #endif mRkAiqAnalyzer->setHwInfos(hw_info); ret = mRkAiqAnalyzer->init(mSnsEntName, mCalibDb, mCalibDbV2); RKAIQMNG_CHECK_RET(ret, "analyzer init error %d !", ret); mRkLumaAnalyzer->setAnalyzeResultCb(this); CalibDbV2_LUMA_DETECT_t *lumaDetect = (CalibDbV2_LUMA_DETECT_t*)(CALIBDBV2_GET_MODULE_PTR((void*)mCalibDbV2, lumaDetect)); ret = mRkLumaAnalyzer->init(lumaDetect); RKAIQMNG_CHECK_RET(ret, "luma analyzer init error %d !", ret); mCamHw->setHwResListener(this); ret = mCamHw->init(mSnsEntName); RKAIQMNG_CHECK_RET(ret, "camHw init error %d !", ret); _state = AIQ_STATE_INITED; isp_drv_share_mem_ops_t *mem_ops = NULL; mCamHw->getShareMemOps(&mem_ops); mRkAiqAnalyzer->setShareMemOps(mem_ops); // set default mirror & flip setDefMirrorFlip(); mAiqMngCmdTh->triger_start(); bool bret = mAiqMngCmdTh->start(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "cmd thread start error"); mDleayCpslParams = NULL; EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::prepare(uint32_t width, uint32_t height, rk_aiq_working_mode_t mode) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; rk_aiq_exposure_sensor_descriptor sensor_des; XCAM_ASSERT (mCalibDbV2); #ifdef RUNTIME_MODULE_DEBUG #ifndef RK_SIMULATOR_HW get_dbg_force_disable_mods_env(); #endif #endif int working_mode_hw = RK_AIQ_WORKING_MODE_NORMAL; if (mode == RK_AIQ_WORKING_MODE_NORMAL) { working_mode_hw = mode; } else { // depreate mCalibDb->sysContrl.hdr_mode /* if (mode != RK_AIQ_HDR_GET_WORKING_MODE(mCalibDb->sysContrl.hdr_mode)) { */ /* ret = XCAM_RETURN_ERROR_PARAM; */ /* RKAIQMNG_CHECK_RET(ret, "Not supported HDR mode!"); */ /* } else { */ /* working_mode_hw = mCalibDb->sysContrl.hdr_mode; */ /* } */ if (mode == RK_AIQ_WORKING_MODE_ISP_HDR2) working_mode_hw = RK_AIQ_ISP_HDR_MODE_2_FRAME_HDR; else if (mode == RK_AIQ_WORKING_MODE_ISP_HDR3) working_mode_hw = RK_AIQ_ISP_HDR_MODE_3_FRAME_HDR; else LOGE_ANALYZER("Not supported HDR mode !"); } mCamHw->setCalib(mCalibDbV2); CalibDb_Sensor_ParaV2_t* sensor_calib = (CalibDb_Sensor_ParaV2_t*)(CALIBDBV2_GET_MODULE_PTR(mCalibDbV2, sensor_calib)); if(mode != RK_AIQ_WORKING_MODE_NORMAL) ret = mCamHw->prepare(width, height, working_mode_hw, sensor_calib->CISExpUpdate.Hdr.time_update, sensor_calib->CISExpUpdate.Hdr.gain_update); else ret = mCamHw->prepare(width, height, working_mode_hw, sensor_calib->CISExpUpdate.Linear.time_update, sensor_calib->CISExpUpdate.Linear.gain_update); RKAIQMNG_CHECK_RET(ret, "camhw prepare error %d", ret); xcam_mem_clear(sensor_des); ret = mCamHw->getSensorModeData(mSnsEntName, sensor_des); int w,h,aligned_w,aligned_h; ret = mCamHw->get_sp_resolution(w, h, aligned_w, aligned_h); ret = mRkAiqAnalyzer->set_sp_resolution(w, h, aligned_w, aligned_h); ret = mRkLumaAnalyzer->prepare(working_mode_hw); RKAIQMNG_CHECK_RET(ret, "getSensorModeData error %d", ret); mRkAiqAnalyzer->notifyIspStreamMode(mCamHw->getIspStreamMode()); ret = mRkAiqAnalyzer->prepare(&sensor_des, working_mode_hw); RKAIQMNG_CHECK_RET(ret, "analyzer prepare error %d", ret); SmartPtr initParams = mRkAiqAnalyzer->getAiqFullParams(); ret = applyAnalyzerResult(initParams); RKAIQMNG_CHECK_RET(ret, "set initial params error %d", ret); mWorkingMode = mode; mOldWkModeForGray = RK_AIQ_WORKING_MODE_NORMAL; mWidth = width; mHeight = height; _state = AIQ_STATE_PREPARED; EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::start() { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; // restart if (_state == AIQ_STATE_STOPED) { SmartPtr initParams = mRkAiqAnalyzer->getAiqFullParams(); #if 0 if (initParams->data()->mIspMeasParams.ptr()) { initParams->data()->mIspMeasParams->data()->frame_id = 0; } if (initParams->data()->mIsppMeasParams.ptr()) { initParams->data()->mIsppMeasParams->data()->frame_id = 0; } #endif applyAnalyzerResult(initParams); } mAiqRstAppTh->triger_start(); bool bret = mAiqRstAppTh->start(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread start error"); ret = mRkAiqAnalyzer->start(); RKAIQMNG_CHECK_RET(ret, "analyzer start error %d", ret); ret = mRkLumaAnalyzer->start(); RKAIQMNG_CHECK_RET(ret, "luma analyzer start error %d", ret); ret = mCamHw->start(); RKAIQMNG_CHECK_RET(ret, "camhw start error %d", ret); _state = AIQ_STATE_STARTED; EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::stop(bool keep_ext_hw_st) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; if (_state == AIQ_STATE_STOPED) { return ret; } mAiqRstAppTh->triger_stop(); bool bret = mAiqRstAppTh->stop(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread stop error"); ret = mRkAiqAnalyzer->stop(); RKAIQMNG_CHECK_RET(ret, "analyzer stop error %d", ret); ret = mRkLumaAnalyzer->stop(); RKAIQMNG_CHECK_RET(ret, "luma analyzer stop error %d", ret); mCamHw->keepHwStAtStop(keep_ext_hw_st); ret = mCamHw->stop(); RKAIQMNG_CHECK_RET(ret, "camhw stop error %d", ret); mDleayCpslParams = NULL; _state = AIQ_STATE_STOPED; EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::deInit() { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; mAiqMngCmdTh->triger_stop(); bool bret = mAiqMngCmdTh->stop(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "cmd thread stop error"); ret = mRkAiqAnalyzer->deInit(); RKAIQMNG_CHECK_RET(ret, "analyzer deinit error %d", ret); ret = mRkLumaAnalyzer->deInit(); RKAIQMNG_CHECK_RET(ret, "luma analyzer deinit error %d", ret); ret = mCamHw->deInit(); RKAIQMNG_CHECK_RET(ret, "camhw deinit error %d", ret); if (mCalibDbV2) { delete mCalibDbV2; mCalibDbV2 = NULL; } _state = AIQ_STATE_INVALID; EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::updateCalibDb(const CamCalibDbV2Context_t* newCalibDb) { XCamReturn ret = XCAM_RETURN_NO_ERROR; SmartPtr initParams; if (_state != AIQ_STATE_STARTED) { LOGW_ANALYZER("should be called at STARTED state"); return ret; } mAiqRstAppTh->triger_stop(); bool bret = mAiqRstAppTh->stop(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread stop error"); ret = mRkAiqAnalyzer->stop(); RKAIQMNG_CHECK_RET(ret, "analyzer stop error %d", ret); //ret = mRkLumaAnalyzer->stop(); //RKAIQMNG_CHECK_RET(ret, "luma analyzer stop error %d", ret); // ret = mRkAiqAnalyzer->deInit(); //ret = mRkLumaAnalyzer->deInit(); *mCalibDbV2 = *newCalibDb; CalibDbV2_LUMA_DETECT_t *lumaDetect = (CalibDbV2_LUMA_DETECT_t*)(CALIBDBV2_GET_MODULE_PTR((void*)mCalibDbV2, lumaDetect)); ret = mRkAiqAnalyzer->setCalib(mCalibDbV2); //ret = mRkLumaAnalyzer->init(lumaDetect); // 3. re-prepare analyzer LOGI_ANALYZER("reprepare analyzer ..."); rk_aiq_exposure_sensor_descriptor sensor_des; ret = mCamHw->getSensorModeData(mSnsEntName, sensor_des); int working_mode_hw = RK_AIQ_WORKING_MODE_NORMAL; if (mWorkingMode == RK_AIQ_WORKING_MODE_ISP_HDR2) working_mode_hw = RK_AIQ_ISP_HDR_MODE_2_FRAME_HDR; else if (mWorkingMode == RK_AIQ_WORKING_MODE_ISP_HDR3) working_mode_hw = RK_AIQ_ISP_HDR_MODE_2_FRAME_HDR; mRkAiqAnalyzer->notifyIspStreamMode(mCamHw->getIspStreamMode()); ret = mRkAiqAnalyzer->prepare(&sensor_des, working_mode_hw); RKAIQMNG_CHECK_RET(ret, "analyzer prepare error %d", ret); // update calib to hw mCamHw->setCalib(mCalibDbV2); initParams = mRkAiqAnalyzer->getAiqFullParams(); ret = applyAnalyzerResult(initParams); RKAIQMNG_CHECK_RET(ret, "set initial params error %d", ret); // 4. restart analyzer LOGI_ANALYZER("restart analyzer"); mAiqRstAppTh->triger_start(); bret = mAiqRstAppTh->start(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread start error"); ret = mRkAiqAnalyzer->start(); RKAIQMNG_CHECK_RET(ret, "analyzer start error %d", ret); //ret = mRkLumaAnalyzer->start(); //RKAIQMNG_CHECK_RET(ret, "luma analyzer start error %d", ret); EXIT_XCORE_FUNCTION(); return XCAM_RETURN_NO_ERROR; } XCamReturn RkAiqManager::hwResCb(SmartPtr& hwres) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; if (hwres->_buf_type == ISP_POLL_3A_STATS) { ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_POLL_LUMA) { ret = mRkLumaAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_POLL_PARAMS) { } else if (hwres->_buf_type == ISPP_POLL_NR_STATS) { ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_POLL_SOF){ xcam_get_runtime_log_level(); SmartPtr mCamHwIsp20 = mCamHw.dynamic_cast_ptr(); mCamHwIsp20->notify_sof(hwres); SmartPtr evtbuf = hwres.dynamic_cast_ptr(); SmartPtr evtdata = evtbuf->get_data(); SmartPtr hw_evt = mCamHwIsp20->make_ispHwEvt(evtdata->_frameid, V4L2_EVENT_FRAME_SYNC, evtdata->_timestamp); mRkAiqAnalyzer->pushEvts(hw_evt); // TODO: moved to aiq core ? if (mMetasCb) { rk_aiq_metas_t metas; metas.frame_id = evtdata->_frameid; (*mMetasCb)(&metas); } } else if (hwres->_buf_type == ISP_POLL_TX) { #if 0 XCamVideoBuffer* camVBuf = convert_to_XCamVideoBuffer(hwres); LOGD_ANALYZER("raw: \n format: 0x%x\n color_bits: %d\n width: %d\n height: %d\n aligned_width: %d\naligned_height: %d\n" "size: %d\n components: %d\n strides[0]: %d\n strides[1]: %d\n offset[0]: %d\n offset[1]: %d\n", camVBuf->info.format, camVBuf->info.color_bits, camVBuf->info.width, camVBuf->info.height, camVBuf->info.aligned_width, camVBuf->info.aligned_height, camVBuf->info.size, camVBuf->info.components, camVBuf->info.strides[0], camVBuf->info.strides[1], camVBuf->info.offsets[0], camVBuf->info.offsets[1]); camVBuf->unref(camVBuf); #endif ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_POLL_SP) { #if 0 XCamVideoBuffer* camVBuf = convert_to_XCamVideoBuffer(hwres); LOGD_ANALYZER("spimg: frameid:%d \n format: 0x%x\n color_bits: %d\n width: %d\n height: %d\n aligned_width: %d\naligned_height: %d\n" "size: %d\n components: %d\n strides[0]: %d\n strides[1]: %d\n offset[0]: %d\n offset[1]: %d\n",hwres->get_sequence(), camVBuf->info.format, camVBuf->info.color_bits, camVBuf->info.width, camVBuf->info.height, camVBuf->info.aligned_width, camVBuf->info.aligned_height, camVBuf->info.size, camVBuf->info.components, camVBuf->info.strides[0], camVBuf->info.strides[1], camVBuf->info.offsets[0], camVBuf->info.offsets[1]); camVBuf->unref(camVBuf); #endif LOGD_ANALYZER("ISP_IMG"); ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_NR_IMG) { #if 0 XCamVideoBuffer* camVBuf = convert_to_XCamVideoBuffer(hwres); LOGD_ANALYZER("nrimg: \n format: 0x%x\n color_bits: %d\n width: %d\n height: %d\n aligned_width: %d\naligned_height: %d\n" "size: %d\n components: %d\n strides[0]: %d\n strides[1]: %d\n offset[0]: %d\n offset[1]: %d\n", camVBuf->info.format, camVBuf->info.color_bits, camVBuf->info.width, camVBuf->info.height, camVBuf->info.aligned_width, camVBuf->info.aligned_height, camVBuf->info.size, camVBuf->info.components, camVBuf->info.strides[0], camVBuf->info.strides[1], camVBuf->info.offsets[0], camVBuf->info.offsets[1]); camVBuf->unref(camVBuf); #endif ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISP_GAIN) { LOGD_ANALYZER("ISP_GAIN"); ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISPP_GAIN_WR) { LOGD_ANALYZER("ISPP_GAIN_WR"); ret = mRkAiqAnalyzer->pushStats(hwres); } else if (hwres->_buf_type == ISPP_GAIN_KG) { LOGD_ANALYZER("ISPP_GAIN_KG"); ret = mRkAiqAnalyzer->pushStats(hwres); } EXIT_XCORE_FUNCTION(); return ret; } #if 0 XCamReturn RkAiqManager::applyAnalyzerResult(SmartPtr& results) { ENTER_XCORE_FUNCTION(); xcam_get_runtime_log_level(); XCamReturn ret = XCAM_RETURN_NO_ERROR; RkAiqFullParams* aiqParams = NULL; if (!results.ptr()) { LOGW_ANALYZER("empty aiq params results!"); return ret; } // TODO: couldn't get dynamic debug env now #if 0//def RUNTIME_MODULE_DEBUG get_dbg_force_disable_mods_env(); #endif aiqParams = results->data().ptr(); #ifdef RUNTIME_MODULE_DEBUG #ifndef RK_SIMULATOR_HW if (g_bypass_exp_params) goto set_exp_end; #endif #endif /* #define FLASH_CTL_DEBUG */ #ifdef FLASH_CTL_DEBUG { // for test int fd = open("/tmp/flash_ctl", O_RDWR); if (fd != -1) { char c; read(fd, &c, 1); int enable = atoi(&c); SmartPtr fl = new rk_aiq_flash_setting_t(); fl->flash_mode = enable ? RK_AIQ_FLASH_MODE_TORCH : RK_AIQ_FLASH_MODE_OFF; fl->power[0] = 10000; fl->strobe = enable ? true : false; aiqParams->mFlParams = new SharedItemProxy(fl); aiqParams->mFlParams->setType(RESULT_TYPE_CPSL_PARAM); mCamHw->applyAnalyzerResult(aiqParams->mFlParams, false); close(fd); } } #else #ifndef RK_SIMULATOR_HW if (aiqParams->mCpslParams.ptr() && aiqParams->mIspOtherParams.ptr()) { SmartPtr mCamHwIsp20 = mCamHw.dynamic_cast_ptr(); // TODO Merge : consider isp21 ? rk_aiq_isp_other_params_v20_t* ispParams = static_cast(aiqParams->mIspOtherParams->data().ptr()); int gray_mode = ispParams->ie.base.mode; bool cpsl_ir_en = aiqParams->mCpslParams->data()->update_ir && aiqParams->mCpslParams->data()->ir.irc_on; bool cpsl_update = aiqParams->mCpslParams->data()->update_ir || aiqParams->mCpslParams->data()->update_fl; if (cpsl_ir_en) { mDelayCpslApplyFrmNum = 2; mDleayCpslParams = aiqParams->mCpslParams; LOGD_ANALYZER("gray mode on, cpsl ir on delay 2 frames"); } else if (cpsl_update) { mDleayCpslParams.release(); mDelayCpslApplyFrmNum = 0; aiqParams->mCpslParams->setType(RESULT_TYPE_CPSL_PARAM); mCamHw->applyAnalyzerResult(aiqParams->mCpslParams, false); } } if (mDleayCpslParams.ptr() && --mDelayCpslApplyFrmNum == 0) { LOGD_ANALYZER("set delyay cpsl ir on"); aiqParams->mCpslParams->setType(RESULT_TYPE_CPSL_PARAM); mCamHw->applyAnalyzerResult(mDleayCpslParams, false); } #endif #endif if (aiqParams->mExposureParams.ptr()) { //#define DEBUG_FIXED_EXPOSURE #ifdef DEBUG_FIXED_EXPOSURE /* test aec with fixed sensor exposure */ int cnt = aiqParams->mIspMeasParams->data()->frame_id ; if (aiqParams->mExposureParams->data()->algo_id == 0) { aiqParams->mExposureParams->data()->exp_tbl_size = 1; RKAiqAecExpInfo_t* exp_tbl = &aiqParams->mExposureParams->data()->exp_tbl[0]; if(cnt % 40 <= 19) { exp_tbl->HdrExp[2].exp_sensor_params.coarse_integration_time = 984; exp_tbl->HdrExp[2].exp_sensor_params.analog_gain_code_global = 48; exp_tbl->HdrExp[1].exp_sensor_params.coarse_integration_time = 984; exp_tbl->HdrExp[1].exp_sensor_params.analog_gain_code_global = 48; exp_tbl->HdrExp[0].exp_sensor_params.coarse_integration_time = 246; exp_tbl->HdrExp[0].exp_sensor_params.analog_gain_code_global = 16; exp_tbl->HdrExp[2].exp_real_params.integration_time = 0.02; exp_tbl->HdrExp[2].exp_real_params.analog_gain = 3; exp_tbl->HdrExp[1].exp_real_params.integration_time = 0.02; exp_tbl->HdrExp[1].exp_real_params.analog_gain = 3; exp_tbl->HdrExp[0].exp_real_params.integration_time = 0.005; exp_tbl->HdrExp[0].exp_real_params.analog_gain = 1; } else { exp_tbl->HdrExp[2].exp_sensor_params.coarse_integration_time = 1475; exp_tbl->HdrExp[2].exp_sensor_params.analog_gain_code_global = 144; exp_tbl->HdrExp[1].exp_sensor_params.coarse_integration_time = 1475; exp_tbl->HdrExp[1].exp_sensor_params.analog_gain_code_global = 144; exp_tbl->HdrExp[0].exp_sensor_params.coarse_integration_time = 492; exp_tbl->HdrExp[0].exp_sensor_params.analog_gain_code_global = 48; exp_tbl->HdrExp[2].exp_real_params.integration_time = 0.03; exp_tbl->HdrExp[2].exp_real_params.analog_gain = 9; exp_tbl->HdrExp[1].exp_real_params.integration_time = 0.03; exp_tbl->HdrExp[1].exp_real_params.analog_gain = 9; exp_tbl->HdrExp[0].exp_real_params.integration_time = 0.01; exp_tbl->HdrExp[0].exp_real_params.analog_gain = 3; } } aiqParams->mExposureParams->setType(RESULT_TYPE_EXPOSURE); mCamHw->applyAnalyzerResult(aiqParams->mExposureParams, false); #else aiqParams->mExposureParams->setType(RESULT_TYPE_EXPOSURE); if (_state == AIQ_STATE_STARTED) mCamHw->applyAnalyzerResult(aiqParams->mExposureParams, false); else mCamHw->applyAnalyzerResult(aiqParams->mExposureParams, true); #endif } set_exp_end: CalibDb_Aec_ParaV2_t *aec = (CalibDb_Aec_ParaV2_t*)(CALIBDBV2_GET_MODULE_PTR((void*)mCalibDbV2, ae_calib)); if (aiqParams->mIrisParams.ptr()) { aiqParams->mIrisParams->setType(RESULT_TYPE_IRIS_PARAM); mCamHw->applyAnalyzerResult(aiqParams->mIrisParams, false); } #ifdef RUNTIME_MODULE_DEBUG #ifndef RK_SIMULATOR_HW if (g_bypass_isp_params) goto set_isp_end; #endif #endif if (aiqParams->mIspOtherParams.ptr()) { aiqParams->mIspOtherParams->setType(RESULT_TYPE_ISP_OTHER); if (_state == AIQ_STATE_STARTED) mCamHw->applyAnalyzerResult(aiqParams->mIspOtherParams, false); else mCamHw->applyAnalyzerResult(aiqParams->mIspOtherParams, true); } if (aiqParams->mIspMeasParams.ptr()) { #ifndef RK_SIMULATOR_HW if (mWorkingMode != RK_AIQ_WORKING_MODE_NORMAL) { SmartPtr mCamHwIsp20 = mCamHw.dynamic_cast_ptr(); // TODO Merge : consider isp21 ? rk_aiq_isp_meas_params_v20_t* ispParams = static_cast(aiqParams->mIspMeasParams->data().ptr()); bool isHdrGlobalTmo = ispParams->atmo_proc_res.isHdrGlobalTmo; mCamHwIsp20->setHdrGlobalTmoMode(aiqParams->mIspMeasParams->data()->frame_id, isHdrGlobalTmo); } #endif aiqParams->mIspMeasParams->setType(RESULT_TYPE_ISP_MEAS); if (_state == AIQ_STATE_STARTED) mCamHw->applyAnalyzerResult(aiqParams->mIspMeasParams, false); else mCamHw->applyAnalyzerResult(aiqParams->mIspMeasParams, true); } set_isp_end: #ifdef RUNTIME_MODULE_DEBUG #ifndef RK_SIMULATOR_HW if (g_bypass_ispp_params) goto set_ispp_end; #endif #endif #ifndef DISABLE_PP if (aiqParams->mIsppOtherParams.ptr()) { aiqParams->mIsppOtherParams->setType(RESULT_TYPE_ISPP_OTHER); if (_state == AIQ_STATE_STARTED) mCamHw->applyAnalyzerResult(aiqParams->mIsppOtherParams, false); else mCamHw->applyAnalyzerResult(aiqParams->mIsppOtherParams, true); } if (aiqParams->mIsppMeasParams.ptr()) { aiqParams->mIsppMeasParams->setType(RESULT_TYPE_ISPP_MEAS); if (_state == AIQ_STATE_STARTED) mCamHw->applyAnalyzerResult(aiqParams->mIsppMeasParams, false); else mCamHw->applyAnalyzerResult(aiqParams->mIsppMeasParams, true); } #endif set_ispp_end: if (aiqParams->mFocusParams.ptr()) { aiqParams->mFocusParams->setType(RESULT_TYPE_AF_PARAM); mCamHw->applyAnalyzerResult(aiqParams->mFocusParams, false); } // disable this feature