#include "xm_type.h" #include "xm_comm_isp.h" #include "xm_comm_sns.h" #include "xm_sns_ctrl.h" #include "mpi_isp.h" #include "mpi_ae.h" #include "mpi_awb.h" #include "xm_awb_comm.h" #include "xm_print.h" #include "XAx_cmos.h" #define STATIC static extern GAIN_MODE_DT gstGainModeDt; extern const ISP_CMOS_GAMMA_S gstIspGamma; extern XM_VOID XM_MPI_ISP_Memset(XM_U8 *pu8Addr,XM_U8 u8Ch, XM_U32 u32Num); #define HD3MP_25P_LINES (1584) static const ISP_CMOS_AGC_TABLE_S g_stIspAgcTable = { /* bvalid */ 1, /* 100, 200, 400, 800, 1600, 3200, 6400, 12800; 100, 200, 400, 800, 1600, 3200, 6400, 12800 */ /* sharpen_D H */ {0x30,0x2E,0x28,0x20,0x1c,0x10,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04}, /* sharpen_Ud M */ {0x2E,0x2A,0x28,0x24,0x22,0x14,0x08,0x08,0x08,0x08,0x08,0x08,0x08,0x08,0x08,0x08}, /* sharpen_Kd */ {0x3E,0x3C,0x38,0x30,0x28,0x10,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04,0x04}, /* snr_thresh 2DNr */ {0x00,0x01,0x06,0x08,0x18,0x30,0x40,0x40,0x48,0x48,0x48,0x48,0x48,0x48,0x48,0x48}, /* snr_thresh 3DNr Tf */ {0x02,0x04,0x06,0x08,0x10,0x14,0x16,0x18,0x1C,0x1C,0x1C,0x1C,0x1C,0x1C,0x1C,0x1C}, /* snr_thresh 3DNr Sf */ {0x01,0x02,0x08,0x0c,0x12,0x28,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40}, /* DyDpc_thresh */ {0xB8,0xC0,0xD0,0xD4,0xD8,0xDC,0xE0,0xE0,0xF0,0xF0,0xF0,0xF0,0xF0,0xF0,0xF0,0xF0}, /* saturation_strength */ {0xA0,0xA0,0x9A,0x90,0x88,0x78,0x50,0x50,0x50,0x10,0x10,0x10,0x10,0x10,0x10,0x10}, /* Blc */ {0x46,0x46,0x46,0x46,0x46,0x44,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40}, /*Y_Tran gamma*/ {0x34,0x34,0x34,0x35,0x35,0x35,0x30,0x30,0x26,0x26,0x26,0x26,0x26,0x26,0x26,0x26}, }; static XM_S32 cmos_get_isp_default(ISP_CMOS_DEFAULT_S *pstDef) { if (XM_NULL == pstDef) { ERR("null pointer when get isp default value!\n"); return -1; } pstDef->stGamma.bValid = XM_TRUE; XM_MPI_ISP_Memncpy((XM_U8*)&pstDef->stGamma, (XM_U8*)&gstIspGamma, sizeof(ISP_CMOS_GAMMA_S)); XM_MPI_ISP_Memncpy((XM_U8 *)&pstDef->stAgcTbl, (XM_U8 *)&g_stIspAgcTable, sizeof(ISP_CMOS_AGC_TABLE_S)); return 0; } static XM_VOID cmos_set_pixel_detect(XM_BOOL bEnable) { return; } STATIC XM_S32 cmos_set_mirror_flip(XM_U8 u8Mirror,XM_U8 u8Flip) { XM_U32 u32Tmp1,u32Tmp2; XM_U16 u16OfstH,u16OfsV; u32Tmp1 = sensor_read_register(0x3221); u32Tmp2 = sensor_read_register(0x3220); u16OfstH = 0; u16OfsV = 0; if(u8Mirror) { u32Tmp1 |= 0x06; } else { u32Tmp1 &= ~0x06; } if(u8Flip) { u32Tmp2 |= 0x06; } else { u32Tmp2 &= ~0x06; } sensor_write_register(0x3221, u32Tmp1); sensor_write_register(0x3220, u32Tmp2); VI_WinSet(1, u8Mirror, u8Flip, u16OfstH, u16OfsV); return XM_SUCCESS; } STATIC XM_VOID cmos_again_calc_table(XM_U32 u32InTimes,AE_SENSOR_GAININFO_S *pstAeSnsGainInfo) { if(XM_NULL == pstAeSnsGainInfo) { ERR("null pointer when get ae sensor gain info value!\n"); return; } pstAeSnsGainInfo->u32GainDb = u32InTimes; pstAeSnsGainInfo->u32SnsTimes = u32InTimes; return; } STATIC XM_VOID cmos_dgain_calc_table(XM_U32 u32InTimes,AE_SENSOR_GAININFO_S *pstAeSnsGainInfo) { if(XM_NULL == pstAeSnsGainInfo) { ERR("null pointer when get ae sensor gain info value!\n"); return; } pstAeSnsGainInfo->u32GainDb = u32InTimes; pstAeSnsGainInfo->u32SnsTimes = u32InTimes; return; } static XM_S32 cmos_get_ae_default(AE_SENSOR_DEFAULT_S *pstAeSnsDft) { if (XM_NULL == pstAeSnsDft) { ERR("null pointer when get ae default value!