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MStar hereby reserves the // rights to any and all damages, losses, costs and expenses resulting therefrom. // //////////////////////////////////////////////////////////////////////////////// //------------------------------------------------------------------------------------------------- // Include Files //------------------------------------------------------------------------------------------------- // Common Definition #ifdef MSOS_TYPE_LINUX_KERNEL #include #include #include "chip_setup.h" #include "include/mstar/mstar_chip.h" #else #include #endif #include "drvHVD_Common.h" // Internal Definition #include "drvHVD_def.h" #include "fwHVD_if.h" #include "halVPU_EX.h" #include "halHVD_EX.h" #include "regHVD_EX.h" //------------------------------------------------------------------------------------------------- // Driver Compiler Options //------------------------------------------------------------------------------------------------- #if (!defined(MSOS_TYPE_NUTTX) && !defined(MSOS_TYPE_OPTEE)) || defined(SUPPORT_X_MODEL_FEATURE) //------------------------------------------------------------------------------------------------- // Local Defines //------------------------------------------------------------------------------------------------- #define RV_VLC_TABLE_SIZE 0x20000 /* Add for Mobile Platform by Ted Sun */ //#define HVD_DISPQ_PREFETCH_COUNT 2 #define HVD_FW_MEM_OFFSET 0x100000UL // 1M #define VPU_QMEM_BASE 0x20000000UL //max support pixel(by chip capacity) #define HVD_HW_MAX_PIXEL (3840*2160*31000ULL) // 4kx2k@30p #define HEVC_HW_MAX_PIXEL (4096*2160*61000ULL) // 4kx2k@60p #define VP9_HW_MAX_PIXEL (4096*2304*31000ULL) // 4kx2k@30p #if 0 static HVD_AVC_VUI_DISP_INFO g_hvd_VUIINFO; static MS_U8 g_hvd_nal_fill_pair[2][8] = { {0, 0, 0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0, 0, 0} }; static MS_U32 u32RV_VLCTableAddr = 0; // offset from Frame buffer start address static MS_U16 _u16DispQPtr = 0; #endif #define IS_TASK_ALIVE(id) ((id) != -1) #ifndef UNUSED #define UNUSED(x) (void)(x) #endif //---------------------------------- Mutex settings ----------------------------------------- #if HAL_HVD_ENABLE_MUTEX_PROTECT #define _HAL_HVD_MutexCreate() \ do \ { \ if (s32HVDMutexID < 0) \ { \ s32HVDMutexID = OSAL_HVD_MutexCreate((MS_U8*)(_u8HVD_Mutex)); \ } \ } while (0) #define _HAL_HVD_MutexDelete() \ do \ { \ if (s32HVDMutexID >= 0) \ { \ OSAL_HVD_MutexDelete(s32HVDMutexID); \ s32HVDMutexID = -1; \ } \ } while (0) #define _HAL_HVD_Entry() \ do \ { \ if (s32HVDMutexID >= 0) \ { \ if (!OSAL_HVD_MutexObtain(s32HVDMutexID, OSAL_HVD_MUTEX_TIMEOUT)) \ { \ printf("[HAL HVD][%06d] Mutex taking timeout\n", __LINE__); \ } \ } \ } while (0) #define _HAL_HVD_Return(_ret_) \ do \ { \ if (s32HVDMutexID >= 0) \ { \ OSAL_HVD_MutexRelease(s32HVDMutexID); \ } \ return _ret_; \ } while(0) #define _HAL_HVD_Release() \ do \ { \ if (s32HVDMutexID >= 0) \ { \ OSAL_HVD_MutexRelease(s32HVDMutexID); \ } \ } while (0) #else // HAL_HVD_ENABLE_MUTEX_PROTECT #define _HAL_HVD_MutexCreate() #define _HAL_HVD_MutexDelete() #define _HAL_HVD_Entry() #define _HAL_HVD_Return(_ret) {return _ret;} #define _HAL_HVD_Release() #endif // HAL_HVD_ENABLE_MUTEX_PROTECT #define INC_VALUE(value, queue_sz) { (value) = ((++(value)) >= queue_sz) ? 0 : (value); } #define IS_TASK_ALIVE(id) ((id) != -1) #define NEXT_MULTIPLE(value, n) (((value) + (n) - 1) & ~((n)-1)) //------------------------------ MIU SETTINGS ---------------------------------- #define _MaskMiuReq_MVD_RW_0( m ) _HVD_WriteRegBit(MIU0_REG_RQ2_MASK, m, BIT(4)) #define _MaskMiuReq_MVD_RW_1( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(6)) #define _MaskMiuReq_MVD_BBU_R( m ) _HVD_WriteRegBit(MIU0_REG_RQ0_MASK+1, m, BIT(4)) #define _MaskMiuReq_HVD_RW_MIF0( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(2)) #define _MaskMiuReq_HVD_RW_MIF1( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(3)) #define _MaskMiuReq_HVD_BBU_R( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(0)) #define _MaskMiu1Req_MVD_RW_0( m ) _HVD_WriteRegBit(MIU1_REG_RQ2_MASK, m, BIT(4)) #define _MaskMiu1Req_MVD_RW_1( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(6)) #define _MaskMiu1Req_MVD_BBU_R( m ) _HVD_WriteRegBit(MIU1_REG_RQ0_MASK+1, m, BIT(4)) #define _MaskMiu1Req_HVD_RW_MIF0( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(2)) #define _MaskMiu1Req_HVD_RW_MIF1( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(3)) #define _MaskMiu1Req_HVD_BBU_R( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(0)) #define HVD_MVD_RW_0_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL2) & BIT(4)) == 0) #define HVD_MVD_RW_1_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(6)) == 0) #define HVD_MVD_BBU_R_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL0) & BIT(12)) == 0) #define HVD_HVD_RW_MIF0_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(2)) == 0) #define HVD_HVD_RW_MIF1_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(3)) == 0) #define HVD_HVD_BBU_R_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(0)) == 0) #define HVD_MVD_RW_0_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL2) & BIT(4)) == BIT(4)) #define HVD_MVD_RW_1_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(6)) == BIT(6)) #define HVD_MVD_BBU_R_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL0) & BIT(12)) == BIT(12)) #define HVD_HVD_RW_MIF0_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(2)) == BIT(2)) #define HVD_HVD_RW_MIF1_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(3)) == BIT(3)) #define HVD_HVD_BBU_R_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(0)) == BIT(0)) #if SUPPORT_EVD #define _MaskMiuReq_EVD_RW( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(4)) #define _MaskMiuReq_EVD_BBU_R( m ) _HVD_WriteRegBit(MIU0_REG_RQ4_MASK, m, BIT(4)) #define _MaskMiu1Req_EVD_RW( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(4)) #define _MaskMiu1Req_EVD_BBU_R( m ) _HVD_WriteRegBit(MIU1_REG_RQ4_MASK, m, BIT(4)) #define HVD_EVD_RW_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(4)) == 0) #define HVD_EVD_BBU_R_ON_MIU0 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(4)) == 0) #define HVD_EVD_RW_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(4)) == BIT(4)) #define HVD_EVD_BBU_R_ON_MIU1 ((_HVD_Read2Byte(MIU0_REG_SEL4) & BIT(4)) == BIT(4)) #endif #define _HVD_MIU_SetReqMask(miu_clients, mask) \ do \ { \ if (HVD_##miu_clients##_ON_MIU0 == 1) \ { \ _MaskMiuReq_##miu_clients(mask); \ } \ else \ { \ if (HVD_##miu_clients##_ON_MIU1 == 1) \ { \ _MaskMiu1Req_##miu_clients(mask); \ } \ } \ } while (0) // check RM is supported or not #define HVD_HW_RUBBER3 (HAL_HVD_EX_GetHWVersionID()& BIT(14)) #ifdef VDEC3 #define HAL_HVD_EX_MAX_SUPPORT_STREAM 16 #else #define HAL_HVD_EX_MAX_SUPPORT_STREAM 3 #endif #define DIFF(a, b) (a > b ? (a-b) : (b-a)) // abs diff //------------------------------------------------------------------------------------------------- // Local Structures //------------------------------------------------------------------------------------------------- //------------------------------------------------------------------------------------------------- // Local Functions Prototype //------------------------------------------------------------------------------------------------- static MS_U16 _HVD_EX_GetBBUReadptr(MS_U32 u32Id); static void _HVD_EX_SetBBUWriteptr(MS_U32 u32Id, MS_U16 u16BBUNewWptr); static MS_BOOL _HVD_EX_MBoxSend(MS_U32 u32Id, MS_U8 u8MBox, MS_U32 u32Msg); static MS_BOOL _HVD_EX_MBoxReady(MS_U32 u32Id, MS_U8 u8MBox); static MS_BOOL _HVD_EX_MBoxRead(MS_U32 u32Id, MS_U8 u8MBox, MS_U32 *u32Msg); //static void _HVD_EX_MBoxClear(MS_U8 u8MBox); static MS_U32 _HVD_EX_GetPC(void); static MS_U32 _HVD_EX_GetESWritePtr(MS_U32 u32Id); static MS_U32 _HVD_EX_GetESReadPtr(MS_U32 u32Id, MS_BOOL bDbug); static MS_BOOL _HVD_EX_SetCMDArg(MS_U32 u32Id, MS_U32 u32Arg); static MS_BOOL _HVD_EX_SetCMD(MS_U32 u32Id, MS_U32 u32Cmd); static HVD_Return _HVD_EX_SendCmd(MS_U32 u32Id, MS_U32 u32Cmd, MS_U32 u32CmdArg); static void _HVD_EX_SetMIUProtectMask(MS_BOOL bEnable); static void _HVD_EX_SetBufferAddr(MS_U32 u32Id); static MS_U32 _HVD_EX_GetESLevel(MS_U32 u32Id); static MS_U32 _HVD_EX_GetESQuantity(MS_U32 u32Id); static HVD_Return _HVD_EX_UpdatePTSTable(MS_U32 u32Id, HVD_BBU_Info *pInfo); static HVD_Return _HVD_EX_UpdateESWptr(MS_U32 u32Id, MS_U32 u32NalOffset, MS_U32 u32NalLen); static HVD_Return _HVD_EX_UpdateESWptr_VP8(MS_U32 u32Id, MS_U32 u32NalOffset, MS_U32 u32NalLen, MS_U32 u32NalOffset2, MS_U32 u32NalLen2); static MS_VIRT _HVD_EX_GetVUIDispInfo(MS_U32 u32Id); static MS_U32 _HVD_EX_GetBBUQNumb(MS_U32 u32Id); static MS_U32 _HVD_EX_GetPTSQNumb(MS_U32 u32Id); static HVD_EX_Drv_Ctrl *_HVD_EX_GetDrvCtrl(MS_U32 u32Id); static HVD_Frm_Information *_HVD_EX_GetNextDispFrame(MS_U32 u32Id); static void HAL_HVD_EX_VP8AECInUsed(MS_U32 u32Id, MS_BOOL *isVP8Used, MS_BOOL *isAECUsed, MS_BOOL *isAVCUsed); static void HAL_AEC_PowerCtrl(MS_BOOL bEnable); static void HAL_VP8_PowerCtrl(MS_BOOL bEnable); #if SUPPORT_EVD static void HAL_EVD_EX_PowerCtrl(MS_U32 u32Id, MS_BOOL bEnable); #endif #if SUPPORT_G2VP9 && defined(VDEC3) static void HAL_VP9_EX_PowerCtrl(MS_BOOL bEnable); #endif static MS_U64 _HAL_EX_GetHwMaxPixel(MS_U32 u32Id); #if SUPPORT_G2VP9 && defined(VDEC3) static MS_BOOL _HAL_HVD_EX_PostProc_Task(MS_U32 u32Id); #endif //------------------------------------------------------------------------------------------------- // Global Variables //------------------------------------------------------------------------------------------------- #if defined (__aeon__) static MS_VIRT u32HVDRegOSBase = 0xA0200000; #else static MS_VIRT u32HVDRegOSBase = 0xBF200000; #endif #if HAL_HVD_ENABLE_MUTEX_PROTECT MS_S32 s32HVDMutexID = -1; MS_U8 _u8HVD_Mutex[] = { "HVD_Mutex" }; #endif #define HVD_EX_STACK_SIZE 4096 //------------------------------------------------------------------------------------------------- // Local Variables //------------------------------------------------------------------------------------------------- typedef struct { HVD_AVC_VUI_DISP_INFO g_hvd_VUIINFO; MS_U8 g_hvd_nal_fill_pair[2][8]; MS_VIRT u32RV_VLCTableAddr; // offset from Frame buffer start address MS_U16 _u16DispQPtr; MS_U16 _u16DispOutSideQPtr[HAL_HVD_EX_MAX_SUPPORT_STREAM]; //HVD_EX_Drv_Ctrl *_pHVDCtrls; MS_U32 u32HVDCmdTimeout;//same as HVD_FW_CMD_TIMEOUT_DEFAULT MS_U32 u32VPUClockType; MS_U32 u32HVDClockType;//160 #if SUPPORT_EVD MS_U32 u32EVDClockType; #endif #if SUPPORT_G2VP9 && defined(VDEC3) MS_U32 u32VP9ClockType; #endif HVD_EX_Stream _stHVDStream[HAL_HVD_EX_MAX_SUPPORT_STREAM]; volatile HVD_Frm_Information *pHvdFrm;//_HVD_EX_GetNextDispFrame() MS_BOOL g_RstFlag; MS_U64 u64pts_real; MS_PHY u32VP8BBUWptr; MS_PHY u32EVDBBUWptr; MS_BOOL bBBU_running[HAL_HVD_EX_MAX_SUPPORT_STREAM]; MS_U32 u32BBUReadEsPtr[HAL_HVD_EX_MAX_SUPPORT_STREAM]; MS_S32 _s32VDEC_BBU_TaskId[HAL_HVD_EX_MAX_SUPPORT_STREAM]; MS_U8 u8VdecExBBUStack[HAL_HVD_EX_MAX_SUPPORT_STREAM][HVD_EX_STACK_SIZE]; //pre_set HVD_Pre_Ctrl *pHVDPreCtrl_Hal[HAL_HVD_EX_MAX_SUPPORT_STREAM]; } HVD_Hal_CTX; HVD_Hal_CTX* pHVDHalContext = NULL; HVD_Hal_CTX gHVDHalContext; HVD_EX_Drv_Ctrl *_pHVDCtrls = NULL; static HVD_EX_PreSet _stHVDPreSet[HAL_HVD_EX_MAX_SUPPORT_STREAM] = { {FALSE}, {FALSE}, {FALSE}, #ifdef VDEC3 {FALSE}, #endif }; //------------------------------------------------------------------------------------------------- // Debug Functions //------------------------------------------------------------------------------------------------- void HVD_EX_SetRstFlag(MS_BOOL bRst) { pHVDHalContext->g_RstFlag = bRst; } MS_BOOL HVD_EX_GetRstFlag(void) { return pHVDHalContext->g_RstFlag; } //------------------------------------------------------------------------------------------------- // Local Functions //------------------------------------------------------------------------------------------------- #ifdef VDEC3 static MS_BOOL _HAL_EX_IS_EVD(MS_U32 u32ModeFlag) { MS_U32 u32CodecType = u32ModeFlag & E_HVD_INIT_HW_MASK; if (u32CodecType == E_HVD_INIT_HW_HEVC || u32CodecType == E_HVD_INIT_HW_HEVC_DV #if SUPPORT_MSVP9 || u32CodecType == E_HVD_INIT_HW_VP9 #endif ) return TRUE; return FALSE; } static MS_BOOL _HAL_EX_BBU_VP8_InUsed(void) { if (!pHVDHalContext) return FALSE; MS_U32 i; MS_BOOL bRet = FALSE; for (i = 0; i < HAL_HVD_EX_MAX_SUPPORT_STREAM; i++) { if (pHVDHalContext->_stHVDStream[i].bUsed && pHVDHalContext->_stHVDStream[i].u32CodecType == E_HAL_HVD_VP8) { bRet = TRUE; break; } } return bRet; } // This function will get decoder type not only MVD,HVD,EVD but more codec types. // However, sometimes we don't use so deterministic infomation. static MS_BOOL HAL_HVD_EX_GetTaskInfo(MS_U32 u32Id, VPU_EX_TaskInfo* pstTaskInfo) { MS_U32 ret = TRUE; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if(pCtrl == NULL || pstTaskInfo == NULL) return FALSE; pstTaskInfo->u32Id = u32Id; switch(pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) { case E_HVD_INIT_HW_RM: pstTaskInfo->eDecType = E_VPU_EX_DECODER_RVD; break; case E_HVD_INIT_HW_VP8: pstTaskInfo->eDecType = E_VPU_EX_DECODER_VP8; break; case E_HVD_INIT_HW_MVC: pstTaskInfo->eDecType = E_VPU_EX_DECODER_HVD; //E_VPU_EX_DECODER_MVC; break; case E_HVD_INIT_HW_HEVC: case E_HVD_INIT_HW_HEVC_DV: pstTaskInfo->eDecType = E_VPU_EX_DECODER_EVD; break; #if SUPPORT_MSVP9 case E_HVD_INIT_HW_VP9: pstTaskInfo->eDecType = E_VPU_EX_DECODER_EVD; break; #endif #if SUPPORT_G2VP9 case E_HVD_INIT_HW_VP9: pstTaskInfo->eDecType = E_VPU_EX_DECODER_G2VP9; break; #endif default: pstTaskInfo->eDecType = E_VPU_EX_DECODER_HVD; break; } pstTaskInfo->eVpuId = (HAL_VPU_StreamId) (0xFF & u32Id); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { pstTaskInfo->eSrcType = E_VPU_EX_INPUT_FILE; } else { pstTaskInfo->eSrcType = E_VPU_EX_INPUT_TSP; } pstTaskInfo->u32HeapSize = HVD_DRAM_SIZE; #ifdef SUPPORT_EVD if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC || (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP9) pstTaskInfo->u32HeapSize = EVD_DRAM_SIZE; #endif return ret; } MS_U32 HAL_HVD_EX_GetBBUId(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U32 ret = HAL_HVD_INVALID_BBU_ID; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); _HAL_HVD_Entry(); if(pCtrl == NULL) _HAL_HVD_Return(ret); VPU_EX_TaskInfo taskInfo; memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); HAL_HVD_EX_GetTaskInfo(u32Id,&taskInfo); taskInfo.u8HalId = u8Idx; ret = HAL_VPU_EX_GetBBUId(u32Id, &taskInfo, pCtrl->bShareBBU); HVD_EX_MSG_DBG("u32Id=0x%x eDecType=0x%x eSrcType=0x%x ret=0x%x\n", (unsigned int)taskInfo.u32Id, (unsigned int)taskInfo.eDecType, (unsigned int)taskInfo.eSrcType, (unsigned int)ret); _HAL_HVD_Return(ret); } MS_BOOL HAL_HVD_EX_FreeBBUId(MS_U32 u32Id, MS_U32 u32BBUId) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL ret = FALSE; _HAL_HVD_Entry(); if(pCtrl == NULL) _HAL_HVD_Return(ret); VPU_EX_TaskInfo taskInfo; memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); HAL_HVD_EX_GetTaskInfo(u32Id,&taskInfo); ret = HAL_VPU_EX_FreeBBUId(u32Id,u32BBUId,&taskInfo); HVD_EX_MSG_DBG("u32Id=0x%x eDecType=0x%x eSrcType=0x%x ret=0x%x\n", (unsigned int)taskInfo.u32Id, (unsigned int)taskInfo.eDecType, (unsigned int)taskInfo.eSrcType, (unsigned int)ret); _HAL_HVD_Return(ret); } MS_BOOL HAL_HVD_EX_ClearBBUSetting(MS_U32 u32Id, MS_U32 u32BBUId) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL ret = FALSE; _HAL_HVD_Entry(); if(pCtrl == NULL) _HAL_HVD_Return(ret); VPU_EX_TaskInfo taskInfo; memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); HAL_HVD_EX_GetTaskInfo(u32Id,&taskInfo); HAL_VPU_EX_ClearBBUSetting(u32Id, u32BBUId, taskInfo.eDecType); _HAL_HVD_Return(TRUE); } #endif static void _HVD_EX_PpTask_Delete(HVD_EX_Stream *pstHVDStream) { pstHVDStream->ePpTaskState = E_HAL_HVD_STATE_STOP; MsOS_DeleteTask(pstHVDStream->s32HvdPpTaskId); pstHVDStream->s32HvdPpTaskId = -1; } static void _HVD_EX_Context_Init_HAL(void) { pHVDHalContext->u32HVDCmdTimeout = 100;//same as HVD_FW_CMD_TIMEOUT_DEFAULT pHVDHalContext->u32VPUClockType = 432; pHVDHalContext->u32HVDClockType = 384; #if SUPPORT_EVD pHVDHalContext->u32EVDClockType = 576; #endif #if SUPPORT_G2VP9 && defined(VDEC3) pHVDHalContext->u32VP9ClockType = 384; #endif #ifdef VDEC3 MS_U8 i; for (i = 0; i < HAL_HVD_EX_MAX_SUPPORT_STREAM; i++) { pHVDHalContext->_stHVDStream[i].eStreamId = E_HAL_HVD_N_STREAM0 + i; pHVDHalContext->_stHVDStream[i].ePpTaskState = E_HAL_HVD_STATE_STOP; pHVDHalContext->_stHVDStream[i].s32HvdPpTaskId = -1; } #else pHVDHalContext->_stHVDStream[0].eStreamId = E_HAL_HVD_MAIN_STREAM0; pHVDHalContext->_stHVDStream[1].eStreamId = E_HAL_HVD_SUB_STREAM0; pHVDHalContext->_stHVDStream[2].eStreamId = E_HAL_HVD_SUB_STREAM1; #endif } static MS_U16 _HVD_EX_GetBBUReadptr(MS_U32 u32Id) { MS_U16 u16Ret = 0; #if (HVD_ENABLE_MVC || (!VDEC3)) MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); #if HVD_ENABLE_MVC if(HAL_HVD_EX_CheckMVCID(u32Id)) { u8TaskId = (MS_U8) HAL_HVD_EX_GetView(u32Id); } #endif /// HVD_ENABLE_MVC _HVD_WriteWordMask(HVD_REG_POLL_NAL_RPTR(u32RB), 0, HVD_REG_POLL_NAL_RPTR_BIT); _HVD_WriteWordMask(HVD_REG_POLL_NAL_RPTR(u32RB), HVD_REG_POLL_NAL_RPTR_BIT, HVD_REG_POLL_NAL_RPTR_BIT); if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) // VP8 { u16Ret = _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI_BS4); u16Ret = _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI_BS3); } else #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { //if(pCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) u16Ret = pShm->u32ColocateBBUReadPtr; else u16Ret = _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI(u32RB)); } else { //if(pCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) u16Ret = pShm->u32ColocateBBUReadPtr; else u16Ret = _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI_BS2(u32RB)); } HVD_EX_MSG_DBG("Task0=%d, Task1=%d\n", _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI(u32RB)), _HVD_Read2Byte(HVD_REG_NAL_RPTR_HI_BS2(u32RB))); return u16Ret; } static MS_U16 _HVD_EX_GetBBUWritedptr(MS_U32 u32Id) { MS_U16 u16Ret = 0; #if (HVD_ENABLE_MVC || (!VDEC3)) MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pDrvCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); #if HVD_ENABLE_MVC if (HAL_HVD_EX_CheckMVCID(u32Id)) { u8TaskId = (MS_U8) HAL_HVD_EX_GetView(u32Id); } #endif /// HVD_ENABLE_MVC _HVD_WriteWordMask(HVD_REG_POLL_NAL_RPTR(u32RB), 0, HVD_REG_POLL_NAL_RPTR_BIT); _HVD_WriteWordMask(HVD_REG_POLL_NAL_RPTR(u32RB), HVD_REG_POLL_NAL_RPTR_BIT, HVD_REG_POLL_NAL_RPTR_BIT); if ((pDrvCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP8) // VP8 { u16Ret = _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI_BS4); u16Ret = _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI_BS3); } else #ifdef VDEC3 if (0 == pDrvCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { //if(pDrvCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) u16Ret = pShm->u32ColocateBBUWritePtr; else u16Ret = _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI(u32RB)); } else { //if(pDrvCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) u16Ret = pShm->u32ColocateBBUWritePtr; else u16Ret = _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI_BS2(u32RB)); } return u16Ret; } static void _HVD_EX_ResetMainSubBBUWptr(MS_U32 u32Id) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI(u32RB), 0); _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_NAL_WPTR_SYNC, HVD_REG_NAL_WPTR_SYNC); // set bit 3 _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI_BS2(u32RB), 0); _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_NAL_WPTR_SYNC, HVD_REG_NAL_WPTR_SYNC); // set bit 3 _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI_BS3, 0); _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_NAL_WPTR_SYNC, HVD_REG_NAL_WPTR_SYNC); // set bit 3 _HVD_Write2Byte(HVD_REG_NAL_RPTR_HI_BS4, 0); _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_NAL_WPTR_SYNC, HVD_REG_NAL_WPTR_SYNC); // set bit 3 } static void _HVD_EX_SetBBUWriteptr(MS_U32 u32Id, MS_U16 u16BBUNewWptr) { #if (HVD_ENABLE_MVC || (!VDEC3)) MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); #if HVD_ENABLE_MVC if (HAL_HVD_EX_CheckMVCID(u32Id)) { u8TaskId = (MS_U8) HAL_HVD_EX_GetView(u32Id); } #endif /// HVD_ENABLE_MVC if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) // VP8 { _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI_BS3, u16BBUNewWptr); _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI_BS4, u16BBUNewWptr); } else #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI(u32RB), u16BBUNewWptr); //if(pCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) pShm->u32ColocateBBUWritePtr = u16BBUNewWptr; } else { _HVD_Write2Byte(HVD_REG_NAL_WPTR_HI_BS2(u32RB), u16BBUNewWptr); //if(pCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) pShm->u32ColocateBBUWritePtr = u16BBUNewWptr; } HVD_EX_MSG_DBG("Task0=%d, Task1=%d\n", _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI(u32RB)), _HVD_Read2Byte(HVD_REG_NAL_WPTR_HI_BS2(u32RB))); _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_NAL_WPTR_SYNC, HVD_REG_NAL_WPTR_SYNC); // set bit 3 } static MS_BOOL _HVD_EX_MBoxSend(MS_U32 u32Id, MS_U8 u8MBox, MS_U32 u32Msg) { MS_BOOL bResult = TRUE; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; switch (u8MBox) { case E_HVD_HI_0: { _HVD_Write4Byte(HVD_REG_HI_MBOX0_L(u32RB), u32Msg); _HVD_WriteWordMask(HVD_REG_HI_MBOX_SET(u32RB), HVD_REG_HI_MBOX0_SET, HVD_REG_HI_MBOX0_SET); break; } case E_HVD_HI_1: { _HVD_Write4Byte(HVD_REG_HI_MBOX1_L(u32RB), u32Msg); _HVD_WriteWordMask(HVD_REG_HI_MBOX_SET(u32RB), HVD_REG_HI_MBOX1_SET, HVD_REG_HI_MBOX1_SET); break; } case E_HVD_VPU_HI_0: { bResult = HAL_VPU_EX_MBoxSend(VPU_HI_MBOX0, u32Msg); break; } case E_HVD_VPU_HI_1: { bResult = HAL_VPU_EX_MBoxSend(VPU_HI_MBOX1, u32Msg); break; } default: { bResult = FALSE; break; } } return bResult; } static MS_BOOL _HVD_EX_MBoxReady(MS_U32 u32Id, MS_U8 u8MBox) { MS_BOOL bResult = TRUE; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; switch (u8MBox) { case E_HVD_HI_0: bResult = _HVD_ReadWordBit(HVD_REG_HI_MBOX_RDY(u32RB), HVD_REG_HI_MBOX0_RDY) ? FALSE : TRUE; break; case E_HVD_HI_1: bResult = _HVD_ReadWordBit(HVD_REG_HI_MBOX_RDY(u32RB), HVD_REG_HI_MBOX1_RDY) ? FALSE : TRUE; break; case E_HVD_RISC_0: bResult = _HVD_ReadWordBit(HVD_REG_RISC_MBOX_RDY(u32RB), HVD_REG_RISC_MBOX0_RDY) ? TRUE : FALSE; break; case E_HVD_RISC_1: bResult = _HVD_ReadWordBit(HVD_REG_RISC_MBOX_RDY(u32RB), HVD_REG_RISC_MBOX1_RDY) ? TRUE : FALSE; break; case E_HVD_VPU_HI_0: bResult = HAL_VPU_EX_MBoxRdy(VPU_HI_MBOX0); break; case E_HVD_VPU_HI_1: bResult = HAL_VPU_EX_MBoxRdy(VPU_HI_MBOX1); break; case