#include "rk_aiq_acnr_algo_cnr_v1.h" RKAIQ_BEGIN_DECLARE Acnr_result_t cnr_get_mode_by_name_V1(struct list_head* pCalibdbList, char *name, Calibdb_Cnr_V1_t** ppProfile) { int i = 0; Acnr_result_t res = ACNR_RET_SUCCESS; if(pCalibdbList == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(name == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(ppProfile == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } #if 1 *ppProfile = NULL; struct list_head* p; p = pCalibdbList->next; while (p != pCalibdbList) { Calibdb_Cnr_V1_t* pProfile = container_of(p, Calibdb_Cnr_V1_t, listItem); LOGD_ANR("%s:%d %s %p \n", __FUNCTION__, __LINE__, pProfile->modeName, p); if (!strncmp(pProfile->modeName, name, sizeof(pProfile->modeName))) { *ppProfile = pProfile; return res; } p = p->next; } Calibdb_Cnr_V1_t* pProfile = container_of(pCalibdbList->next, Calibdb_Cnr_V1_t, listItem); *ppProfile = pProfile; #else #endif return res; } Acnr_result_t cnr_get_setting_by_name_V1(struct list_head *pSettingList, char *name, Calibdb_Cnr_params_V1_t** ppSetting) { int i = 0; Acnr_result_t res = ACNR_RET_SUCCESS; if(pSettingList == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(name == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(ppSetting == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } *ppSetting = NULL; struct list_head* p; p = pSettingList->next; while (p != pSettingList) { Calibdb_Cnr_params_V1_t* pSetting = container_of(p, Calibdb_Cnr_params_V1_t, listItem); LOGD_ANR("%s:%d: %s %p \n", __FUNCTION__, __LINE__, pSetting->snr_mode, p); if (!strncmp(pSetting->snr_mode, name, sizeof(pSetting->snr_mode))) { *ppSetting = pSetting; return res; } p = p->next; } Calibdb_Cnr_params_V1_t* pSetting = container_of(pSettingList->next, Calibdb_Cnr_params_V1_t, listItem); *ppSetting = pSetting; return res; } Acnr_result_t cnr_config_setting_param_V1(RK_CNR_Params_V1_t *pParams, struct list_head *pCalibdbList, char* param_mode, char * snr_name) { Acnr_result_t res = ACNR_RET_SUCCESS; Calibdb_Cnr_V1_t *pProfile; Calibdb_Cnr_params_V1_t *pCalibParms; if(pParams == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pCalibdbList == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(param_mode == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(snr_name == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } res = cnr_get_mode_by_name_V1(pCalibdbList, param_mode, &pProfile); if(res != ACNR_RET_SUCCESS) { LOGW_ANR("%s(%d): error!!! can't find mode name in iq files, use 0 instead\n", __FUNCTION__, __LINE__); } res = cnr_get_setting_by_name_V1(&pProfile->listHead, snr_name, &pCalibParms); if(res != ACNR_RET_SUCCESS) { LOGW_ANR("%s(%d): error!!! can't find setting in iq files, use 0 instead\n", __FUNCTION__, __LINE__); } res = cnr_init_params_V1(pParams, pCalibParms); pParams->enable = pProfile->enable; return res; } Acnr_result_t cnr_init_params_V1(RK_CNR_Params_V1_t *pParams, Calibdb_Cnr_params_V1_t* pCalibParms) { Acnr_result_t