\n"); return -1; } pstAeSnsDft->u32FullLinesStd = HD3MP_25P_LINES; pstAeSnsDft->u8AeCompensation = 0x39; pstAeSnsDft->u32LinesPer500ms = pstAeSnsDft->u32FullLinesStd*25/2; pstAeSnsDft->u32FlickerFreq = 0; pstAeSnsDft->u32MaxIntTime = pstAeSnsDft->u32FullLinesStd-4; pstAeSnsDft->u32MinIntTime = 2; pstAeSnsDft->u32MaxAgain = 1984;// 124 pstAeSnsDft->u32MinAgain = 16; pstAeSnsDft->u32MaxDgain = 32; pstAeSnsDft->u32MinDgain = 32; pstAeSnsDft->u32ISPDgainShift = 8; pstAeSnsDft->u32MaxISPDgain= 8 << pstAeSnsDft->u32ISPDgainShift; pstAeSnsDft->u32MinISPDgain= 1 << pstAeSnsDft->u32ISPDgainShift; pstAeSnsDft->bDelayCfg = XM_FALSE; return 0; } static XM_S32 cmos_get_sensor_max_resolution(ISP_CMOS_SENSOR_MAX_RESOLUTION *pstSensorMaxResolution) { if (XM_NULL == pstSensorMaxResolution) { ERR("null pointer when get sensor max resolution \n"); return -1; } pstSensorMaxResolution->u32MaxWidth = 2048; pstSensorMaxResolution->u32MaxHeight = 1536; return 0; } STATIC XM_VOID cmos_inttime_update(XM_U32 u32IntTime) { XM_U32 u32Tmp; if(gu32ShutNow == u32IntTime) return; gu32ShutNow = u32IntTime; u32Tmp = ((u32IntTime&0x0ff0)>>4); sensor_write_register(0x3e01, u32Tmp); sensor_write_register(0x3e02, ((u32IntTime&0xf)<<4)); return; } const static XM_U8 gau8Logic_sc3035[3][4] = { // 0x3630,0x3635,0x3620,0x3627 {0xa9, 0x66, 0xd2, 0x02}, {0x67, 0x64, 0xd2, 0x02}, {0x67, 0x62, 0x63, 0x06} }; const static XM_U16 gau16LogicAddr[4] = { 0x3630,0x3635,0x3620,0x3627 }; static void gainLogic_sc3035(XM_U32 u32AllGain) { static XM_U8 su8Idx = 0xFF;//[bit0~bit3]:Vstd [bit4~bit7]:Agc XM_U8 u8Idx2,u8i; u32AllGain = u32AllGain/64; // *1024->*16 if(u32AllGain<32) u8Idx2 = 0; else if(u32AllGain<256) u8Idx2 = 1; else u8Idx2 = 2; if( ((su8Idx>>4)&0x0F) != u8Idx2) { su8Idx = ((u8Idx2&0x0F)<<4); for(u8i=0; u8i<4; u8i ++) { sensor_write_register((XM_U32)gau16LogicAddr[u8i], (XM_U32)gau8Logic_sc3035[u8Idx2][u8i]); } } } STATIC XM_VOID cmos_gains_update(XM_U32 u32Again, XM_U32 u32Dgain) { static XM_U32 su32AGain = 0xFFFFFFF; static XM_U32 su32DGain = 0xFFFFFFF; XM_U32 u32AllGain; u32AllGain = u32Again; if((su32AGain != u32Again) || (su32DGain != u32Dgain)) { su32AGain = u32Again; su32DGain = u32Dgain; // 1. Logic gainLogic_sc3035(u32AllGain); // 2.GainUpdate sensor_write_register(0x3e08, (u32Again>>8)&0xFF); sensor_write_register(0x3e09, u32Again&0xFF); } return; } /* the function of sensor set fps */ STATIC XM_VOID cmos_fps_set(XM_U8 u8Fps, AE_SENSOR_DEFAULT_S *pstAeSnsDft) { XM_U32 u32Tmp; switch(u8Fps) { case 30: // Change the frame rate via changing the vertical blanking u32Tmp = 2500; break; case 25: default: // Change the frame rate via changing the vertical blanking u32Tmp = 3000; break; } if(pstAeSnsDft != NULL) { pstAeSnsDft->u32FullLinesStd = HD3MP_25P_LINES; pstAeSnsDft->u32MaxIntTime = pstAeSnsDft->u32FullLinesStd-gu8MaxShutterOfst; pstAeSnsDft->u32LinesPer500ms = pstAeSnsDft->u32FullLinesStd * u8Fps / 2; } u32Tmp = u32Tmp>>1; sensor_write_register(0x320c, (u32Tmp>>8)&0xFF); sensor_write_register(0x320d, u32Tmp&0xFF); return; } static XM_VOID cmos_slow_framerate_set(XM_U16 u16FullLines, AE_SENSOR_DEFAULT_S *pstAeSnsDft) { return ; static