E_HVD_VPU_RISC_0: bResult = HAL_VPU_EX_MBoxRdy(VPU_RISC_MBOX0); break; case E_HVD_VPU_RISC_1: bResult = HAL_VPU_EX_MBoxRdy(VPU_RISC_MBOX1); break; default: break; } return bResult; } static MS_BOOL _HVD_EX_MBoxRead(MS_U32 u32Id, MS_U8 u8MBox, MS_U32 *u32Msg) { MS_BOOL bResult = TRUE; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; switch (u8MBox) { case E_HVD_HI_0: { *u32Msg = _HVD_Read4Byte(HVD_REG_HI_MBOX0_L(u32RB)); break; } case E_HVD_HI_1: { *u32Msg = _HVD_Read4Byte(HVD_REG_HI_MBOX1_L(u32RB)); break; } case E_HVD_RISC_0: { *u32Msg = _HVD_Read4Byte(HVD_REG_RISC_MBOX0_L(u32RB)); break; } case E_HVD_RISC_1: { *u32Msg = _HVD_Read4Byte(HVD_REG_RISC_MBOX1_L(u32RB)); break; } case E_HVD_VPU_RISC_0: { bResult = HAL_VPU_EX_MBoxRead(VPU_RISC_MBOX0, u32Msg); break; } case E_HVD_VPU_RISC_1: { bResult = HAL_VPU_EX_MBoxRead(VPU_RISC_MBOX1, u32Msg); break; } default: { bResult = FALSE; break; } } return bResult; } #if 0 static void _HVD_EX_MBoxClear(MS_U8 u8MBox) { switch (u8MBox) { case E_HVD_RISC_0: _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR, HVD_REG_RISC_MBOX0_CLR, HVD_REG_RISC_MBOX0_CLR); break; case E_HVD_RISC_1: _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR, HVD_REG_RISC_MBOX1_CLR, HVD_REG_RISC_MBOX1_CLR); break; case E_HVD_VPU_RISC_0: HAL_VPU_EX_MBoxClear(VPU_RISC_MBOX0); break; case E_HVD_VPU_RISC_1: HAL_VPU_EX_MBoxClear(VPU_RISC_MBOX1); break; default: break; } } #endif static MS_U32 _HVD_EX_GetPC(void) { MS_U32 u32PC = 0; u32PC = HAL_VPU_EX_GetProgCnt(); // HVD_MSG_DBG("pc0 =0x%lx\n",u32PC); return u32PC; } static MS_U32 _HVD_EX_GetESWritePtr(MS_U32 u32Id) { MS_U32 u32Data = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { u32Data = pCtrl->LastNal.u32NalAddr + pCtrl->LastNal.u32NalSize; if (u32Data > pCtrl->MemMap.u32BitstreamBufSize) { u32Data -= pCtrl->MemMap.u32BitstreamBufSize; HVD_EX_MSG_ERR("app should not put this kind of packet\n"); } } else { #if HVD_ENABLE_MVC MS_U8 u8ViewIdx = 0; if(HAL_HVD_EX_CheckMVCID(u32Id)) { u8ViewIdx = (MS_U8) HAL_HVD_EX_GetView(u32Id); } if(u8ViewIdx != 0) /// 2nd ES ptr. { u32Data = pShm->u32ES2WritePtr; } else { u32Data = pShm->u32ESWritePtr; } #else u32Data = pShm->u32ESWritePtr; #endif } return u32Data; } #define NAL_UNIT_LEN_BITS 21 #define NAL_UNIT_OFT_BITS 30 #define NAL_UNIT_OFT_LOW_BITS (32-NAL_UNIT_LEN_BITS) #define NAL_UNIT_OFT_HIGH_BITS (NAL_UNIT_OFT_BITS-NAL_UNIT_OFT_LOW_BITS) #define NAL_UNIT_OFT_LOW_MASK (((unsigned int)0xFFFFFFFF)>>(32-NAL_UNIT_OFT_LOW_BITS)) static MS_U32 _HVD_EX_GetESReadPtr(MS_U32 u32Id, MS_BOOL bDbug) { MS_U32 u32Data = 0; MS_U8 u8TaskId = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; MS_PHY u32VP8_BBU_DRAM_ST_ADDR_BS3 = pShm->u32HVD_BBU_DRAM_ST_ADDR; u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #if HVD_ENABLE_MVC if(HAL_HVD_EX_CheckMVCID(u32Id)) { u8TaskId = (MS_U8) HAL_HVD_EX_GetView(u32Id); } #endif /// HVD_ENABLE_MVC if (((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) || (TRUE == bDbug)) { if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP8) { // MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U16 u16ReadPtr = _HVD_EX_GetBBUReadptr(u32Id); MS_U16 u16WritePtr = _HVD_EX_GetBBUWritedptr(u32Id); MS_U32 *u32Adr; MS_U32 u32Tmp; if (u16ReadPtr == u16WritePtr) { u32Data = _HVD_EX_GetESWritePtr(u32Id); } else { if (u16ReadPtr) u16ReadPtr--; else u16ReadPtr = VP8_BBU_DRAM_TBL_ENTRY - 1; u32Adr = (MS_U32 *)(MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32VP8_BBU_DRAM_ST_ADDR_BS3 + (u16ReadPtr << 3))); u32Data = (*u32Adr) >> NAL_UNIT_LEN_BITS; u32Tmp = (*(u32Adr+1)) & (0xffffffff>>(32-(NAL_UNIT_OFT_BITS-(32-NAL_UNIT_LEN_BITS)))); u32Tmp = u32Tmp << (32-NAL_UNIT_LEN_BITS); u32Data = u32Data | u32Tmp; //printf("[VP8] GetESRptr (%x,%x,%x,%x,%d,%d)\n", u32Adr, (*u32Adr), (*(u32Adr+1)) , u32Data, u16ReadPtr, u16WritePtr); //while(1); } goto EXIT; } // set reg_poll_nal_rptr 0 _HVD_WriteWordMask(HVD_REG_ESB_RPTR(u32RB), 0, HVD_REG_ESB_RPTR_POLL); // set reg_poll_nal_rptr 1 _HVD_WriteWordMask(HVD_REG_ESB_RPTR(u32RB), HVD_REG_ESB_RPTR_POLL, HVD_REG_ESB_RPTR_POLL); // read reg_nal_rptr_hi #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { u32Data = _HVD_Read2Byte(HVD_REG_ESB_RPTR(u32RB)) & 0xFFC0; u32Data >>= 6; u32Data |= _HVD_Read2Byte(HVD_REG_ESB_RPTR_H(u32RB)) << 10; } else { u32Data = _HVD_Read2Byte(HVD_REG_ESB_RPTR_L_BS2(u32RB)) & 0xFFC0; u32Data >>= 6; u32Data |= _HVD_Read2Byte(HVD_REG_ESB_RPTR_H_BS2(u32RB)) << 10; } u32Data <<= 3; // unit if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { MS_U32 u32ESWptr = _HVD_EX_GetESWritePtr(u32Id); if ((pCtrl->u32LastESRptr < u32ESWptr) && (u32Data > u32ESWptr)) { //HVD_MSG_INFO("HVD Warn: ESRptr(%lx %lx) is running over ESWptr(%lx)\n" , u32Data , pCtrl->u32LastESRptr, u32ESWptr ); u32Data = u32ESWptr; } else if ((pCtrl->u32LastESRptr == u32ESWptr) && (u32Data > u32ESWptr)) { //HVD_MSG_INFO("HVD Warn: ESRptr(%lx %lx) is running over ESWptr(%lx)\n" , u32Data , pCtrl->u32LastESRptr, u32ESWptr ); u32Data = u32ESWptr; } else if ((_HVD_EX_GetBBUQNumb(u32Id) == 0) && ((u32Data - u32ESWptr) < 32) && ((pShm->u32FwState & E_HVD_FW_STATE_MASK) == E_HVD_FW_PLAY)) { //HVD_MSG_INFO("HVD Warn: ESRptr(%lx %lx) is running over ESWptr(%lx)\n" , u32Data , pCtrl->u32LastESRptr, u32ESWptr ); u32Data = u32ESWptr; } else if (((u32Data > u32ESWptr) && (pCtrl->u32LastESRptr > u32Data)) && ((u32Data - u32ESWptr) < 32) && (pCtrl->u32FlushRstPtr == 1)) { //HVD_MSG_INFO("444HVD Warn: ESRptr(%lx %lx) is running over ESWptr(%lx)\n" , u32Data , pCtrl->u32LastESRptr, u32ESWptr ); u32Data = u32ESWptr; } } // remove illegal pointer #if 1 if ((pCtrl->MemMap.u32DrvProcessBufSize != 0) && (pCtrl->MemMap.u32DrvProcessBufAddr != 0)) { MS_U32 u32PacketStaddr = u32Data + pCtrl->MemMap.u32BitstreamBufAddr; if (((pCtrl->MemMap.u32DrvProcessBufAddr <= u32PacketStaddr) && (u32PacketStaddr < (pCtrl->MemMap.u32DrvProcessBufAddr + pCtrl->MemMap.u32DrvProcessBufSize)))) { //HVD_MSG_INFO("HVD Warn: ESRptr(%lx %lx) is located in drv process buffer(%lx %lx)\n" , u32Data , pCtrl->u32LastESRptr, pCtrl->MemMap.u32DrvProcessBufAddr , pCtrl->MemMap.u32DrvProcessBufSize ); u32Data = pCtrl->u32LastESRptr; } } #endif } else { #if HVD_ENABLE_MVC MS_U8 u8ViewIdx = 0; if(HAL_HVD_EX_CheckMVCID(u32Id)) { u8ViewIdx = (MS_U8) HAL_HVD_EX_GetView(u32Id); } if(u8ViewIdx != 0) /// 2nd ES ptr. { u32Data = pShm->u32ES2ReadPtr; } else { u32Data = pShm->u32ESReadPtr; } #else u32Data = pShm->u32ESReadPtr; #endif } EXIT: pCtrl->u32LastESRptr = u32Data; return u32Data; } static MS_BOOL _HVD_EX_SetCMDArg(MS_U32 u32Id, MS_U32 u32Arg) { MS_U16 u16TimeOut = 0xFFFF; MS_BOOL bResult = FALSE; HVD_EX_MSG_DBG("Send ARG 0x%x to HVD\n", u32Arg); while (--u16TimeOut) { if (_HVD_EX_MBoxReady(u32Id, HAL_HVD_CMD_MBOX) && _HVD_EX_MBoxReady(u32Id, HAL_HVD_CMD_ARG_MBOX)) { bResult = _HVD_EX_MBoxSend(u32Id, HAL_HVD_CMD_ARG_MBOX, u32Arg); break; } } return bResult; } static MS_BOOL _HVD_EX_SetCMD(MS_U32 u32Id, MS_U32 u32Cmd) { MS_U16 u16TimeOut = 0xFFFF; MS_BOOL bResult = FALSE; MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); HVD_EX_MSG_DBG("Send CMD 0x%x to HVD \n", u32Cmd); #if HVD_ENABLE_MVC if(E_HAL_VPU_MVC_STREAM_BASE == u8TaskId) { u8TaskId = E_HAL_VPU_MAIN_STREAM_BASE; } #endif /// HVD_ENABLE_MVC HVD_EX_MSG_DBG("Send CMD 0x%x to HVD u8TaskId = %X\n", u32Cmd,u8TaskId); while (--u16TimeOut) { if (_HVD_EX_MBoxReady(u32Id, HAL_HVD_CMD_MBOX)) { u32Cmd |= (u8TaskId << 24); bResult = _HVD_EX_MBoxSend(u32Id, HAL_HVD_CMD_MBOX, u32Cmd); break; } } return bResult; } static HVD_Return _HVD_EX_SendCmd(MS_U32 u32Id, MS_U32 u32Cmd, MS_U32 u32CmdArg) { MS_U32 u32timeout = HVD_GetSysTime_ms() + pHVDHalContext->u32HVDCmdTimeout; #ifdef VDEC3 HVD_DRAM_COMMAND_QUEUE_SEND_STATUS SentRet = E_HVD_COMMAND_QUEUE_SEND_FAIL; MS_BOOL IsSent = FALSE; MS_BOOL IsMailBox = FALSE; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (HAL_VPU_EX_IsDisplayQueueCMD(u32Cmd)) { do { SentRet = HAL_VPU_EX_DRAMStreamDispCMDQueueSend(u32Id, &pShm->cmd_queue, E_HVD_CMDQ_ARG, u32CmdArg); if (!SentRet) HVD_EX_MSG_DBG("^^^Display command ARG return=0x%X cmd=0x%x arg=0x%x\n", SentRet,u32Cmd, u32CmdArg); if (SentRet == E_HVD_COMMAND_QUEUE_NOT_INITIALED) break; else if (SentRet == E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL) { IsSent = TRUE; break; } else if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("^^^Display command ARG timeout: cmd=0x%x arg=0x%x\n", u32Cmd, u32CmdArg); break; } }while (SentRet != E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL); } else if (!HAL_VPU_EX_IsMailBoxCMD(u32Cmd)) { do { SentRet = HAL_VPU_EX_DRAMStreamCMDQueueSend(u32Id, &pShm->cmd_queue, E_HVD_CMDQ_ARG, u32CmdArg); if (!SentRet) HVD_EX_MSG_DBG("^^^Dram command ARG return=0x%X cmd=0x%x arg=0x%x\n", SentRet,u32Cmd, u32CmdArg); if (SentRet == E_HVD_COMMAND_QUEUE_NOT_INITIALED) break; else if (SentRet == E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL) { IsSent = TRUE; break; } else if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("^^^Dram command ARG timeout: cmd=0x%x arg=0x%x\n", u32Cmd, u32CmdArg); break; } }while (SentRet != E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL); } if (!IsSent) { IsMailBox = TRUE; u32timeout = HVD_GetSysTime_ms() + HVD_DRV_MAILBOX_CMD_WAIT_FINISH_TIMEOUT;//pHVDHalContext->u32HVDCmdTimeout; while (!_HVD_EX_SetCMDArg(u32Id, u32CmdArg)) #else while (!_HVD_EX_SetCMDArg(u32Id, u32CmdArg)) #endif { //#ifndef VDEC3 // FIXME: workaround fw response time is slow sometimes in multiple stream case so far if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("Timeout: cmd=0x%x arg=0x%x\n", u32Cmd, u32CmdArg); return E_HVD_RETURN_TIMEOUT; } //#endif #if 0 if (u32Cmd == E_HVD_CMD_STOP) { MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #if HVD_ENABLE_MVC if(E_HAL_VPU_MVC_STREAM_BASE == u8TaskId) { u8TaskId = E_HAL_VPU_MAIN_STREAM_BASE; } #endif /// HVD_ENABLE_MVC MS_U32 u32Cmdtmp = (u8TaskId << 24) | E_HVD_CMD_STOP; _HVD_EX_MBoxSend(u32Id, HAL_HVD_CMD_MBOX, u32Cmdtmp); _HVD_EX_MBoxSend(u32Id, HAL_HVD_CMD_ARG_MBOX, 0); return E_HVD_RETURN_SUCCESS; } #endif if(u32Cmd < E_DUAL_CMD_BASE) { //_HVD_EX_GetPC(); HAL_HVD_EX_Dump_FW_Status(u32Id); HAL_HVD_EX_Dump_HW_Status(HVD_U32_MAX); } } #ifdef VDEC3 } IsSent = FALSE; u32timeout = HVD_GetSysTime_ms() + pHVDHalContext->u32HVDCmdTimeout; if (HAL_VPU_EX_IsDisplayQueueCMD(u32Cmd) && !IsMailBox) { do { SentRet = HAL_VPU_EX_DRAMStreamDispCMDQueueSend(u32Id, &pShm->cmd_queue, E_HVD_CMDQ_CMD,u32Cmd); if (!SentRet) HVD_EX_MSG_DBG("^^^Display command CMD return=0x%X cmd=0x%x arg=0x%x\n", SentRet,u32Cmd, u32CmdArg); if (SentRet == E_HVD_COMMAND_QUEUE_NOT_INITIALED) break; else if (SentRet == E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL){ IsSent = TRUE; break; } else if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("^^^Display command CMD timeout: cmd=0x%x arg=0x%x\n", u32Cmd, u32CmdArg); break; } } while (SentRet != E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL); } else if(!HAL_VPU_EX_IsMailBoxCMD(u32Cmd) && !IsMailBox) { do { SentRet = HAL_VPU_EX_DRAMStreamCMDQueueSend(u32Id, &pShm->cmd_queue, E_HVD_CMDQ_CMD,u32Cmd); if (SentRet != E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL) { HVD_EX_MSG_ERR("^^^Dram command CMD return=0x%X cmd=0x%x arg=0x%x\n", SentRet,u32Cmd, u32CmdArg); } if (SentRet == E_HVD_COMMAND_QUEUE_NOT_INITIALED) break; else if (SentRet == E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL){ IsSent = TRUE; break; } else if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("^^^Dram command CMD timeout: cmd=0x%x arg=0x%x\n", u32Cmd, u32CmdArg); break; } } while (SentRet != E_HVD_COMMAND_QUEUE_SEND_SUCCESSFUL); } if (!IsSent) { u32timeout = HVD_GetSysTime_ms() + HVD_DRV_MAILBOX_CMD_WAIT_FINISH_TIMEOUT;//pHVDHalContext->u32HVDCmdTimeout; while (!