res = ACNR_RET_SUCCESS; int i = 0; int j = 0; if(pParams == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pCalibParms == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } pParams->enable = pCalibParms->enable; for(i = 0; i < RK_CNR_V1_MAX_ISO_NUM; i++ ) { pParams->iso[i] = pCalibParms->iso[i]; pParams->rkcnr_hq_bila_bypass[i] = pCalibParms->rkcnr_hq_bila_bypass[i]; pParams->rkcnr_lq_bila_bypass[i] = pCalibParms->rkcnr_lq_bila_bypass[i]; pParams->rkcnr_exgain[i] = pCalibParms->rkcnr_exgain[i]; pParams->rkcnr_g_gain[i] = pCalibParms->rkcnr_g_gain[i]; pParams->ratio[i] = pCalibParms->ratio[i]; pParams->offset[i] = pCalibParms->offset[i]; pParams->medRatio1[i] = pCalibParms->medRatio1[i]; pParams->sigmaR1[i] = pCalibParms->sigmaR1[i]; pParams->uvgain1[i] = pCalibParms->uvgain1[i]; pParams->bfRatio1[i] = pCalibParms->bfRatio1[i]; pParams->hbf_wgt_clip[i] = pCalibParms->hbf_wgt_clip[i]; pParams->medRatio2[i] = pCalibParms->medRatio2[i]; pParams->sigmaR2[i] = pCalibParms->sigmaR2[i]; pParams->uvgain2[i] = pCalibParms->uvgain2[i]; pParams->sigmaR3[i] = pCalibParms->sigmaR3[i]; pParams->uvgain3[i] = pCalibParms->uvgain3[i]; pParams->bfRatio3[i] = pCalibParms->bfRatio3[i]; } memcpy(pParams->kernel_5x5_table, pCalibParms->kernel_5x5_table, sizeof(float) * 5); return ACNR_RET_SUCCESS; } float interp_cnr_v1(int ISO_low, int ISO_high, float value_low, float value_high, int ISO, float value) { if (ISO <= ISO_low) { value = value_low; } else if (ISO >= ISO_high) { value = value_high; } else { value = float(ISO - ISO_low) / float(ISO_high - ISO_low) * (value_high - value_low) + value_low; } return value; } Acnr_result_t cnr_select_params_by_ISO_V1(RK_CNR_Params_V1_t *pParams, RK_CNR_Params_V1_Select_t *pSelect, Acnr_ExpInfo_t *pExpInfo) { Acnr_result_t res = ACNR_RET_SUCCESS; int iso = 50; if(pParams == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pSelect == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pExpInfo == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } iso = pExpInfo->arIso[pExpInfo->hdr_mode]; //È·¶¨isoµÈ¼¶ //rkuvnriso@50 100 200 400 800 1600 3200 6400 12800 // isogain: 1 2 4 8 16 32 64 128 256 // isoindex: 0 1 2 3 4 5 6 7 8 int isoIndex = 0; int isoGainLow = 0; int isoGainHigh = 0; int isoIndexLow = 0; int isoIndexHigh = 0; int iso_div = 50; int max_iso_step = RK_CNR_V1_MAX_ISO_NUM; #ifndef RK_SIMULATOR_HW for (int i = 0; i < max_iso_step - 1 ; i++) { if (iso >= pParams->iso[i] && iso <= pParams->iso[i + 1]) { isoGainLow = pParams->iso[i] ; isoGainHigh = pParams->iso[i + 1]; isoIndexLow = i; isoIndexHigh = i + 1; isoIndex = isoIndexLow; } } if(iso < pParams->iso[0] ) { isoGainLow = pParams->iso[0]; isoGainHigh = pParams->iso[1]; isoIndexLow = 0; isoIndexHigh = 1; isoIndex = 0; } if(iso > pParams->iso[max_iso_step - 1] ) { isoGainLow = pParams->iso[max_iso_step - 2] ; isoGainHigh = pParams->iso[max_iso_step - 1]; isoIndexLow = max_iso_step - 2; isoIndexHigh = max_iso_step - 1; isoIndex = max_iso_step - 1; } #else isoIndex = int(log(float(iso / iso_div)) / log(2.0f)); for (int i = max_iso_step - 1; i >= 0; i--) { if (iso < iso_div * (2 << i)) { isoGainLow = iso_div * (2 << (i)) / 2; isoGainHigh = iso_div * (2 << i); } } isoGainLow = MIN(isoGainLow, iso_div * (2 << max_iso_step)); isoGainHigh = MIN(isoGainHigh, iso_div * (2 << max_iso_step)); isoIndexHigh = (int)(log((float)isoGainHigh / iso_div) / log((float)2)); isoIndexLow = (int)(log((float)isoGainLow / iso_div) / log((float)2)); isoIndexLow = MIN(MAX(isoIndexLow, 0), max_iso_step - 1); isoIndexHigh = MIN(MAX(isoIndexHigh, 0), max_iso_step - 1); #endif LOGD_ANR("%s:%d iso:%d high:%d low:%d \n", __FUNCTION__, __LINE__, iso, isoGainHigh, isoGainLow); pSelect->enable = pParams->enable; // bypass pSelect->rkcnr_hq_bila_bypass = pParams->rkcnr_hq_bila_bypass[isoIndex]; pSelect->rkcnr_lq_bila_bypass = pParams->rkcnr_lq_bila_bypass[isoIndex]; // gain pSelect->rkcnr_exgain = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->rkcnr_exgain[isoIndexLow], pParams->rkcnr_exgain[isoIndexHigh], iso, pSelect->rkcnr_exgain); pSelect->rkcnr_g_gain = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->rkcnr_g_gain[isoIndexLow], pParams->rkcnr_g_gain[isoIndexHigh], iso, pSelect->rkcnr_g_gain); // pSelect->ratio = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->ratio[isoIndexLow], pParams->ratio[isoIndexHigh], iso, pSelect->ratio); pSelect->offset = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->offset[isoIndexLow], pParams->offset[isoIndexHigh], iso, pSelect->offset); // step1 // median filter pSelect->medRatio1 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->medRatio1[isoIndexLow], pParams->medRatio1[isoIndexHigh], iso, pSelect->medRatio1); // bilateral filter pSelect->sigmaR1 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->sigmaR1[isoIndexLow], pParams->sigmaR1[isoIndexHigh], iso, pSelect->sigmaR1); pSelect->uvgain1 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->uvgain1[isoIndexLow], pParams->uvgain1[isoIndexHigh], iso, pSelect->uvgain1); pSelect->bfRatio1 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->bfRatio1[isoIndexLow], pParams->bfRatio1[isoIndexHigh], iso, pSelect->bfRatio1); pSelect->hbf_wgt_clip = pParams->hbf_wgt_clip[isoIndex]; // step2 // median filter pSelect->medRatio2 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->medRatio2[isoIndexLow], pParams->medRatio2[isoIndexHigh], iso, pSelect->medRatio2); // bilateral filter pSelect->sigmaR2 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->sigmaR2[isoIndexLow], pParams->sigmaR2[isoIndexHigh], iso, pSelect->sigmaR2); pSelect->uvgain2 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->uvgain2[isoIndexLow], pParams->uvgain2[isoIndexHigh], iso, pSelect->uvgain2); // step3 // bilateral filter pSelect->sigmaR3 