now, this require the hdr mode set to auto #if 0 // switch working mode by gray_mode ? if (aiqParams->mIspMeasParams.ptr()) { SmartPtr isp_params = aiqParams->mIspMeasParams->data(); LOGD_ANALYZER("ie mode %d, mWkSwitching %d, mWorkingMode %d, mOldWkModeForGray %d", isp_params->ie.base.mode, mWkSwitching, mWorkingMode, mOldWkModeForGray); if (isp_params->ie.base.mode == RK_AIQ_IE_EFFECT_BW && mWorkingMode != RK_AIQ_WORKING_MODE_NORMAL && !mWkSwitching) { mOldWkModeForGray = mWorkingMode; mWkSwitching = true; LOGD_ANALYZER("switch to BW, old mode %d", mOldWkModeForGray); SmartPtr msg = new RkAiqMngCmdThread::msg_t(); msg->cmd = RkAiqMngCmdThread::MSG_CMD_SW_WORKING_MODE; msg->sync = false; msg->data.sw_wk_mode.mode = RK_AIQ_WORKING_MODE_NORMAL; mAiqMngCmdTh->send_cmd(msg); } else if (isp_params->ie.base.mode != RK_AIQ_IE_EFFECT_BW && mOldWkModeForGray != RK_AIQ_WORKING_MODE_NORMAL && !mWkSwitching) { LOGD_ANALYZER("switch to color, old mode %d", mOldWkModeForGray); mWkSwitching = true; SmartPtr msg = new RkAiqMngCmdThread::msg_t(); msg->cmd = RkAiqMngCmdThread::MSG_CMD_SW_WORKING_MODE; msg->sync = false; msg->data.sw_wk_mode.mode = mOldWkModeForGray; mAiqMngCmdTh->send_cmd(msg); mOldWkModeForGray = RK_AIQ_WORKING_MODE_NORMAL; LOGD_ANALYZER("done switch to color, old mode %d", mOldWkModeForGray); } } #endif EXIT_XCORE_FUNCTION(); out: return ret; } #else /* TODO: add other features */ XCamReturn RkAiqManager::applyAnalyzerResult(SmartPtr& results) { ENTER_XCORE_FUNCTION(); //xcam_get_runtime_log_level(); XCamReturn ret = XCAM_RETURN_NO_ERROR; RkAiqFullParams* aiqParams = NULL; if (!results.ptr()) { LOGW_ANALYZER("empty aiq params results!"); return ret; } aiqParams = results->data().ptr(); cam3aResultList results_list; if (aiqParams->mExposureParams.ptr()) { aiqParams->mExposureParams->setType(RESULT_TYPE_EXPOSURE); results_list.push_back(aiqParams->mExposureParams); } if (aiqParams->mFocusParams.ptr()) { aiqParams->mFocusParams->setType(RESULT_TYPE_FOCUS_PARAM); results_list.push_back(aiqParams->mFocusParams); } #define APPLY_ANALYZER_RESULT(lc, BC) \ if (aiqParams->m##lc##Params.ptr()) { \ aiqParams->m##lc##Params->setType(RESULT_TYPE_##BC##_PARAM); \ aiqParams->m##lc##Params->setId(aiqParams->m##lc##Params->data()->frame_id); \ results_list.push_back(aiqParams->m##lc##Params); \ } \ APPLY_ANALYZER_RESULT(Aec, AEC); APPLY_ANALYZER_RESULT(Hist, HIST); APPLY_ANALYZER_RESULT(Awb, AWB); APPLY_ANALYZER_RESULT(AwbGain, AWBGAIN); APPLY_ANALYZER_RESULT(Af, AF); APPLY_ANALYZER_RESULT(Dpcc, DPCC); APPLY_ANALYZER_RESULT(Merge, MERGE); APPLY_ANALYZER_RESULT(Tmo, TMO); APPLY_ANALYZER_RESULT(Ccm, CCM); APPLY_ANALYZER_RESULT(Lsc, LSC); APPLY_ANALYZER_RESULT(Blc, BLC); APPLY_ANALYZER_RESULT(Rawnr, RAWNR); APPLY_ANALYZER_RESULT(Gic, GIC); APPLY_ANALYZER_RESULT(Debayer, DEBAYER); APPLY_ANALYZER_RESULT(Ldch, LDCH); APPLY_ANALYZER_RESULT(Lut3d, LUT3D); APPLY_ANALYZER_RESULT(Dehaze, DEHAZE); APPLY_ANALYZER_RESULT(Agamma, AGAMMA); APPLY_ANALYZER_RESULT(Adegamma, ADEGAMMA); APPLY_ANALYZER_RESULT(Wdr, WDR); APPLY_ANALYZER_RESULT(Csm, CSM); APPLY_ANALYZER_RESULT(Cgc, CGC); APPLY_ANALYZER_RESULT(Conv422, CONV422); APPLY_ANALYZER_RESULT(Yuvconv, YUVCONV); APPLY_ANALYZER_RESULT(Gain, GAIN); APPLY_ANALYZER_RESULT(Cp, CP); APPLY_ANALYZER_RESULT(Ie, IE); APPLY_ANALYZER_RESULT(Motion, MOTION); APPLY_ANALYZER_RESULT(Tnr, TNR); APPLY_ANALYZER_RESULT(Ynr, YNR); APPLY_ANALYZER_RESULT(Uvnr, UVNR); APPLY_ANALYZER_RESULT(Sharpen, SHARPEN); APPLY_ANALYZER_RESULT(Edgeflt, EDGEFLT); APPLY_ANALYZER_RESULT(Fec, FEC); APPLY_ANALYZER_RESULT(Orb, ORB); // ispv21 