_HVD_EX_SetCMD(u32Id, u32Cmd)) #else u32timeout = HVD_GetSysTime_ms() + pHVDHalContext->u32HVDCmdTimeout; while (!_HVD_EX_SetCMD(u32Id, u32Cmd)) #endif { //#ifndef VDEC3 // FIXME: workaround fw response time is slow sometimes in multiple stream case so far if (HVD_GetSysTime_ms() > u32timeout) { HVD_EX_MSG_ERR("cmd timeout: %x\n", u32Cmd); return E_HVD_RETURN_TIMEOUT; } //#endif if(u32Cmd < E_DUAL_CMD_BASE) { //_HVD_EX_GetPC(); HAL_HVD_EX_Dump_FW_Status(u32Id); HAL_HVD_EX_Dump_HW_Status(HVD_U32_MAX); } } #ifdef VDEC3 } else { HAL_HVD_EX_FlushMemory(); } #endif return E_HVD_RETURN_SUCCESS; } static void _HVD_EX_SetMIUProtectMask(MS_BOOL bEnable) { #if HAL_HVD_ENABLE_MIU_PROTECT _HVD_MIU_SetReqMask(MVD_RW_0, bEnable); _HVD_MIU_SetReqMask(MVD_RW_1, bEnable); _HVD_MIU_SetReqMask(MVD_BBU_R, bEnable); #if SUPPORT_EVD _HVD_MIU_SetReqMask(EVD_RW, bEnable); _HVD_MIU_SetReqMask(EVD_BBU_R, bEnable); #endif _HVD_MIU_SetReqMask(HVD_RW_MIF0, bEnable); _HVD_MIU_SetReqMask(HVD_RW_MIF1, bEnable); _HVD_MIU_SetReqMask(HVD_BBU_R, bEnable); HAL_VPU_EX_MIU_RW_Protect(bEnable); //HVD_Delay_ms(1); #endif return; } static void _HVD_EX_SetBufferAddr(MS_U32 u32Id) { MS_U16 u16Reg = 0; MS_VIRT u32StAddr = 0; #ifdef VDEC3 MS_U32 u32Length = 0; #endif MS_U8 u8BitMiuSel = 0; MS_U8 u8CodeMiuSel = 0; MS_U8 u8FBMiuSel = 0; MS_U8 u8TmpMiuSel = 0; MS_U32 u32BitStartOffset; MS_U32 u32CodeStartOffset; MS_U32 u32FBStartOffset; #ifndef VDEC3 MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; _HAL_HVD_Entry(); if (pCtrl == NULL) { _HAL_HVD_Return(); } MS_BOOL bESBufferAlreadySet = FALSE; VPU_EX_TaskInfo taskInfo; memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); HAL_HVD_EX_GetTaskInfo(u32Id, &taskInfo); bESBufferAlreadySet = HAL_VPU_EX_CheckBBUSetting(u32Id, pCtrl->u32BBUId, taskInfo.eDecType, VPU_BBU_ES_BUFFER); _phy_to_miu_offset(u8BitMiuSel, u32BitStartOffset, pCtrl->MemMap.u32BitstreamBufAddr); _phy_to_miu_offset(u8CodeMiuSel, u32CodeStartOffset, pCtrl->MemMap.u32CodeBufAddr); _phy_to_miu_offset(u8FBMiuSel, u32FBStartOffset, pCtrl->MemMap.u32FrameBufAddr); HAL_HVD_EX_SetData(u32Id, E_HVD_SDATA_MIU_SEL, (u8BitMiuSel << VDEC_BS_MIUSEL) | (u8FBMiuSel << VDEC_LUMA8_MIUSEL) | (u8FBMiuSel << VDEC_LUMA2_MIUSEL) | (u8FBMiuSel << VDEC_CHROMA8_MIUSEL) | (u8FBMiuSel << VDEC_CHROMA2_MIUSEL) | (u8FBMiuSel << VDEC_HWBUF_MIUSEL) | (u8FBMiuSel << VDEC_BUF1_MIUSEL) | (u8FBMiuSel << VDEC_BUF2_MIUSEL) | (u8FBMiuSel << VDEC_PPIN_MIUSEL) | (u8FBMiuSel << VDEC_XCSHM_MIUSEL)); if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { // ES buffer #ifdef VDEC3 if(pCtrl->bShareBBU) u32StAddr = pCtrl->MemMap.u32TotalBitstreamBufAddr; // NStream will share the same ES buffer else #endif u32StAddr = u32BitStartOffset; _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, u32StAddr); #ifdef VDEC3 if (!_HAL_EX_BBU_VP8_InUsed()) #endif { HVD_EX_MSG_DBG("ESB start addr=%lx\n", (unsigned long)u32StAddr); _HVD_Write2Byte(HVD_REG_ESB_ST_ADR_L_BS34, HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADR_H_BS34, HVD_HWORD(u32StAddr >> 3)); #ifdef VDEC3 _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS34, HVD_LWORD(pCtrl->MemMap.u32TotalBitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS34, HVD_HWORD(pCtrl->MemMap.u32TotalBitstreamBufSize >> 3)); #else _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS34, HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS34, HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); #endif u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BS34); u16Reg &= ~HVD_REG_BS34_TSP_INPUT; u16Reg &= ~HVD_REG_BS34_PASER_MASK; u16Reg |= HVD_REG_BS34_PASER_DISABLE; u16Reg |= HVD_REG_BS34_AUTO_NAL_TAB; _HVD_Write2Byte(HVD_REG_MIF_BS34, u16Reg); } _HAL_HVD_Return(); } // ES buffer #ifdef VDEC3 if(!pCtrl->bShareBBU || E_HVD_INIT_INPUT_TSP == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK)) { u32StAddr = pCtrl->MemMap.u32BitstreamBufAddr; u32Length = pCtrl->MemMap.u32BitstreamBufSize >> 3; } else { u32StAddr = pCtrl->MemMap.u32TotalBitstreamBufAddr; u32Length = pCtrl->MemMap.u32TotalBitstreamBufSize >> 3; } #else u32StAddr = u32BitStartOffset; #endif _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, u32StAddr); HVD_EX_MSG_DBG("ESB start addr=%lx, len=%x\n", (unsigned long)u32StAddr, pCtrl->MemMap.u32BitstreamBufSize); #ifdef VDEC3 if (!bESBufferAlreadySet) { if (pCtrl->u32BBUId == 0) { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L(u32RB), HVD_LWORD(u32Length)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H(u32RB), HVD_HWORD(u32Length)); } else { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L_BS2(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H_BS2(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS2(u32RB), HVD_LWORD(u32Length)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS2(u32RB), HVD_HWORD(u32Length)); } } #else if (0 == u8TaskId) { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L(u32RB), HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H(u32RB), HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); } else { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L_BS2(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H_BS2(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS2(u32RB), HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS2(u32RB), HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); } #endif // others #ifdef VDEC3 if (!bESBufferAlreadySet) { if (pCtrl->u32BBUId == 0) u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU(u32RB)); else u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU_BS2(u32RB)); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { if (pCtrl->u32BBUId == 0) u16Reg |= HVD_REG_BBU_TSP_INPUT; else u16Reg |= HVD_REG_BBU_TSP_INPUT_BS2; } else { if (pCtrl->u32BBUId == 0) u16Reg &= ~HVD_REG_BBU_TSP_INPUT; else u16Reg &= ~HVD_REG_BBU_TSP_INPUT_BS2; } // do not set parsing setting in DRV, and we set it in FW (hvd_switch_bbu) if (pCtrl->u32BBUId == 0) u16Reg &= ~HVD_REG_BBU_PASER_MASK; else u16Reg &= ~HVD_REG_BBU_PASER_MASK_BS2; if (pCtrl->u32BBUId == 0) { u16Reg |= HVD_REG_BBU_AUTO_NAL_TAB; _HVD_Write2Byte(HVD_REG_MIF_BBU(u32RB), u16Reg); } else { u16Reg |= HVD_REG_BBU_AUTO_NAL_TAB_BS2; _HVD_Write2Byte(HVD_REG_MIF_BBU_BS2(u32RB), u16Reg); } } #else if (0 == u8TaskId) { u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU(u32RB)); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { u16Reg |= HVD_REG_BBU_TSP_INPUT; } else { u16Reg &= ~HVD_REG_BBU_TSP_INPUT; } u16Reg &= ~HVD_REG_BBU_PASER_MASK; if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) // RM { u16Reg |= HVD_REG_BBU_PASER_DISABLE; // force BBU to remove nothing, RM only } else // AVS or AVC { if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_START_CODE_MASK) == E_HVD_INIT_START_CODE_REMOVED) { u16Reg |= HVD_REG_BBU_PASER_ENABLE_03; } else // start code remained { u16Reg |= HVD_REG_BBU_PASER_ENABLE_ALL; } } u16Reg |= HVD_REG_BBU_AUTO_NAL_TAB; _HVD_Write2Byte(HVD_REG_MIF_BBU(u32RB), u16Reg); } else { u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU_BS2(u32RB)); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { u16Reg |= HVD_REG_BBU_TSP_INPUT_BS2; } else { u16Reg &= ~HVD_REG_BBU_TSP_INPUT_BS2; } u16Reg &= ~HVD_REG_BBU_PASER_MASK_BS2; if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) // RM { u16Reg |= HVD_REG_BBU_PASER_DISABLE_BS2; // force BBU to remove nothing, RM only } else // AVS or AVC { if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_START_CODE_MASK) == E_HVD_INIT_START_CODE_REMOVED) { u16Reg |= HVD_REG_BBU_PASER_ENABLE_03_BS2; } else // start code remained { u16Reg |= HVD_REG_BBU_PASER_ENABLE_ALL_BS2; } } u16Reg |= HVD_REG_BBU_AUTO_NAL_TAB_BS2; _HVD_Write2Byte(HVD_REG_MIF_BBU_BS2(u32RB), u16Reg); } #endif #if (HVD_ENABLE_MVC) if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_MVC) { /// Used sub stream to record sub view data. HVD_EX_Drv_Ctrl *pDrvCtrl_Sub = _HVD_EX_GetDrvCtrl((u32Id+0x00011000)); //printf("**************** Buffer setting for MVC dual-BBU *************\n"); // ES buffer _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, (pDrvCtrl_Sub->MemMap.u32BitstreamBufAddr)); HVD_EX_MSG_DBG("[MVC] 2nd ES _HAL_HVD_SetBuffer2Addr: ESb StAddr:%lx, len:%lx.\n", (unsigned long) u32StAddr, (unsigned long) pDrvCtrl_Sub->MemMap.u32BitstreamBufSize); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L_BS2(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H_BS2(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS2(u32RB), HVD_LWORD(pDrvCtrl_Sub->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS2(u32RB), HVD_HWORD(pDrvCtrl_Sub->MemMap.u32BitstreamBufSize >> 3)); u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU_BS2(u32RB)); if((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { u16Reg |= HVD_REG_BBU_TSP_INPUT_BS2; HVD_EX_MSG_DBG("[MVC] 2nd ES, TSP mode.\n"); } else { u16Reg &= ~HVD_REG_BBU_TSP_INPUT_BS2; HVD_EX_MSG_DBG("[MVC] 2nd ES, BBU mode.\n"); } u16Reg &= ~HVD_REG_BBU_PASER_MASK_BS2; if((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) // RM { u16Reg |= HVD_REG_BBU_PASER_DISABLE_BS2; // force BBU to remove nothing, RM only } else // AVS or AVC { if((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_START_CODE_MASK) == E_HVD_INIT_START_CODE_REMOVED) { u16Reg |= HVD_REG_BBU_PASER_ENABLE_03_BS2; } else // start code remained { u16Reg |= HVD_REG_BBU_PASER_ENABLE_ALL_BS2; ///HVD_MSG_DBG("[MVC] BBU Paser all.\n"); } } u16Reg |= HVD_REG_BBU_AUTO_NAL_TAB_BS2; ///HVD_MSG_DBG("[MVC] 2nd MIF BBU 0x%lx.