XM_U16 preU16FullLine = 0xffff; if(preU16FullLine == u16FullLines) return; preU16FullLine = u16FullLines; u16FullLines = (u16FullLines>=4096)?4000:u16FullLines; pstAeSnsDft->u32MaxIntTime = u16FullLines - gu8MaxShutterOfst; SysDelay_ms(100); if(gu32ShutNow>pstAeSnsDft->u32MaxIntTime) { cmos_inttime_update(pstAeSnsDft->u32MaxIntTime); } sensor_write_register(0x320e, (u16FullLines&0xff00)>>8); sensor_write_register(0x320f, u16FullLines&0xff); XM_MPI_MIPI_RefreshFV(0, (XM_U32)u16FullLines); } /**************************************************************************** * AWB ****************************************************************************/ static const ISP_COLORMATRIX_AUTO_S g_stAwbCcm = { 5000, { 0x000,356, -135, 35, 0x000,-59, 327, -12, 0x000, 5, -145, 396//0x000, -35, -130, 421 }, 4000, { 0x000,327, -130,59, 0x000,-70,281,45, 0x000,-39,-233,528 }, 2800, { 0x000, 287,-86,55, 0x000,-87,269,74, 0x000, -115,-369,740 } }; static const ISP_AWB_CALIBRATION_V2_S gstAwbCal = { {0, 0, 4096, 2602, 3773, 1836, 1107, 4096}, {4096, 3420, 0, 0, 3625, 2345, 4096, 1355}, {-1150, -4096, -1687, -4096, -4096, -4096, -2524, -2972}, 213, 0, 1908, 0, 3281, {0, 1073, 1314, 1642, 1752, 1900, 2145, 2166, 3281, 0, 0, 0, 0, 0, 0, 0}, {2000, 2150, 2800, 4000, 4150, 5000, 6500, 7500, 12000, 0, 0, 0, 0, 0, 0, 0}, {1386, 1024, 1400, 0} }; static XM_S32 cmos_get_awb_default(AWB_SENSOR_DEFAULT_S *pstAwbSnsDft) { if(XM_NULL == pstAwbSnsDft) { ERR("null pointer when get awb default value!\n"); return XM_FAILURE; } XM_MPI_ISP_Memset((XM_U8*)pstAwbSnsDft, 0, sizeof(AWB_SENSOR_DEFAULT_S)); pstAwbSnsDft->pstRbTable = (const AWB_COEF_TABLE_S*)(&gstAwbCal); // CCM XM_MPI_ISP_Memncpy((XM_U8*)&(pstAwbSnsDft->stCcm), (XM_U8*)&g_stAwbCcm, sizeof(ISP_COLORMATRIX_AUTO_S)); return XM_SUCCESS; } XM_S32 cmos_init_sensor_exp_function_sc3035(ISP_SENSOR_EXP_FUNC_S *pstSensorExpFunc) { // XM_MPI_ISP_Memset((char *)pstSensorExpFunc, 0, sizeof(ISP_SENSOR_EXP_FUNC_S)); pstSensorExpFunc->pfn_cmos_sensor_init = NULL; pstSensorExpFunc->pfn_cmos_get_isp_default = cmos_get_isp_default;//cmos_get_isp_default; pstSensorExpFunc->pfn_cmos_set_pixel_detect = cmos_set_pixel_detect; pstSensorExpFunc->pfn_cmos_get_sensor_max_resolution = cmos_get_sensor_max_resolution;//cmos_get_sensor_max_resolution; pstSensorExpFunc->pfn_cmos_set_mirror_flip = cmos_set_mirror_flip; return 0; } XM_S32 cmos_init_ae_exp_function_sc3035(AE_SENSOR_EXP_FUNC_S *pstExpFuncs) { // XM_MPI_ISP_Memset((char *)pstExpFuncs, 0, sizeof(AE_SENSOR_EXP_FUNC_S)); pstExpFuncs->pfn_cmos_fps_get = NULL; pstExpFuncs->pfn_cmos_get_ae_default = cmos_get_ae_default; pstExpFuncs->pfn_cmos_fps_set = cmos_fps_set; pstExpFuncs->pfn_cmos_slow_framerate_set= cmos_slow_framerate_set; pstExpFuncs->pfn_cmos_inttime_update = cmos_inttime_update; pstExpFuncs->pfn_cmos_gains_update = cmos_gains_update; pstExpFuncs->pfn_cmos_again_calc_table = cmos_again_calc_table; pstExpFuncs->pfn_cmos_dgain_calc_table = cmos_dgain_calc_table; pstExpFuncs->pfn_cmos_shut_calc_table = NULL; return 0; } XM_S32 cmos_init_awb_exp_function_sc3035(AWB_SENSOR_EXP_FUNC_S *pstExpFuncs) { XM_MPI_ISP_Memset((XM_U8*)pstExpFuncs, 0, sizeof(AWB_SENSOR_EXP_FUNC_S)); pstExpFuncs->pfn_cmos_get_awb_default = cmos_get_awb_default; return 0; }