APPLY_ANALYZER_RESULT(DrcV21, DRC); APPLY_ANALYZER_RESULT(AwbV21, AWB); APPLY_ANALYZER_RESULT(BlcV21, BLC); APPLY_ANALYZER_RESULT(GicV21, GIC); APPLY_ANALYZER_RESULT(DehazeV21, DEHAZE); APPLY_ANALYZER_RESULT(YnrV21, YNR); APPLY_ANALYZER_RESULT(CnrV21, UVNR); APPLY_ANALYZER_RESULT(SharpenV21, SHARPEN); APPLY_ANALYZER_RESULT(BaynrV21, RAWNR); mCamHw->applyAnalyzerResult(results_list); EXIT_XCORE_FUNCTION(); return ret; } #endif void RkAiqManager::rkAiqCalcDone(SmartPtr &results) { ENTER_XCORE_FUNCTION(); XCAM_ASSERT (mAiqRstAppTh.ptr()); mAiqRstAppTh->push_results(results); EXIT_XCORE_FUNCTION(); } void RkAiqManager::rkAiqCalcFailed(const char* msg) { ENTER_XCORE_FUNCTION(); // TODO EXIT_XCORE_FUNCTION(); return ; } void RkAiqManager::rkLumaCalcDone(rk_aiq_luma_params_t luma_params) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->setHdrProcessCount(luma_params); EXIT_XCORE_FUNCTION(); } void RkAiqManager::rkLumaCalcFailed(const char* msg) { ENTER_XCORE_FUNCTION(); // TODO EXIT_XCORE_FUNCTION(); return ; } XCamReturn RkAiqManager::setModuleCtl(rk_aiq_module_id_t mId, bool mod_en) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->setModuleCtl(mId, mod_en); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::getModuleCtl(rk_aiq_module_id_t mId, bool& mod_en) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->getModuleCtl(mId, mod_en); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::rawdataPrepare(rk_aiq_raw_prop_t prop) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->rawdataPrepare(prop); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::enqueueRawBuffer(void *rawdata, bool sync) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->enqueueRawBuffer(rawdata, sync); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::enqueueRawFile(const char *path) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->enqueueRawFile(path); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::registRawdataCb(void (*callback)(void *)) { ENTER_XCORE_FUNCTION(); XCamReturn ret = XCAM_RETURN_NO_ERROR; ret = mCamHw->registRawdataCb(callback); EXIT_XCORE_FUNCTION(); return ret; } XCamReturn RkAiqManager::setSharpFbcRotation(rk_aiq_rotation_t rot) { #ifndef RK_SIMULATOR_HW SmartPtr camHwIsp20 = mCamHw.dynamic_cast_ptr(); if (camHwIsp20.ptr()) return camHwIsp20->setSharpFbcRotation(rot); else return XCAM_RETURN_ERROR_FAILED; #else return XCAM_RETURN_ERROR_FAILED; #endif } XCamReturn RkAiqManager::setMirrorFlip(bool mirror, bool flip, int skip_frm_cnt) { XCamReturn ret = XCAM_RETURN_NO_ERROR; ENTER_XCORE_FUNCTION(); if (_state == AIQ_STATE_INVALID) { LOGE_ANALYZER("wrong aiq state !"); return XCAM_RETURN_ERROR_FAILED; } ret = mCamHw->setSensorFlip(mirror, flip, skip_frm_cnt); if (ret == XCAM_RETURN_NO_ERROR) { // notify aiq sensor flip is changed mRkAiqAnalyzer->setSensorFlip(mirror, flip); mCurMirror = mirror; mCurFlip = flip; } else { LOGW_ANALYZER("set mirror %d, flip %d error", mirror, flip); } return ret; EXIT_XCORE_FUNCTION(); } XCamReturn RkAiqManager::getMirrorFlip(bool& mirror, bool& flip) { ENTER_XCORE_FUNCTION(); if (_state == AIQ_STATE_INVALID) { LOGE_ANALYZER("wrong aiq state !"); return XCAM_RETURN_ERROR_FAILED; } mirror = mCurMirror; flip = mCurFlip; EXIT_XCORE_FUNCTION(); return XCAM_RETURN_NO_ERROR; } void RkAiqManager::setDefMirrorFlip() { /* set defalut mirror & flip from iq*/ CalibDb_Sensor_ParaV2_t* sensor = (CalibDb_Sensor_ParaV2_t*)(CALIBDBV2_GET_MODULE_PTR(mCalibDbV2, sensor_calib)); bool