\n",(MS_U32)u16Reg); _HVD_Write2Byte(HVD_REG_MIF_BBU_BS2(u32RB), u16Reg); } #endif // MIF offset #if 0 { MS_U16 offaddr = 0; u32StAddr = pCtrl->MemMap.u32CodeBufAddr; if (u32StAddr >= pCtrl->MemMap.u32MIU1BaseAddr) { u32StAddr -= pCtrl->MemMap.u32MIU1BaseAddr; } HVD_EX_MSG_DBG("MIF offset:%lx \n", u32StAddr); offaddr = (MS_U16) ((u32StAddr) >> 20); offaddr &= BMASK(HVD_REG_MIF_OFFSET_L_BITS:0); //0x1FF; // 9 bits(L + H) u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BBU); u16Reg &= ~HVD_REG_MIF_OFFSET_H; u16Reg &= ~(BMASK(HVD_REG_MIF_OFFSET_L_BITS:0)); if (offaddr & BIT(HVD_REG_MIF_OFFSET_L_BITS)) { u16Reg |= HVD_REG_MIF_OFFSET_H; } _HVD_Write2Byte(HVD_REG_MIF_BBU, (u16Reg | (offaddr & BMASK(HVD_REG_MIF_OFFSET_L_BITS:0)))); } #endif if (!bESBufferAlreadySet) { HAL_VPU_EX_SetBBUSetting(u32Id, pCtrl->u32BBUId, taskInfo.eDecType, VPU_BBU_ES_BUFFER); } _HAL_HVD_Return(); } #if 0 //defined(SUPPORT_NEW_MEM_LAYOUT) || defined(SUPPORT_NEW_VDEC_FLOW) // Note: For VP8 only. MVC ES buffer address will be set when _HVD_EX_SetBufferAddr() is called static void _HVD_EX_SetESBufferAddr(MS_U32 u32Id) { MS_U16 u16Reg = 0; MS_U32 u32StAddr = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; if(pCtrl == NULL) return; if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { _HVD_Write2Byte(HVD_REG_HK_VP8, HVD_REG_HK_PLAYER_FM); // ES buffer u32StAddr = pCtrl->MemMap.u32BitstreamBufAddr; if (u32StAddr >= pCtrl->MemMap.u32MIU1BaseAddr) { u32StAddr -= pCtrl->MemMap.u32MIU1BaseAddr; } _HVD_Write2Byte(HVD_REG_ESB_ST_ADR_L_BS34, HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADR_H_BS34, HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS34, HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS34, HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); u16Reg = _HVD_Read2Byte(HVD_REG_MIF_BS34); u16Reg &= ~HVD_REG_BS34_TSP_INPUT; u16Reg &= ~HVD_REG_BS34_PASER_MASK; u16Reg |= HVD_REG_BS34_PASER_DISABLE; u16Reg |= HVD_REG_BS34_AUTO_NAL_TAB; _HVD_Write2Byte(HVD_REG_MIF_BS34, u16Reg); return; } // ES buffer u32StAddr = pCtrl->MemMap.u32BitstreamBufAddr; if (u32StAddr >= pCtrl->MemMap.u32MIU1BaseAddr) { u32StAddr -= pCtrl->MemMap.u32MIU1BaseAddr; } HVD_EX_MSG_DBG("ESB start addr=%lx, len=%lx\n", u32StAddr, pCtrl->MemMap.u32BitstreamBufSize); if (0 == HAL_VPU_EX_GetTaskId(u32Id)) { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L(u32RB), HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H(u32RB), HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); } else { _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_L_BS2(u32RB), HVD_LWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_ST_ADDR_H_BS2(u32RB), HVD_HWORD(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_L_BS2(u32RB), HVD_LWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); _HVD_Write2Byte(HVD_REG_ESB_LENGTH_H_BS2(u32RB), HVD_HWORD(pCtrl->MemMap.u32BitstreamBufSize >> 3)); } } #endif static MS_U32 _HVD_EX_GetESLevel(MS_U32 u32Id) { MS_U32 u32Wptr = 0; MS_U32 u32Rptr = 0; MS_U32 u32CurMBX = 0; MS_U32 u32ESsize = 0; MS_U32 u32Ret = E_HVD_ESB_LEVEL_NORMAL; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); u32Wptr = _HVD_EX_GetESWritePtr(u32Id); u32Rptr = _HVD_EX_GetESReadPtr(u32Id, FALSE); u32ESsize = pCtrl->MemMap.u32BitstreamBufSize; if (u32Rptr >= u32Wptr) { u32CurMBX = u32Rptr - u32Wptr; } else { u32CurMBX = u32ESsize - (u32Wptr - u32Rptr); } if (u32CurMBX == 0) { u32Ret = E_HVD_ESB_LEVEL_UNDER; } else if (u32CurMBX < HVD_FW_AVC_ES_OVER_THRESHOLD) { u32Ret = E_HVD_ESB_LEVEL_OVER; } else { u32CurMBX = u32ESsize - u32CurMBX; if (u32CurMBX < HVD_FW_AVC_ES_UNDER_THRESHOLD) { u32Ret = E_HVD_ESB_LEVEL_UNDER; } } return u32Ret; } static MS_U32 _HVD_EX_GetESQuantity(MS_U32 u32Id) { MS_U32 u32Wptr = 0; MS_U32 u32Rptr = 0; MS_U32 u32ESsize = 0; MS_U32 u32Ret = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); u32Wptr = _HVD_EX_GetESWritePtr(u32Id); u32Rptr = _HVD_EX_GetESReadPtr(u32Id, FALSE); u32ESsize = pCtrl->MemMap.u32BitstreamBufSize; if(u32Wptr >= u32Rptr) { u32Ret = u32Wptr - u32Rptr; } else { u32Ret = u32ESsize - u32Rptr + u32Wptr; } //printf("ES Quantity <0x%lx> W:0x%lx, R:0x%lx, Q:0x%lx.\n",u32Id,u32Wptr,u32Rptr,u32Ret); return u32Ret; } #if (HVD_ENABLE_IQMEM) MS_BOOL HAL_HVD_EX_IQMem_Init(MS_U32 u32Id) { MS_U32 u32Timeout = 20000; if (HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_IQMEM_CTRL) == E_HVD_IQMEM_INIT_NONE) { HAL_VPU_EX_IQMemSetDAMode(TRUE); HAL_HVD_EX_SetData(u32Id, E_HVD_SDATA_FW_IQMEM_CTRL, E_HVD_IQMEM_INIT_LOADING); while (u32Timeout) { if (HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_IQMEM_CTRL) == E_HVD_IQMEM_INIT_LOADED) { break; } u32Timeout--; HVD_Delay_ms(1); } HAL_VPU_EX_IQMemSetDAMode(FALSE); HAL_HVD_EX_SetData(u32Id, E_HVD_SDATA_FW_IQMEM_CTRL, E_HVD_IQMEM_INIT_FINISH); if (u32Timeout==0) { HVD_EX_MSG_ERR("Wait E_HVD_IQMEM_INIT_LOADED timeout !!\n"); return FALSE; } } return TRUE; } #endif #ifdef VDEC3 static MS_BOOL _HVD_EX_SetRegCPU(MS_U32 u32Id, MS_BOOL bFWdecideFB) #else static MS_BOOL _HVD_EX_SetRegCPU(MS_U32 u32Id) #endif { MS_U32 u32FirmVer = 0; MS_U32 u32Timeout = 20000; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_EX_MSG_DBG("HVD HW ver id: 0x%04x\n", HAL_HVD_EX_GetHWVersionID()); #if HVD_ENABLE_TIME_MEASURE HVD_EX_MSG_MUST("HVD Time Measure:%d (%s %d) \n", HVD_GetSysTime_ms() - pHVDDrvContext->u32InitSysTimeBase, __FUNCTION__, __LINE__); #endif HAL_VPU_EX_SetFWReload(!pCtrl->bTurboFWMode); VPU_EX_FWCodeCfg fwCfg; VPU_EX_TaskInfo taskInfo; VPU_EX_VLCTblCfg vlcCfg; #ifdef VDEC3 VPU_EX_FBCfg fbCfg; #endif VPU_EX_NDecInitPara nDecInitPara; memset(&fwCfg, 0, sizeof(VPU_EX_FWCodeCfg)); memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); memset(&vlcCfg, 0, sizeof(VPU_EX_VLCTblCfg)); memset(&nDecInitPara, 0, sizeof(VPU_EX_NDecInitPara)); #ifdef VDEC3_FB nDecInitPara.pVLCCfg = NULL; #else if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) //rm { vlcCfg.u32DstAddr = MsOS_PA2KSEG0(pCtrl->MemMap.u32FrameBufAddr + pHVDHalContext->u32RV_VLCTableAddr); vlcCfg.u32BinAddr = pCtrl->MemMap.u32VLCBinaryVAddr; vlcCfg.u32BinSize = pCtrl->MemMap.u32VLCBinarySize; vlcCfg.u32FrameBufAddr = pCtrl->MemMap.u32FrameBufVAddr; vlcCfg.u32VLCTableOffset = pHVDHalContext->u32RV_VLCTableAddr; nDecInitPara.pVLCCfg = &vlcCfg; } #endif nDecInitPara.pFWCodeCfg = &fwCfg; nDecInitPara.pTaskInfo = &taskInfo; #ifdef VDEC3 fbCfg.u32FrameBufAddr = pCtrl->MemMap.u32FrameBufAddr; fbCfg.u32FrameBufSize = pCtrl->MemMap.u32FrameBufSize; if (fbCfg.u32FrameBufAddr >= pCtrl->MemMap.u32MIU1BaseAddr) { fbCfg.u32FrameBufAddr -= pCtrl->MemMap.u32MIU1BaseAddr; } nDecInitPara.pFBCfg = &fbCfg; #endif fwCfg.u8SrcType = pCtrl->MemMap.eFWSourceType; fwCfg.u32DstAddr = pCtrl->MemMap.u32CodeBufVAddr; fwCfg.u32DstSize = pCtrl->MemMap.u32CodeBufSize; fwCfg.u32BinAddr = pCtrl->MemMap.u32FWBinaryVAddr; fwCfg.u32BinSize = pCtrl->MemMap.u32FWBinarySize; taskInfo.u32Id = u32Id; if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_MVC) { taskInfo.eDecType = E_VPU_EX_DECODER_HVD; //E_VPU_EX_DECODER_MVC; } #ifdef VDEC3 else if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC || (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC_DV) { taskInfo.eDecType = E_VPU_EX_DECODER_EVD; } #if SUPPORT_MSVP9 else if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP9) { taskInfo.eDecType = E_VPU_EX_DECODER_EVD; } #endif #if SUPPORT_G2VP9 else if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP9) { taskInfo.eDecType = E_VPU_EX_DECODER_G2VP9; } #endif #endif else { taskInfo.eDecType = E_VPU_EX_DECODER_HVD; } taskInfo.eVpuId = (HAL_VPU_StreamId) (0xFF & u32Id); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { taskInfo.eSrcType = E_VPU_EX_INPUT_FILE; } else { taskInfo.eSrcType = E_VPU_EX_INPUT_TSP; } taskInfo.u32HeapSize = HVD_DRAM_SIZE; #ifdef SUPPORT_EVD if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC || (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP9 ) taskInfo.u32HeapSize = EVD_DRAM_SIZE; #endif if(TRUE == HVD_EX_GetRstFlag()) { //Delete task for Rst if(!HAL_VPU_EX_TaskDelete(u32Id, &nDecInitPara)) { HVD_EX_MSG_ERR("HAL_VPU_EX_TaskDelete fail\n"); } HVD_EX_SetRstFlag(FALSE); } #if (HVD_ENABLE_IQMEM) HAL_HVD_EX_SetData(u32Id, E_HVD_SDATA_FW_IQMEM_ENABLE_IF_SUPPORT, (MS_U32)1); #endif #ifdef VDEC3 if (!HAL_VPU_EX_TaskCreate(u32Id, &nDecInitPara, bFWdecideFB, pCtrl->u32BBUId)) #else if (!HAL_VPU_EX_TaskCreate(u32Id, &nDecInitPara)) #endif { HVD_EX_MSG_ERR("Task create fail!\n"); return FALSE; } while (u32Timeout) { u32FirmVer = HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_INIT_DONE); if (u32FirmVer != 0) { u32FirmVer = HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_VERSION_ID); break; } u32Timeout--; HVD_Delay_ms(1); } #ifdef VDEC3_FB #if HVD_ENABLE_RV_FEATURE HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) //rm { if(pShm->u32RM_VLCTableAddr == 0) { HVD_EX_MSG_ERR("[VDEC3_FB] Error!!!RM_VLCTableAddr is not ready\n"); } else { vlcCfg.u32DstAddr = MsOS_PA2KSEG1(MsOS_VA2PA(nDecInitPara.pFWCodeCfg->u32DstAddr + pShm->u32RM_VLCTableAddr)); vlcCfg.u32BinAddr = pCtrl->MemMap.u32VLCBinaryVAddr; vlcCfg.u32BinSize = pCtrl->MemMap.u32VLCBinarySize; vlcCfg.u32FrameBufAddr = pCtrl->MemMap.u32FrameBufVAddr; //this is frame buffer address is decided by player. In VDEC3_FB path, this variable could be zero or the start address of overall Frame buffer. vlcCfg.u32VLCTableOffset = pShm->u32RM_VLCTableAddr; // offset from FW code start address nDecInitPara.pVLCCfg = &vlcCfg; } } if (nDecInitPara.pVLCCfg) { HVD_EX_MSG_DBG("[VDEC3_FB] Ready to load VLC Table DstAddr=0x%x FrameBufAddr=0x%x VLCTableOffset=0x%x\n", (unsigned int)vlcCfg.u32DstAddr, (unsigned int)vlcCfg.u32FrameBufAddr, (unsigned int)vlcCfg.u32VLCTableOffset); if (!HAL_VPU_EX_LoadVLCTable(nDecInitPara.pVLCCfg, nDecInitPara.pFWCodeCfg->u8SrcType)) { HVD_EX_MSG_ERR("[VDEC3_FB] Error!!!Load VLC Table fail!\n"); return FALSE; } } #endif #endif if (u32Timeout > 0) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); pHVDHalContext->_stHVDStream[u8Idx].bUsed = TRUE; #ifdef VDEC3 switch (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) { case E_HVD_INIT_HW_AVC: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_AVC; break; case E_HVD_INIT_HW_AVS: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_AVS; break; case E_HVD_INIT_HW_RM: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_RM; break; case E_HVD_INIT_HW_MVC: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_MVC; break; case E_HVD_INIT_HW_VP8: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_VP8; break; case E_HVD_INIT_HW_MJPEG: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_MJPEG; break; case E_HVD_INIT_HW_VP6: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_VP6; break; case E_HVD_INIT_HW_HEVC: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_HEVC; break; case E_HVD_INIT_HW_VP9: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_VP9; break; case E_HVD_INIT_HW_HEVC_DV: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_HEVC_DV; break; default: pHVDHalContext->_stHVDStream[u8Idx].u32CodecType = E_HAL_HVD_NONE; break; } #endif HVD_EX_MSG_INF("FW version binary=0x%x, if=0x%x\n", u32FirmVer, (MS_U32) HVD_FW_VERSION); } else { HVD_EX_MSG_ERR("Cannot get FW version !!0x%x 0x%lx \n", (MS_S16) _HVD_Read2Byte(HVD_REG_RESET), (unsigned long)HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_VERSION_ID)); if (TRUE != HAL_VPU_EX_TaskDelete(u32Id, &nDecInitPara)) { HVD_EX_MSG_ERR("Task delete fail!