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->sigmaR3[isoIndexLow], pParams->sigmaR3[isoIndexHigh], iso, pSelect->sigmaR3); pSelect->uvgain3 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->uvgain3[isoIndexLow], pParams->uvgain3[isoIndexHigh], iso, pSelect->uvgain3); pSelect->bfRatio3 = interp_cnr_v1(isoGainLow, isoGainHigh, pParams->bfRatio3[isoIndexLow], pParams->bfRatio3[isoIndexHigh], iso, pSelect->bfRatio3); // bilateral filter kernels memcpy(pSelect->kernel_5x5_table, pParams->kernel_5x5_table, sizeof(float) * 5); return ACNR_RET_SUCCESS; } Acnr_result_t cnr_fix_transfer_V1(RK_CNR_Params_V1_Select_t *pSelect, RK_CNR_Fix_V1_t *pFix, Acnr_ExpInfo_t *pExpInfo, float fStrength) { LOGI_ANR("%s:(%d) enter \n", __FUNCTION__, __LINE__); int i = 0; Acnr_result_t res = ACNR_RET_SUCCESS; int tmp = 0; if(pSelect == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pFix == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(pExpInfo == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } if(fStrength <= 0.0) { fStrength = 0.000001; } // fix bit : RK_CNR_V1_log2e + RK_CNR_V1_SIGMA_FIX_BIT, msigma = (1 / sigma) * (1 << RK_CNR_V1_SIGMA_FIX_BIT) * log2e * (1 << RK_CNR_V1_log2e); int log2e = (int)(0.8493f * (1 << (RK_CNR_V1_log2e + RK_CNR_V1_SIGMA_FIX_BIT))); //ISP_CNR_2800_CTRL pFix->cnr_thumb_mix_cur_en = 0; pFix->cnr_exgain_bypass = 1; pFix->cnr_hq_bila_bypass = pSelect->rkcnr_hq_bila_bypass; pFix->cnr_lq_bila_bypass = pSelect->rkcnr_lq_bila_bypass; pFix->cnr_en_i = pSelect->enable; // ISP_CNR_2800_EXGAIN tmp = pSelect->rkcnr_exgain * (1 << RK_CNR_V1_sgmGain); pFix->cnr_exgain_mux = CLIP(tmp, 0, 255); // ISP_CNR_2800_GAIN_PARA tmp = pSelect->rkcnr_g_gain * (1 << RK_CNR_V1_gainRatio); pFix->cnr_gain_iso = CLIP(tmp, 0, 128); tmp = (int)(pSelect->offset * (1 << RK_CNR_V1_offset)); pFix->cnr_gain_offset = CLIP(tmp, 0, 16); tmp = (int)(pSelect->ratio * (1 << RK_CNR_V1_ratio)); pFix->cnr_gain_1sigma = CLIP(tmp, 0, 255); // ISP_CNR_2800_GAIN_UV_PARA tmp = (int)(pSelect->uvgain1 / fStrength * (1 << RK_CNR_V1_uvgain)); pFix->cnr_gain_uvgain0 = CLIP(tmp, 0, (1 << 7) - 1); tmp = (int)(pSelect->uvgain3 / fStrength * (1 << RK_CNR_V1_uvgain)); pFix->cnr_gain_uvgain1 = CLIP(tmp, 0, (1 << 7) - 1); // ISP_CNR_2800_LMED3 tmp = (int)(pSelect->medRatio2 * (1 << RK_CNR_V1_medRatio)); pFix->cnr_lmed3_alpha = CLIP(tmp, 0, 16); // ISP_CNR_2800_LBF5_GAIN int rkcnr_sigmaR2 = (int)(log2e / pSelect->sigmaR2 / fStrength); int rkcnr_uvgain2 = (int)(pSelect->uvgain2 / fStrength * (1 << RK_CNR_V1_uvgain)); int tmpBit = 10 + RK_CNR_V1_log2e + RK_CNR_V1_uvgain - 6; int sgmRatio = 1 << RK_CNR_V1_sgmRatio; int ky = sgmRatio * (1 << RK_CNR_V1_uvgain) >> RK_CNR_V1_sgmRatio; int kuv = sgmRatio * rkcnr_uvgain2 >> RK_CNR_V1_sgmRatio; ky = MIN2(ky, (1 << (4 + RK_CNR_V1_uvgain)) - 1); kuv = MIN2(kuv, (1 << (4 + RK_CNR_V1_uvgain)) - 1); tmp = ((rkcnr_sigmaR2 * ky + (1 << (tmpBit - 1))) >> tmpBit); pFix->cnr_lbf5_gain_y = CLIP(tmp, 0, 15); tmp = ((rkcnr_sigmaR2 * kuv + (1 << (tmpBit - 1))) >> tmpBit); pFix->cnr_lbf5_gain_c = CLIP(tmp, 0, 63); // ISP_CNR_2800_LBF5_WEITD0_3 // bilateral filter kernels for (int i = 0; i < 5; i++) { tmp = (int)(pSelect->kernel_5x5_table[i] * (1 << RK_CNR_V1_kernels)); pFix->cnr_lbf5_weit_d[i] = CLIP(tmp, 0, 128); } // ISP_CNR_2800_HMED3 tmp = (int)(pSelect->medRatio1 * (1 << RK_CNR_V1_medRatio)); pFix->cnr_hmed3_alpha = CLIP(tmp, 0, 16); // ISP_CNR_2800_HBF5 tmp = (int)(log2e / pSelect->sigmaR1 / fStrength); pFix->cnr_hbf5_sigma = CLIP(tmp, 0, (1 << 13) - 1); tmp = (int)(pSelect->bfRatio1 * (1 << RK_CNR_V1_bfRatio)); pFix->cnr_hbf5_weit_src = CLIP(tmp, 0, 128); tmp = pSelect->hbf_wgt_clip; pFix->cnr_hbf5_min_wgt = CLIP(tmp, 0, (1 << 8) - 1); // ISP_CNR_2800_LBF3 // step3 // bilateral filter tmp = (int)(log2e / pSelect->sigmaR3 / fStrength); pFix->cnr_lbf3_sigma = CLIP(tmp, 0, (1 << 13) - 1); tmp = (int)(pSelect->bfRatio3 * (1 << RK_CNR_V1_bfRatio)); pFix->cnr_lbf5_weit_src = CLIP(tmp, 0, 128); cnr_fix_printf_V1(pFix); LOGI_ANR("%s:(%d) exit \n", __FUNCTION__, __LINE__); return ACNR_RET_SUCCESS; } Acnr_result_t cnr_fix_printf_V1(RK_CNR_Fix_V1_t * pFix) { int i = 0; LOGI_ANR("%s:(%d) enter \n", __FUNCTION__, __LINE__); Acnr_result_t res = ACNR_RET_SUCCESS; if(pFix == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } //ISP_CNR_2800_CTRL (0x0000) LOGD_ANR("(0x0000) thumb_mix_cur_en:0x%x lq_bila_bypass:0x%x hq_bila_bypass:0x%x exgain_bypass:0x%x cnr_en_i:0x%x\n", pFix->cnr_thumb_mix_cur_en, pFix->cnr_lq_bila_bypass, pFix->cnr_hq_bila_bypass, pFix->cnr_exgain_bypass, pFix->cnr_en_i); // ISP_CNR_2800_EXGAIN (0x0004) LOGD_ANR("(0x0004) cnr_exgain_mux:0x%x \n", pFix->cnr_exgain_mux); // ISP_CNR_2800_GAIN_PARA (0x0008) LOGD_ANR("(0x0008) gain_iso:0x%x gain_offset:0x%x gain_1sigma:0x%x \n", pFix->cnr_gain_iso, pFix->cnr_gain_offset, pFix->cnr_gain_1sigma); // ISP_CNR_2800_GAIN_UV_PARA (0x000c) LOGD_ANR("(0x000c) gain_uvgain1:0x%x gain_uvgain0:0x%x \n", pFix->cnr_gain_uvgain1, pFix->cnr_gain_uvgain0); // ISP_CNR_2800_LMED3 (0x0010) LOGD_ANR("(0x0010) lmed3_alpha:0x%x \n", pFix->cnr_lmed3_alpha); // ISP_CNR_2800_LBF5_GAIN (0x0014) LOGD_ANR("(0x0014) lbf5_gain_y:0x%x lbf5_gain_c:0x%x \n", pFix->cnr_lbf5_gain_y, pFix->cnr_lbf5_gain_c); // ISP_CNR_2800_LBF5_WEITD0_4 (0x0018 - 0x001c) for(int i = 0; i < 5; i++) { LOGD_ANR("(0x0018 - 0x001c) lbf5_weit_d[%d]:0x%x \n", i, pFix->cnr_lbf5_weit_d[i]); } // ISP_CNR_2800_HMED3 (0x0020) LOGD_ANR("(0x0020) hmed3_alpha:0x%x \n", pFix->cnr_hmed3_alpha); // ISP_CNR_2800_HBF5 (0x0024) LOGD_ANR("(0x0024) hbf5_weit_src:0x%x hbf5_min_wgt:0x%x hbf5_sigma:0x%x \n", pFix->cnr_hbf5_weit_src, pFix->cnr_hbf5_min_wgt, pFix->cnr_hbf5_sigma); // ISP_CNR_2800_LBF3 (0x0028) LOGD_ANR("(0x0028) lbf5_weit_src:0x%x lbf3_sigma:0x%x \n", pFix->cnr_lbf5_weit_src, pFix->cnr_lbf3_sigma); LOGD_ANR("%s:(%d) exit \n", __FUNCTION__, __LINE__); return ACNR_RET_SUCCESS; } Acnr_result_t cnr_get_setting_by_name_json_V1(CalibDbV2_CNR_t *pCalibdbV2, char *name, int *tuning_idx) { int i = 0; Acnr_result_t res = ACNR_RET_SUCCESS; if(pCalibdbV2 == NULL || name == NULL || tuning_idx == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } for(i = 0; i < pCalibdbV2->TuningPara.Setting_len; i++) { if(strncmp(name, pCalibdbV2->TuningPara.Setting[i].SNR_Mode, strlen(name)*sizeof(char)) == 0) { break; } } if(i < pCalibdbV2->TuningPara.Setting_len) { *tuning_idx = i; } else { *tuning_idx = 0; } LOGD_ANR("%s:%d snr_name:%s snr_idx:%d i:%d \n", __FUNCTION__, __LINE__, name, *tuning_idx, i); return res; } Acnr_result_t cnr_init_params_json_V1(RK_CNR_Params_V1_t *pParams, CalibDbV2_CNR_t *pCalibdbV2, int tuning_idx) { Acnr_result_t res = ACNR_RET_SUCCESS; CalibDbV2_CNR_TuningPara_Setting_ISO_t *pTuningISO = NULL; if(pParams == NULL || pCalibdbV2 == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } pParams->enable = pCalibdbV2->TuningPara.enable; for(int i = 0; i < pCalibdbV2->TuningPara.Setting[tuning_idx].Tuning_ISO_len && i < RK_CNR_V1_MAX_ISO_NUM; i++ ) { pTuningISO = &pCalibdbV2->TuningPara.Setting[tuning_idx].Tuning_ISO[i]; pParams->iso[i] = pTuningISO->iso; pParams->rkcnr_hq_bila_bypass[i] = pTuningISO->hf_bypass; pParams->rkcnr_lq_bila_bypass[i] = pTuningISO->lf_bypass; pParams->rkcnr_exgain[i] = pTuningISO->cnr_exgain; pParams->rkcnr_g_gain[i] = pTuningISO->cnr_g_gain; pParams->ratio[i] = pTuningISO->color_sat_adj; pParams->offset[i] = pTuningISO->color_sat_adj_alpha; pParams->medRatio1[i] = pTuningISO->hf_spikes_reducion_strength; pParams->sigmaR1[i] = pTuningISO->hf_denoise_strength; pParams->uvgain1[i] = pTuningISO->hf_color_sat; pParams->bfRatio1[i] = pTuningISO->hf_denoise_alpha; pParams->hbf_wgt_clip[i] = pTuningISO->hf_bf_wgt_clip; pParams->medRatio2[i] = pTuningISO->thumb_spikes_reducion_strength; pParams->sigmaR2[i] = pTuningISO->thumb_denoise_strength; pParams->uvgain2[i] = pTuningISO->thumb_color_sat; pParams->sigmaR3[i] = pTuningISO->lf_denoise_strength; pParams->uvgain3[i] = pTuningISO->lf_color_sat; pParams->bfRatio3[i] = pTuningISO->lf_denoise_alpha; } memcpy(pParams->kernel_5x5_table, pCalibdbV2->TuningPara.Kernel_Coeff.kernel_5x5, sizeof(float) * 5); return ACNR_RET_SUCCESS; } Acnr_result_t cnr_config_setting_param_json_V1(RK_CNR_Params_V1_t *pParams, CalibDbV2_CNR_t *pCalibdbV2, char* param_mode, char * snr_name) { Acnr_result_t res = ACNR_RET_SUCCESS; int tuning_idx; if(pParams == NULL || pCalibdbV2 == NULL || param_mode == NULL || snr_name == NULL) { LOGE_ANR("%s(%d): null pointer\n", __FUNCTION__, __LINE__); return ACNR_RET_NULL_POINTER; } res = cnr_get_setting_by_name_json_V1(pCalibdbV2, snr_name, &tuning_idx); if(res != ACNR_RET_SUCCESS) { LOGW_ANR("%s(%d): error!!! can't find setting in iq files, use 0 instead\n", __FUNCTION__, __LINE__); } res = cnr_init_params_json_V1(pParams, pCalibdbV2, tuning_idx); pParams->enable = pCalibdbV2->TuningPara.enable; return res; } RKAIQ_END_DECLARE