def_mirr = sensor->CISFlip & 0x1 ? true : false; bool def_flip = sensor->CISFlip & 0x2 ? true : false; setMirrorFlip(def_mirr, def_flip, 0); } XCamReturn RkAiqManager::swWorkingModeDyn_msg(rk_aiq_working_mode_t mode) { SmartPtr msg = new RkAiqMngCmdThread::msg_t(); msg->cmd = RkAiqMngCmdThread::MSG_CMD_SW_WORKING_MODE; msg->sync = true; msg->data.sw_wk_mode.mode = mode; mAiqMngCmdTh->send_cmd(msg); return XCAM_RETURN_NO_ERROR; } XCamReturn RkAiqManager::swWorkingModeDyn(rk_aiq_working_mode_t mode) { ENTER_XCORE_FUNCTION(); SmartPtr initParams; XCamReturn ret = XCAM_RETURN_NO_ERROR; if (mode == mWorkingMode) return ret; if (_state != AIQ_STATE_STARTED) { LOGW_ANALYZER("should be called at STARTED state"); return ret; } // 1. stop analyzer, re-preapre with the new mode // 2. stop luma analyzer, re-preapre with the new mode LOGI_ANALYZER("stop analyzer ..."); mAiqRstAppTh->triger_stop(); bool bret = mAiqRstAppTh->stop(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread stop error"); ret = mRkAiqAnalyzer->stop(); RKAIQMNG_CHECK_RET(ret, "analyzer stop error %d", ret); ret = mRkLumaAnalyzer->stop(); RKAIQMNG_CHECK_RET(ret, "luma analyzer stop error %d", ret); // 3. pause hwi LOGI_ANALYZER("pause hwi ..."); ret = mCamHw->pause(); RKAIQMNG_CHECK_RET(ret, "pause hwi error %d", ret); int working_mode_hw = RK_AIQ_WORKING_MODE_NORMAL; if (mode == RK_AIQ_WORKING_MODE_ISP_HDR2) working_mode_hw = RK_AIQ_ISP_HDR_MODE_2_FRAME_HDR; else if (mode == RK_AIQ_WORKING_MODE_ISP_HDR3) working_mode_hw = RK_AIQ_ISP_HDR_MODE_3_FRAME_HDR; // 4. set new mode to hwi ret = mCamHw->swWorkingModeDyn(working_mode_hw); if (ret) { LOGE_ANALYZER("hwi swWorkingModeDyn error ..."); goto restart; } // 5. re-prepare analyzer LOGI_ANALYZER("reprepare analyzer ..."); rk_aiq_exposure_sensor_descriptor sensor_des; ret = mCamHw->getSensorModeData(mSnsEntName, sensor_des); mRkAiqAnalyzer->notifyIspStreamMode(mCamHw->getIspStreamMode()); ret = mRkAiqAnalyzer->prepare(&sensor_des, working_mode_hw); RKAIQMNG_CHECK_RET(ret, "analyzer prepare error %d", ret); initParams = mRkAiqAnalyzer->getAiqFullParams(); ret = applyAnalyzerResult(initParams); RKAIQMNG_CHECK_RET(ret, "set initial params error %d", ret); restart: // 6. resume hwi LOGI_ANALYZER("resume hwi"); ret = mCamHw->resume(); RKAIQMNG_CHECK_RET(ret, "pause hwi error %d", ret); // 7. restart analyzer LOGI_ANALYZER("restart analyzer"); mAiqRstAppTh->triger_start(); bret = mAiqRstAppTh->start(); ret = bret ? XCAM_RETURN_NO_ERROR : XCAM_RETURN_ERROR_FAILED; RKAIQMNG_CHECK_RET(ret, "apply result thread start error"); ret = mRkAiqAnalyzer->start(); RKAIQMNG_CHECK_RET(ret, "analyzer start error %d", ret); ret = mRkLumaAnalyzer->start(); RKAIQMNG_CHECK_RET(ret, "luma analyzer start error %d", ret); /* // 7. resume hwi */ /* LOGI_ANALYZER("resume hwi"); */ /* ret = mCamHw->resume(); */ /* RKAIQMNG_CHECK_RET(ret, "pause hwi error %d", ret); */ mWorkingMode = mode; EXIT_XCORE_FUNCTION(); return XCAM_RETURN_NO_ERROR; } void RkAiqManager::setMulCamConc(bool cc) { #ifndef RK_SIMULATOR_HW SmartPtr camHwIsp20 = mCamHw.dynamic_cast_ptr(); if (camHwIsp20.ptr()) camHwIsp20->setMulCamConc(cc); #endif } CamCalibDbV2Context_t* RkAiqManager::getCurrentCalibDBV2() { return mCalibDbV2; } XCamReturn RkAiqManager::calibTuning(const CamCalibDbV2Context_t* aiqCalib, ModuleNameList& change_list) { if (!aiqCalib) { return XCAM_RETURN_ERROR_PARAM; } *mCalibDbV2 = *aiqCalib; mCamHw->setCalib(mCalibDbV2); return mRkAiqAnalyzer->calibTuning(aiqCalib, change_list); } }; //namespace RkCam