\n"); } return FALSE; } #if (HVD_ENABLE_IQMEM) if( HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_IS_IQMEM_SUPPORT)) { HAL_HVD_EX_IQMem_Init(u32Id); } else{ HVD_EX_MSG_DBG("not support IQMEM\n"); } #endif #if HVD_ENABLE_TIME_MEASURE HVD_EX_MSG_MUST("HVD Time Measure:%d (%s %d) \n", HVD_GetSysTime_ms() - pHVDDrvContext->u32InitSysTimeBase, __FUNCTION__, __LINE__); #endif return TRUE; } static MS_VIRT _HVD_EX_GetPTSTableRptr(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (pShm->u32PTStableRptrAddr & VPU_QMEM_BASE) { return HAL_VPU_EX_MemRead(pShm->u32PTStableRptrAddr); } else { //return *((MS_VIRT *) MsOS_PA2KSEG1((MS_PHY) pShm->u32PTStableRptrAddr + pCtrl->MemMap.u32CodeBufAddr)); return *((MS_U32 *) MsOS_PA2KSEG1((MS_PHY) pShm->u32PTStableRptrAddr + pCtrl->MemMap.u32CodeBufAddr)); } } static MS_VIRT _HVD_EX_GetPTSTableWptr(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (pShm->u32PTStableWptrAddr & VPU_QMEM_BASE) { return HAL_VPU_EX_MemRead(pShm->u32PTStableWptrAddr); } else { //return *((MS_VIRT *) MsOS_PA2KSEG1((MS_PHY)pShm->u32PTStableWptrAddr + pCtrl->MemMap.u32CodeBufAddr)); return *((MS_U32 *) MsOS_PA2KSEG1((MS_PHY)pShm->u32PTStableWptrAddr + pCtrl->MemMap.u32CodeBufAddr)); } } static void _HVD_EX_SetPTSTableWptr(MS_U32 u32Id, MS_U32 u32Value) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (pShm->u32PTStableWptrAddr & VPU_QMEM_BASE) { if (!HAL_VPU_EX_MemWrite(pShm->u32PTStableWptrAddr, u32Value)) { HVD_EX_MSG_ERR("PTS table SRAM write failed\n"); } } else { //*((MS_VIRT *) MsOS_PA2KSEG1((MS_PHY)pShm->u32PTStableWptrAddr + pCtrl->MemMap.u32CodeBufAddr)) = u32Value; *((MS_U32 *) MsOS_PA2KSEG1((MS_PHY)pShm->u32PTStableWptrAddr + pCtrl->MemMap.u32CodeBufAddr)) = u32Value; } } static HVD_Return _HVD_EX_UpdatePTSTable(MS_U32 u32Id, HVD_BBU_Info *pInfo) { MS_VIRT u32PTSWptr = HVD_U32_MAX; MS_VIRT u32PTSRptr = HVD_U32_MAX; MS_VIRT u32DestAddr = 0; HVD_PTS_Entry PTSEntry; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); // update R & W ptr u32PTSRptr = _HVD_EX_GetPTSTableRptr(u32Id); HVD_EX_MSG_DBG("PTS table rptr:0x%lx, wptr=0x%lx\n", (unsigned long)u32PTSRptr, (unsigned long)_HVD_EX_GetPTSTableWptr(u32Id)); if (u32PTSRptr >= MAX_PTS_TABLE_SIZE) { HVD_EX_MSG_ERR("PTS table Read Ptr(%lx) > max table size(%x) \n", (unsigned long)u32PTSRptr, (MS_U32) MAX_PTS_TABLE_SIZE); return E_HVD_RETURN_FAIL; } // check queue is full or not u32PTSWptr = pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr + 1; u32PTSWptr %= MAX_PTS_TABLE_SIZE; if (u32PTSWptr == u32PTSRptr) { HVD_EX_MSG_ERR("PTS table full. Read Ptr(%lx) == new Write ptr(%lx) ,Pre Wptr(%lx) \n", (unsigned long)u32PTSRptr, (unsigned long)u32PTSWptr, (unsigned long)pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr); return E_HVD_RETURN_FAIL; } // add one PTS entry PTSEntry.u32ByteCnt = pHVDHalContext->_stHVDStream[u8Idx].u32PTSByteCnt & HVD_BYTE_COUNT_MASK; PTSEntry.u32ID_L = pInfo->u32ID_L; PTSEntry.u32ID_H = pInfo->u32ID_H; PTSEntry.u32PTS = pInfo->u32TimeStamp; u32DestAddr = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + (MS_PHY)pShm->u32HVD_PTS_TABLE_ST_OFFSET + (pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr * sizeof(HVD_PTS_Entry))); HVD_EX_MSG_DBG("PTS entry dst addr=0x%lx\n", (unsigned long)MsOS_VA2PA(u32DestAddr)); HVD_memcpy((void *) u32DestAddr, &PTSEntry, sizeof(HVD_PTS_Entry)); HAL_HVD_EX_FlushMemory(); // update Write ptr _HVD_EX_SetPTSTableWptr(u32Id, u32PTSWptr); pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr = u32PTSWptr; return E_HVD_RETURN_SUCCESS; } static HVD_Return _HVD_EX_UpdateESWptr(MS_U32 u32Id, MS_U32 u32NalOffset, MS_U32 u32NalLen) { //--------------------------------------------------- // item format in nal table: // reserved |borken| u32NalOffset | u32NalLen // 13 bits |1bit | 29 bits | 21 bits (total 8 bytes) //--------------------------------------------------- MS_VIRT u32Adr = 0; MS_U32 u32BBUNewWptr = 0; MS_U8 item[8]; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_PHY u32BBU_DRAM_ST_ADDR = pShm->u32HVD_BBU_DRAM_ST_ADDR; #if HVD_ENABLE_MVC if(HAL_HVD_EX_CheckMVCID(u32Id)) { // if MVC_BBU_ADDR and HVD_BBU_ADDR are different, we need to add MVC_BBU_DRAM_ST_ADDR and MVC_BBU2_DRAM_ST_ADDR in share memory u32BBU_DRAM_ST_ADDR = pShm->u32HVD_BBU_DRAM_ST_ADDR; //pShm->u32MVC_BBU_DRAM_ST_ADDR; if(E_VDEC_EX_SUB_VIEW == HAL_HVD_EX_GetView(u32Id)) { u32BBU_DRAM_ST_ADDR = pShm->u32HVD_BBU2_DRAM_ST_ADDR; //pShm->u32MVC_BBU2_DRAM_ST_ADDR; } } #endif /// HVD_ENABLE_MVC if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u32BBUNewWptr = pHVDHalContext->u32VP8BBUWptr; } else { u32BBUNewWptr = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr; } u32BBUNewWptr++; u32BBUNewWptr %= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum; // prepare nal entry if (E_HVD_INIT_HW_HEVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) || E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { // NAL len 22 bits , HEVC level5 constrain item[0] = u32NalLen & 0xff; item[1] = (u32NalLen >> 8) & 0xff; item[2] = ((u32NalLen >> 16) & 0x3f) | ((u32NalOffset << 6) & 0xc0); item[3] = (u32NalOffset >> 2) & 0xff; item[4] = (u32NalOffset >> 10) & 0xff; item[5] = (u32NalOffset >> 18) & 0xff; item[6] = (u32NalOffset >> 26) & 0x0f; //including broken bit item[7] = 0; } else { item[0] = u32NalLen & 0xff; item[1] = (u32NalLen >> 8) & 0xff; item[2] = ((u32NalLen >> 16) & 0x1f) | ((u32NalOffset << 5) & 0xe0); item[3] = (u32NalOffset >> 3) & 0xff; item[4] = (u32NalOffset >> 11) & 0xff; item[5] = (u32NalOffset >> 19) & 0xff; item[6] = (u32NalOffset >> 27) & 0x07; //including broken bit item[7] = 0; } if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u32Adr = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32BBU_DRAM_ST_ADDR + (pHVDHalContext->u32VP8BBUWptr << 3)); } else { // add nal entry u32Adr = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32BBU_DRAM_ST_ADDR + (pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr << 3)); } HVD_memcpy((void *) u32Adr, (void *) item, 8); HAL_HVD_EX_FlushMemory(); HVD_EX_MSG_DBG("addr=0x%lx, bbu wptr=0x%x\n", (unsigned long)MsOS_VA2PA(u32Adr), pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr); if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { pHVDHalContext->u32VP8BBUWptr = u32BBUNewWptr; } else { pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr = u32BBUNewWptr; } return E_HVD_RETURN_SUCCESS; } static HVD_Return _HVD_EX_UpdateESWptr_VP8(MS_U32 u32Id, MS_U32 u32NalOffset, MS_U32 u32NalLen, MS_U32 u32NalOffset2, MS_U32 u32NalLen2) { MS_U8 item[8]; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_VIRT u32Adr = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_PHY u32VP8_BBU_DRAM_ST_ADDR_BS4 = pShm->u32HVD_BBU2_DRAM_ST_ADDR; /* printf("nal2 offset=0x%x, len=0x%x\n", u32NalOffset2, u32NalLen2); */ item[0] = u32NalLen2 & 0xff; item[1] = (u32NalLen2 >> 8) & 0xff; item[2] = ((u32NalLen2 >> 16) & 0x1f) | ((u32NalOffset2 << 5) & 0xe0); item[3] = (u32NalOffset2 >> 3) & 0xff; item[4] = (u32NalOffset2 >> 11) & 0xff; item[5] = (u32NalOffset2 >> 19) & 0xff; item[6] = (u32NalOffset2 >> 27) & 0x07; item[7] = 0; if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u32Adr = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32VP8_BBU_DRAM_ST_ADDR_BS4 + (pHVDHalContext->u32VP8BBUWptr << 3)); } else { u32Adr = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32VP8_BBU_DRAM_ST_ADDR_BS4 + (pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr << 3)); } HVD_memcpy((void *) u32Adr, (void *) item, 8); HAL_HVD_EX_FlushMemory(); return _HVD_EX_UpdateESWptr(u32Id, u32NalOffset, u32NalLen); } static MS_VIRT _HVD_EX_GetVUIDispInfo(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if( ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_AVC) || ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_MVC) || ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC) ) { MS_U16 i; MS_PHY u32VUIAddr; MS_U32 *pData = (MS_U32 *) &(pHVDHalContext->g_hvd_VUIINFO); HAL_HVD_EX_ReadMemory(); u32VUIAddr = pShm->u32AVC_VUIDispInfo_Addr; for (i = 0; i < sizeof(HVD_AVC_VUI_DISP_INFO); i += 4) { if (pShm->u32AVC_VUIDispInfo_Addr & VPU_QMEM_BASE) { *pData = HAL_VPU_EX_MemRead(u32VUIAddr + i); } else { *pData = *((MS_U32 *) MsOS_PA2KSEG1(u32VUIAddr + i + pCtrl->MemMap.u32CodeBufAddr)); } pData++; } } else { memset(&(pHVDHalContext->g_hvd_VUIINFO), 0, sizeof(HVD_AVC_VUI_DISP_INFO)); } return (MS_VIRT) &(pHVDHalContext->g_hvd_VUIINFO); } static MS_U32 _HVD_EX_GetBBUQNumb(MS_U32 u32Id) { MS_U32 u32ReadPtr = 0; MS_U32 eRet = 0; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); u32ReadPtr = _HVD_EX_GetBBUReadptr(u32Id); MS_U32 u32WritePtr = 0; if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u32WritePtr = pHVDHalContext->u32VP8BBUWptr; } else { u32WritePtr = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr; } HVD_EX_MSG_DBG("idx=%x, bbu rptr=%x, bbu wptr=%x\n", u8Idx, u32ReadPtr, u32WritePtr); if (u32WritePtr >= u32ReadPtr) { eRet = u32WritePtr - u32ReadPtr; } else { eRet = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - (u32ReadPtr - u32WritePtr); } #if 0 if (pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr >= u32ReadPtr) { eRet = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr - u32ReadPtr; } else { eRet = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - (u32ReadPtr - pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr); } #endif return eRet; } static MS_U32 _HVD_EX_GetPTSQNumb(MS_U32 u32Id) { MS_U32 u32ReadPtr = 0; MS_U32 eRet = 0; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); u32ReadPtr = _HVD_EX_GetPTSTableRptr(u32Id); if (u32ReadPtr >= MAX_PTS_TABLE_SIZE) { HVD_EX_MSG_ERR("PTS table Read Ptr(%x) > max table size(%x) \n", u32ReadPtr, (MS_U32) MAX_PTS_TABLE_SIZE); return 0; } u8Idx = _HVD_EX_GetStreamIdx(u32Id); if (pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr >= u32ReadPtr) { eRet = pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr - u32ReadPtr; } else { eRet = MAX_PTS_TABLE_SIZE - (u32ReadPtr - pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr); } return eRet; } static MS_BOOL _HVD_EX_IsHevcInterlaceField(MS_U32 u32Id) { HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); return pShm->u32CodecType == E_HVD_Codec_HEVC && pShm->DispInfo.u8Interlace == 1; } static HEVC_PIC_STRUCT hevc_get_paired(HEVC_PIC_STRUCT pic_struct, int first_field) { if (pic_struct == EVD_TOP_FIELD) return EVD_BOTTOM_FIELD; else if (pic_struct == EVD_BOTTOM_FIELD) return EVD_TOP_FIELD; if (first_field) { // pic_struct is the first field and must pair with the next one if (pic_struct == EVD_TOP_WITH_NEXT) return EVD_BOTTOM_WITH_PREV; else if (pic_struct == EVD_BOTTOM_WITH_NEXT) return EVD_TOP_WITH_PREV; } else { // pic_struct is the second field and must pair with the previous one if (pic_struct == EVD_TOP_WITH_PREV) return EVD_BOTTOM_WITH_NEXT; else if (pic_struct == EVD_BOTTOM_WITH_PREV) return EVD_TOP_WITH_NEXT; } return EVD_UNKNOWN_TYPE; } static HVD_Frm_Information *_HVD_EX_GetNextDispFrame(MS_U32 u32Id) { HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL bDolbyVision = (E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)); HAL_HVD_EX_ReadMemory(); MS_U16 u16QNum = pShm->u16DispQNumb; MS_U16 u16QPtr = pShm->u16DispQPtr; HVD_Frm_Information *pHvdFrm = (HVD_Frm_Information*)&pShm->DispQueue[u16QPtr]; if (bDolbyVision) { if (pHVDHalContext->_stHVDStream[u8Idx].bfirstGetFrmInfoDone && u16QNum < 4) // first time we need to wait 4 pic to ensure we got the correct layer type { return NULL; } else { pHVDHalContext->_stHVDStream[u8Idx].bfirstGetFrmInfoDone = FALSE; } } #if (HVD_ENABLE_MVC) MS_BOOL bMVC = HAL_HVD_EX_CheckMVCID(u32Id); if (bMVC || (bDolbyVision && !pShm->bSingleLayer)) { if (pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { MS_U16 u16RealQPtr = pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex; MS_U16 u16UsedFrm = 0; MS_U16 u16ResvFrmNum = ((u16RealQPtr % 2) == 0) ? 1 : 0; // need to check the next frame num is exist when get first frame. if (u16RealQPtr != u16QPtr) { if (u16RealQPtr > u16QPtr) { u16UsedFrm = u16RealQPtr - u16QPtr; } else { u16UsedFrm = pShm->u16DispQSize - (u16QPtr - u16RealQPtr); } } if (u16QNum > (u16UsedFrm + u16ResvFrmNum)) { u16QNum -= u16UsedFrm; u16QPtr = u16RealQPtr; pHvdFrm = (HVD_Frm_Information*)&pShm->DispQueue[u16QPtr]; if (pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) // Must Be { if ((u16QPtr % 2) == 0) { HVD_Frm_Information *pHvdFrmNext = (HVD_Frm_Information*)&pShm->DispQueue[u16QPtr + 1]; if (pHvdFrmNext->u32Status != E_HVD_DISPQ_STATUS_INIT) { return NULL; } //ALOGE("G1: %x", pHvdFrm->u32PrivateData); if(bDolbyVision) { HVD_PRINT("BL pts: %d, u16QPtr: %d, u16QNum:%d, u32PrivateData:%d %d %d %d\n",pHvdFrm->u32TimeStamp, u16QPtr, u16QNum, pHvdFrm->u32PrivateData, pShm->u16DispQNumb, pShm->u16DispQPtr, u16UsedFrm); } pHVDHalContext->_stHVDStream[u8Idx].u32PrivateData = pHvdFrm->u32PrivateData; } else { //ALOGE("G2: %x", (pHvdFrm->u32PrivateData << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32PrivateData); //pShm->UpdateQueue[pShm->u16UpdateQWtPtr] = (pHvdFrm->u32PrivateData << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32PrivateData; //pShm->u16UpdateQWtPtr = (pShm->u16UpdateQWtPtr + 1) % HVD_DISP_QUEUE_MAX_SIZE; HVD_Frm_Information *pHvdFrmPrv = (HVD_Frm_Information*)&pShm->DispQueue[u16QPtr - 1]; // must be odd if(bDolbyVision) { HVD_PRINT("EL pts: %d, u16QPtr: %d, u16QNum:%d, uid:%d %d %d %d\n",pHvdFrm->u32TimeStamp, u16QPtr, u16QNum, pHvdFrm->u32PrivateData, pShm->u16DispQNumb, pShm->u16DispQPtr, u16UsedFrm); #if 0 // dump dolby metadata calculated by FW unsigned char *dump_addr = (unsigned char *)((void *)pShm + pShm->u32HVD_DBG_DUMP_ADDR - (u8Idx * 0x100000 + HVD_SHARE_MEM_ST_OFFSET)); HVD_Frm_Information_EXT_Entry *pFrmInfoExt = NULL; HVD_Frm_Information_EXT *pVsyncBridgeExt = (HVD_Frm_Information_EXT *)HAL_HVD_EX_GetDispQExtShmAddr(u32Id); unsigned int i = 0; unsigned char arr[33] = {0}; if(pVsyncBridgeExt != NULL) { pFrmInfoExt = &(pVsyncBridgeExt->stEntry[u16QPtr]); } dump_addr += 32 * pFrmInfoExt->u8CurrentIndex; for (i = 0; i < 32; i++) { arr[i] = *(dump_addr + i); } HVD_PRINT("[md5]%d=%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x %02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x", (unsigned int)pFrmInfoExt->u8CurrentIndex, arr[0], arr[1], arr[2], arr[3], arr[4], arr[5], arr[6], arr[7], arr[8], arr[9], arr[10], arr[11], arr[12], arr[13], arr[14], arr[15], arr[16], arr[17], arr[18], arr[19], arr[20], arr[21], arr[22], arr[23], arr[24], arr[25], arr[26], arr[27], arr[28], arr[29], arr[30], arr[31]); #endif HVD_Frm_Information *pPrevHvdFrm = (HVD_Frm_Information*)&pShm->DispQueue[u16QPtr - 1];//BL if(DIFF(pPrevHvdFrm->u32TimeStamp, pHvdFrm->u32TimeStamp) > 1000) HVD_EX_MSG_ERR("BL pts: %d, EL pts: %d matched failed!!\n",pPrevHvdFrm->u32TimeStamp, pHvdFrm->u32TimeStamp); } pHvdFrmPrv->u32Status = E_HVD_DISPQ_STATUS_VIEW; pHvdFrm->u32Status = E_HVD_DISPQ_STATUS_VIEW; HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_UPDATE_DISPQ, (pHvdFrm->u32PrivateData << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32PrivateData); } pHVDHalContext->_u16DispOutSideQPtr[u8Idx] = u16QPtr; u16QPtr++; if (u16QPtr == pShm->u16DispQSize) u16QPtr = 0; pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex = u16QPtr; return (HVD_Frm_Information*)(MS_VIRT)pHvdFrm; } } return NULL; } //printf("OQ:%d,DQ:%d.\n",pShm->u16DispQNumb,pShm->u16DecQNumb); //search the next frame to display while (u16QNum > 0) { //printf("Pr:%d,%d.[%ld,%ld,%ld,%ld].\n",u16QPtr,u16QNum,pShm->DispQueue[u16QPtr].u32Status,pShm->DispQueue[u16QPtr+1].u32Status, // pShm->DispQueue[u16QPtr+2].u32Status,pShm->DispQueue[u16QPtr+3].u32Status); pHVDHalContext->pHvdFrm = (HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; //printf("Q2: %ld\n", pHVDShareMem->DispQueue[u16QPtr].u32Status); if (pHVDHalContext->pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) { /// For MVC. Output views after the pair of (base and depend) views were decoded. /// Check the depned view was initial when Output the base view. if((u16QPtr%2) == 0) { HVD_Frm_Information *pHvdFrm_sub = (HVD_Frm_Information *) &pShm->DispQueue[u16QPtr+1]; //if(pHvdFrm_sub->u32Status != E_HVD_DISPQ_STATUS_INIT) if(pHvdFrm_sub->u32Status == E_HVD_DISPQ_STATUS_NONE) { ///printf("[MVC] %d is not E_HVD_DISPQ_STATUS_INIT (%ld).\n",u16QPtr+1,pHvdFrm_sub->u32Status); ///printf("Return NULL.\n"); return NULL; } } //printf("V:%d.\n",u16QPtr); pHVDHalContext->_u16DispQPtr = u16QPtr; pHVDHalContext->pHvdFrm->u32Status = E_HVD_DISPQ_STATUS_VIEW; /////Change its state!! HVD_EX_MSG_DBG("FrameDone: %d, pHvdFrm=0x%lx, timestamp=%d\n", u16QPtr, (unsigned long) pHVDHalContext->pHvdFrm, pShm->DispQueue[u16QPtr].u32TimeStamp); HVD_EX_MSG_INF("<<< halHVD pts,idH = %lu, %lu [%x]\n", (unsigned long) pHVDHalContext->pHvdFrm->u32TimeStamp, (unsigned long) pHVDHalContext->pHvdFrm->u32ID_H, u16QPtr); //STS output return (HVD_Frm_Information *)(MS_VIRT) pHVDHalContext->pHvdFrm; } u16QNum--; //go to next frame in the dispQ u16QPtr++; if (u16QPtr >= pShm->u16DispQSize) { u16QPtr -= pShm->u16DispQSize; //wrap to the begin } } } else #endif ///HVD_ENABLE_MVC // pShm->DispInfo.u8Interlace : 0 = progressive, 1 = interlace field, 2 = interlace frame if (_HVD_EX_IsHevcInterlaceField(u32Id)) { MS_U32 first_field = pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex == 1 ? 0 : 1; HVD_Frm_Information *pHvdFrm_first = NULL; if ((first_field && u16QNum < 2) || (u16QNum == 0)) { return NULL; } while (u16QNum != 0) { pHvdFrm = (HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; if (pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) // Must Be { if (!first_field) // second get frame, we will check at least one paired in disp queue. { pHvdFrm->u32Status = E_HVD_DISPQ_STATUS_VIEW; HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_UPDATE_DISPQ, pHvdFrm->u32PrivateData); pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex = 0; if(pHvdFrm->u8FieldType == EVD_TOP_FIELD || pHvdFrm->u8FieldType == EVD_TOP_WITH_PREV || pHvdFrm->u8FieldType == EVD_TOP_WITH_NEXT) pHvdFrm->u8FieldType = 1; // 1 = E_VDEC_EX_FIELDTYPE_TOP else pHvdFrm->u8FieldType = 2; // 2 = E_VDEC_EX_FIELDTYPE_BOTTOM return pHvdFrm; } else // first get frame, we will check at least one paired in disp queue. { if (pHvdFrm_first == NULL) { pHvdFrm_first = pHvdFrm; } else { pHvdFrm_first->u32Status = E_HVD_DISPQ_STATUS_VIEW; HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_UPDATE_DISPQ, pHvdFrm_first->u32PrivateData); if (pHvdFrm_first->u8FieldType == EVD_TOP_WITH_PREV || pHvdFrm_first->u8FieldType == EVD_BOTTOM_WITH_PREV) { if (pHvdFrm_first->u8FieldType == EVD_TOP_WITH_PREV && pHvdFrm->u8FieldType == EVD_BOTTOM_WITH_NEXT) { pHvdFrm_first->u32ID_L |= (1 << 16); pHvdFrm->u32ID_L |= (1 << 16); } else if (pHvdFrm_first->u8FieldType == EVD_BOTTOM_WITH_PREV && pHvdFrm->u8FieldType == EVD_TOP_WITH_NEXT) { pHvdFrm_first->u32ID_L &= (~(1 << 16)); pHvdFrm->u32ID_L &= (~(1 << 16)); } else { HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_RELEASE_DISPQ, pHvdFrm_first->u32PrivateData); return NULL; } } else { if (hevc_get_paired(pHvdFrm->u8FieldType, 0) != pHvdFrm_first->u8FieldType) { HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_RELEASE_DISPQ, pHvdFrm_first->u32PrivateData); return NULL; } } pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex = 1; if (pHvdFrm_first->u8FieldType == EVD_TOP_FIELD || pHvdFrm_first->u8FieldType == EVD_TOP_WITH_PREV || pHvdFrm_first->u8FieldType == EVD_TOP_WITH_NEXT) pHvdFrm_first->u8FieldType = 1; // 1 = E_VDEC_EX_FIELDTYPE_TOP else pHvdFrm_first->u8FieldType = 2; // 2 = E_VDEC_EX_FIELDTYPE_BOTTOM return pHvdFrm_first; } } } u16QNum--; //go to next frame in the dispQ u16QPtr++; if (u16QPtr == pShm->u16DispQSize) { u16QPtr = 0; //wrap to the begin } } return NULL; } else { if (pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { while (u16QNum != 0) { pHvdFrm = (HVD_Frm_Information*) &pShm->DispQueue[u16QPtr]; if (pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) // Must Be { pHVDHalContext->_u16DispOutSideQPtr[u8Idx] = u16QPtr; pHvdFrm->u32Status = E_HVD_DISPQ_STATUS_VIEW; HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_UPDATE_DISPQ, pHvdFrm->u32PrivateData); return (HVD_Frm_Information*)(MS_VIRT)pHvdFrm; } u16QNum--; //go to next frame in the dispQ if (bDolbyVision) u16QPtr += 2; // single layer must in even ptr else u16QPtr++; if (u16QPtr >= pShm->u16DispQSize) { u16QPtr = 0; //wrap to the begin } } return NULL; } //printf("Q: %d %d\n", u16QNum, u16QPtr); //search the next frame to display while (u16QNum != 0) { pHVDHalContext->pHvdFrm = (HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; //printf("Q2: %ld\n", pHVDShareMem->DispQueue[u16QPtr].u32Status); if (pHVDHalContext->pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) { pHVDHalContext->_u16DispQPtr = u16QPtr; pHVDHalContext->pHvdFrm->u32Status = E_HVD_DISPQ_STATUS_VIEW; /////Change its state!! HVD_EX_MSG_DBG("FrameDone: %d, pHvdFrm=0x%lx, timestamp=%d\n", u16QPtr, (unsigned long) pHVDHalContext->pHvdFrm, pShm->DispQueue[u16QPtr].u32TimeStamp); HVD_EX_MSG_INF("<<< halHVD pts,idH = %u, %u [%x]\n", pHVDHalContext->pHvdFrm->u32TimeStamp, pHVDHalContext->pHvdFrm->u32ID_H, u16QPtr); //STS output return (HVD_Frm_Information *)(MS_VIRT) pHVDHalContext->pHvdFrm; } u16QNum--; //go to next frame in the dispQ u16QPtr++; if (u16QPtr == pShm->u16DispQSize) { u16QPtr = 0; //wrap to the begin } } } return NULL; } static HVD_Frm_Information_EXT_Entry *_HVD_EX_GetNextDispFrameExt(MS_U32 u32Id) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_Frm_Information_EXT_Entry *pFrmInfoExt = NULL; if (pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { HVD_Frm_Information_EXT *pVsyncBridgeExt = (HVD_Frm_Information_EXT *)HAL_HVD_EX_GetDispQExtShmAddr(u32Id); if(pVsyncBridgeExt != NULL) { pFrmInfoExt = &(pVsyncBridgeExt->stEntry[pHVDHalContext->_u16DispOutSideQPtr[u8Idx]]); } } return pFrmInfoExt; } static MS_U64 _HAL_EX_GetHwMaxPixel(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U64 u64Ret = 0; #if SUPPORT_EVD MS_BOOL isEVD = _HAL_EX_IS_EVD(pCtrl->InitParams.u32ModeFlag); if (isEVD) { u64Ret = (MS_U64)HEVC_HW_MAX_PIXEL; } else #endif #if SUPPORT_G2VP9 if (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u64Ret = (MS_U64)VP9_HW_MAX_PIXEL; } else #endif { u64Ret = (MS_U64)HVD_HW_MAX_PIXEL; } return u64Ret; } MS_BOOL HAL_HVD_EX_DispFrameAllViewed(MS_U32 u32Id) { HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U16 u16QNum = pShm->u16DispQNumb; MS_U16 u16QPtr = pShm->u16DispQPtr; static volatile HVD_Frm_Information *pHvdFrm = NULL; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL bDolbyVision = (E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)); MS_BOOL bMVC = FALSE; #if HVD_ENABLE_MVC bMVC = HAL_HVD_EX_CheckMVCID(u32Id); #endif if (bMVC || (bDolbyVision && !pShm->bSingleLayer) || _HVD_EX_IsHevcInterlaceField(u32Id)) { if (u16QNum == 1) return TRUE; } while (u16QNum != 0) { pHvdFrm = (volatile HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; if (pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) { return FALSE; } u16QNum--; if (bDolbyVision) u16QPtr += 2; // single layer must in even ptr else u16QPtr++; if (u16QPtr >= pShm->u16DispQSize) { u16QPtr = 0; //wrap to the begin } } return TRUE; } static HVD_EX_Drv_Ctrl *_HVD_EX_GetDrvCtrl(MS_U32 u32Id) { MS_U8 u8DrvId = (0xFF & (u32Id >> 16)); return &(_pHVDCtrls[u8DrvId]); } MS_U8 _HVD_EX_GetStreamIdx(MS_U32 u32Id) { MS_U8 u8OffsetIdx = 0; MS_U8 u8SidBaseMask = 0xF0; HAL_HVD_StreamId eSidBase = (HAL_HVD_StreamId) (u32Id >> 8 & u8SidBaseMask); switch (eSidBase) { case E_HAL_HVD_MAIN_STREAM_BASE: { u8OffsetIdx = 0; break; } case E_HAL_VPU_SUB_STREAM_BASE: { u8OffsetIdx = 1; break; } case E_HAL_VPU_MVC_STREAM_BASE: { u8OffsetIdx = 0; break; } #ifdef VDEC3 case E_HAL_VPU_N_STREAM_BASE: { u8OffsetIdx = (u32Id>>8) & 0xF; break; } #endif default: { u8OffsetIdx = 0; break; } } return u8OffsetIdx; } /* static MS_BOOL _HAL_HVD_EX_HVDInUsed(void) { MS_U32 i = 0; for(i = 0; i < HAL_HVD_EX_MAX_SUPPORT_STREAM; i++) { if(TRUE == pHVDHalContext->_stHVDStream[i].bUsed) { return TRUE; } } return FALSE; } */ MS_VIRT HAL_HVD_EX_GetShmAddr(MS_U32 u32Id) { MS_PHY u32PhyAddr = 0x0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if (pCtrl->MemMap.u32CodeBufAddr == 0) { return 0; } u32PhyAddr = HAL_VPU_EX_GetShareInfoAddr(u32Id); if (u32PhyAddr == 0xFFFFFFFF) //boris { u32PhyAddr = pCtrl->MemMap.u32CodeBufAddr + (HAL_VPU_EX_GetTaskId(u32Id) * HVD_FW_MEM_OFFSET) + HVD_SHARE_MEM_ST_OFFSET; } else { // TEE, common + share_info u32PhyAddr += COMMON_AREA_SIZE; } return MsOS_PA2KSEG1(u32PhyAddr); } MS_VIRT HAL_HVD_EX_GetDispQExtShmAddr(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (pCtrl->MemMap.u32CodeBufAddr == 0 || pShm == NULL) { return 0; } MS_PHY u32PhyAddr = 0x0; #if 0 u32PhyAddr = HAL_VPU_EX_GetShareInfoAddr(u32Id); if (u32PhyAddr == 0xFFFFFFFF) { u32PhyAddr = pCtrl->MemMap.u32CodeBufAddr + (HAL_VPU_EX_GetTaskId(u32Id) * HVD_FW_MEM_OFFSET); } #endif u32PhyAddr = pCtrl->MemMap.u32CodeBufAddr; u32PhyAddr += pShm->u32DISPQUEUE_EXT_ST_ADDR; //with HVD_FW_MEM_OFFSET return MsOS_PA2KSEG1(u32PhyAddr); } void HAL_HVD_MIF1_MiuClientSel(MS_U8 u8MiuSel) { if (u8MiuSel == E_CHIP_MIU_0) { _HVD_WriteWordMask(MIU0_CLIENT_SELECT_GP4, 0, MIU0_CLIENT_SELECT_GP4_HVD_MIF1); } else if (u8MiuSel == E_CHIP_MIU_1) { _HVD_WriteWordMask(MIU0_CLIENT_SELECT_GP4, MIU0_CLIENT_SELECT_GP4_HVD_MIF1, MIU0_CLIENT_SELECT_GP4_HVD_MIF1); } } #if SUPPORT_G2VP9 && defined(VDEC3) #ifdef __ARM_NEON__ #include static void tile4x4_to_raster_8(MS_U8* raster, MS_U8* tile, MS_U32 stride, MS_U32 tile_w, MS_U32 tile_h) { uint32x4x4_t data, data2; MS_U8* raster2 = raster + tile_w * 4; data = vld4q_u32((const uint32_t *)tile); data2 = vld4q_u32((const uint32_t *)(tile + tile_w * tile_h * 4)); vst1q_u32((uint32_t *)raster, data.val[0]); raster += stride; vst1q_u32((uint32_t *)raster, data.val[1]); raster += stride; vst1q_u32((uint32_t *)raster, data.val[2]); raster += stride; vst1q_u32((uint32_t *)raster, data.val[3]); vst1q_u32((uint32_t *)raster2, data2.val[0]); raster2 += stride; vst1q_u32((uint32_t *)raster2, data2.val[1]); raster2 += stride; vst1q_u32((uint32_t *)raster2, data2.val[2]); raster2 += stride; vst1q_u32((uint32_t *)raster2, data2.val[3]); } #else static void tile4x4_to_raster_4(MS_U8* raster, MS_U8* tile, MS_U32 stride) { MS_U8* tile0 = tile; MS_U8* tile1 = tile+16; MS_U8* tile2 = tile+32; MS_U8* tile3 = tile+48; int i; for (i=0; i<4; i++) { raster[i] = tile0[i]; raster[4+i] = tile1[i]; raster[8+i] = tile2[i]; raster[12+i] = tile3[i]; } for (i=0; i<4; i++) { raster[stride+i] = tile0[4+i]; raster[stride+4+i] = tile1[4+i]; raster[stride+8+i] = tile2[4+i]; raster[stride+12+i] = tile3[4+i]; } for (i=0; i<4; i++) { raster[2*stride+i] = tile0[8+i]; raster[2*stride+4+i] = tile1[8+i]; raster[2*stride+8+i] = tile2[8+i]; raster[2*stride+12+i] = tile3[8+i]; } for (i=0; i<4; i++) { raster[3*stride+i] = tile0[12+i]; raster[3*stride+4+i] = tile1[12+i]; raster[3*stride+8+i] = tile2[12+i]; raster[3*stride+12+i] = tile3[12+i]; } } #endif // #ifdef __ARM_NEON__ static MS_BOOL _HVD_EX_PpTask_Create(MS_U32 u32Id, HVD_EX_Stream *pstHVDStream) { MS_S32 s32HvdPpTaskId = MsOS_CreateTask((TaskEntry)_HAL_HVD_EX_PostProc_Task, u32Id, E_TASK_PRI_MEDIUM, TRUE, NULL, 32, // stack size.. "HVD_PostProcess_task"); if (s32HvdPpTaskId < 0) { HVD_EX_MSG_ERR("Pp Task create failed\n"); return FALSE; } HVD_EX_MSG_DBG("Pp Task create success\n"); pstHVDStream->s32HvdPpTaskId = s32HvdPpTaskId; return TRUE; } static MS_U32 tile_offset(MS_U32 x, MS_U32 y, MS_U32 w, MS_U32 h, MS_U32 stride) { return y * stride * h + x * w * h; } static MS_U32 raster_offset(MS_U32 x, MS_U32 y, MS_U32 w, MS_U32 h, MS_U32 stride) { return y * stride * h + x * w; } static void tile4x4_to_raster(MS_U8* raster, MS_U8* tile, MS_U32 stride) { raster[0] = tile[0]; raster[1] = tile[1]; raster[2] = tile[2]; raster[3] = tile[3]; raster[stride] = tile[4]; raster[stride + 1] = tile[5]; raster[stride + 2] = tile[6]; raster[stride + 3] = tile[7]; raster[2 * stride] = tile[8]; raster[2 * stride + 1] = tile[9]; raster[2 * stride + 2] = tile[10]; raster[2 * stride + 3] = tile[11]; raster[3 * stride] = tile[12]; raster[3 * stride + 1] = tile[13]; raster[3 * stride + 2] = tile[14]; raster[3 * stride + 3] = tile[15]; } static void tiled4x4pic_to_raster_new(MS_U8* dst, MS_U8* src, MS_U32 w, MS_U32 h, MS_U32 raster_stride) { const MS_U32 tile_w = 4; const MS_U32 tile_h = 4; MS_U32 tile_stride = w; MS_U32 x, y; MS_U8 *dst1, *dst2; MS_U8 *src1, *src2; #ifdef __ARM_NEON__ // To overlap load and store, handle two blocks at the same time. dst1 = dst; src1 = src; for (y = 0; y < h / tile_h; y++) { dst2 = dst1; src2 = src1; for (x = 0; x <= (w/tile_w - 8); x+=8) { tile4x4_to_raster_8( dst2, src2, raster_stride, tile_w, tile_h); dst2 += tile_w * 8; src2 += tile_w * tile_h * 8; } dst1 += raster_stride * tile_h; src1 += tile_stride * tile_h; for (; x < w / tile_w; x++) { tile4x4_to_raster( dst + raster_offset(x, y, tile_w, tile_h, raster_stride), src + tile_offset(x, y, tile_w, tile_h, tile_stride), raster_stride); } } #else dst1 = NULL; src1 = NULL; dst2 = NULL; src2 = NULL; for (y = 0; y < h / tile_h; y++) { for (x = 0; x <= (w/tile_w - 4); x+=4) { tile4x4_to_raster_4( dst + raster_offset(x, y, tile_w, tile_h, raster_stride), src + tile_offset(x, y, tile_w, tile_h, tile_stride), raster_stride); } for (; x < w / tile_w; x++) { tile4x4_to_raster( dst + raster_offset(x, y, tile_w, tile_h, raster_stride), src + tile_offset(x, y, tile_w, tile_h, tile_stride), raster_stride); } } #endif } #define FLUSH_CACHE_SIZE (256 * 1024) static void _HAL_HVD_EX_Inv_Cache(void *pVA, MS_U32 u32Size) { // To improve performance, just flush the first FLUSH_CACHE_SIZE bytes of data if (u32Size > FLUSH_CACHE_SIZE) u32Size = FLUSH_CACHE_SIZE; MsOS_MPool_Dcache_Flush((MS_VIRT)pVA, u32Size); } static void _HAL_HVD_EX_Flush_Cache(void *pVA, MS_U32 u32Size) { MS_U32 u32SkipSize = 0; // To improve performance, just flush the last FLUSH_CACHE_SIZE bytes of data if (u32Size > FLUSH_CACHE_SIZE) { u32SkipSize = u32Size - FLUSH_CACHE_SIZE; u32Size = FLUSH_CACHE_SIZE; } MsOS_MPool_Dcache_Flush(((MS_VIRT)pVA) + u32SkipSize, u32Size); } static MS_BOOL _HAL_HVD_EX_PostProc_Task(MS_U32 u32Id) { HVD_EX_Stream *pstHVDStream = pHVDHalContext->_stHVDStream + _HVD_EX_GetStreamIdx(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U32 u32SrcMiuSel, u32DstMiuSel; MS_U16 u16Width = 0, u16Height = 0, u16TileWidth = 0; HVD_EX_MSG_DBG("[%s-%d] Start\n", __FUNCTION__, __LINE__); pstHVDStream->ePpTaskState = E_HAL_HVD_STATE_RUNNING; while (pstHVDStream->ePpTaskState != E_HAL_HVD_STATE_STOP) { if (pstHVDStream->ePpTaskState == E_HAL_HVD_STATE_PAUSING) pstHVDStream->ePpTaskState = E_HAL_HVD_STATE_PAUSE_DONE; HVD_Delay_ms(1); // FIXME if (pstHVDStream->ePpTaskState != E_HAL_HVD_STATE_RUNNING) continue; HAL_HVD_EX_ReadMemory(); while (pShm->u8PpQueueRPtr != pShm->u8PpQueueWPtr) { MS_U8 *pSrcVA, *pDstVA; MS_U32 u32SrcPA, u32DstPA; HVD_Frm_Information *pFrmInfo = (HVD_Frm_Information *)&pShm->DispQueue[pShm->u8PpQueueRPtr]; //HVD_EX_MSG_DBG("[%s-%d] width: %d, height = %d, pitch = %d\n", __FUNCTION__, __LINE__, pFrmInfo->u16Width, pFrmInfo->u16Height, pFrmInfo->u16Pitch); if ((u16Width != pFrmInfo->u16Width) || (u16Height != pFrmInfo->u16Height)) { HVD_Display_Info *pDispInfo = (HVD_Display_Info *) HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_DISP_INFO_ADDR); u16Width = pFrmInfo->u16Width; u16Height = pFrmInfo->u16Height; u16TileWidth = NEXT_MULTIPLE(pFrmInfo->u16Pitch - pDispInfo->u16CropRight, 8); } // Luma u32SrcMiuSel = (pShm->u32VDEC_MIU_SEL >> VDEC_PPIN_MIUSEL) & VDEC_MIUSEL_MASK; u32DstMiuSel = (pShm->u32VDEC_MIU_SEL >> VDEC_LUMA8_MIUSEL) & VDEC_MIUSEL_MASK; _miu_offset_to_phy(u32SrcMiuSel, pFrmInfo->u32PpInLumaAddr, u32SrcPA); _miu_offset_to_phy(u32DstMiuSel, pFrmInfo->u32LumaAddr, u32DstPA); pSrcVA = (MS_U8*) MS_PA2KSEG0(u32SrcPA); pDstVA = (MS_U8*) MS_PA2KSEG0(u32DstPA); _HAL_HVD_EX_Inv_Cache(pSrcVA, u16TileWidth * pFrmInfo->u16Height); tiled4x4pic_to_raster_new(pDstVA, pSrcVA, u16TileWidth, pFrmInfo->u16Height, pFrmInfo->u16Pitch); _HAL_HVD_EX_Flush_Cache(pDstVA, pFrmInfo->u16Pitch * pFrmInfo->u16Height); // Chroma u32SrcMiuSel = (pShm->u32VDEC_MIU_SEL >> VDEC_PPIN_MIUSEL) & VDEC_MIUSEL_MASK; u32DstMiuSel = (pShm->u32VDEC_MIU_SEL >> VDEC_CHROMA8_MIUSEL) & VDEC_MIUSEL_MASK; _miu_offset_to_phy(u32SrcMiuSel, pFrmInfo->u32PpInChromaAddr, u32SrcPA); _miu_offset_to_phy(u32DstMiuSel, pFrmInfo->u32ChromaAddr, u32DstPA); pSrcVA = (MS_U8*) MS_PA2KSEG0(u32SrcPA); pDstVA = (MS_U8*) MS_PA2KSEG0(u32DstPA); _HAL_HVD_EX_Inv_Cache(pSrcVA, u16TileWidth * pFrmInfo->u16Height / 2); tiled4x4pic_to_raster_new(pDstVA, pSrcVA, u16TileWidth, pFrmInfo->u16Height/2, pFrmInfo->u16Pitch); _HAL_HVD_EX_Flush_Cache(pDstVA, pFrmInfo->u16Pitch * pFrmInfo->u16Height / 2); pShm->DispQueue[pShm->u8PpQueueRPtr].u32Status = E_HVD_DISPQ_STATUS_INIT; HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_INC_DISPQ_NUM, 0); INC_VALUE(pShm->u8PpQueueRPtr, pShm->u8PpQueueSize); HAL_HVD_EX_FlushMemory(); if (pstHVDStream->ePpTaskState == E_HAL_HVD_STATE_PAUSING) break; HAL_HVD_EX_ReadMemory(); } } HVD_EX_MSG_DBG("[%s-%d] End\n", __FUNCTION__, __LINE__); return TRUE; } #endif static void HAL_HVD_EX_VP8AECInUsed(MS_U32 u32Id, MS_BOOL *isVP8Used, MS_BOOL *isAECUsed , MS_BOOL *isAVCUsed) { MS_U8 i ; MS_U8 u8DrvId = (0xFF & (u32Id >> 16)); for (i = 0; i < HAL_HVD_EX_MAX_SUPPORT_STREAM ; i++) { if( _pHVDCtrls[i].bUsed && (i != u8DrvId)) { MS_U32 u32TempModeFlag = (_pHVDCtrls[i].InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) ; if((E_HVD_INIT_HW_VP8 == u32TempModeFlag)) { *isVP8Used = TRUE ; } else if((E_HVD_INIT_HW_VP9 == u32TempModeFlag) || (E_HVD_INIT_HW_AVS == u32TempModeFlag)) { *isAECUsed = TRUE ; } else if((E_HVD_INIT_HW_AVC == u32TempModeFlag)) { *isAVCUsed = TRUE ; } } } } MS_BOOL HAL_HVD_EX_InitHW(MS_U32 u32Id,VPU_EX_DecoderType DecoderType) { #ifndef VDEC3 MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL isVP8Used = FALSE; MS_BOOL isAECUsed = FALSE; MS_BOOL isAVCUsed = FALSE; HAL_HVD_EX_VP8AECInUsed(u32Id, &isVP8Used, &isAECUsed, &isAVCUsed); // MS_U8 u8MiuSel; // MS_U32 u32StartOffset; #if SUPPORT_EVD MS_BOOL isEVD = _HAL_EX_IS_EVD(pCtrl->InitParams.u32ModeFlag); #else MS_BOOL isEVD = FALSE; #endif MS_BOOL isHVD = !isEVD; //patch for enable evd in AVC because AVC may enable mf_codec which need evd registers isEVD = isEVD || (E_HVD_INIT_HW_AVC== (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)); // power on / reset HVD; set nal, es rw, bbu parser, release HVD engine // re-setup clock. #if SUPPORT_G2VP9 && defined(VDEC3) if (E_HVD_INIT_HW_VP9 != (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) #endif if (isHVD) { if (!HAL_VPU_EX_HVDInUsed()) { printf("HVD power on\n"); HAL_HVD_EX_PowerCtrl(u32Id, TRUE); } if(!isVP8Used && (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK))) { HAL_VP8_PowerCtrl(TRUE); } else if(!isAECUsed && (E_HVD_INIT_HW_AVS == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK))) { HAL_AEC_PowerCtrl(TRUE); } #ifdef CONFIG_MSTAR_SRAMPD _HVD_WriteByteMask(REG_HICODEC_SRAM_SD_EN, HICODEC_SRAM_HICODEC1, HICODEC_SRAM_HICODEC1); HVD_Delay_ms(1); #endif } #if SUPPORT_EVD #ifdef VDEC3 if (isEVD) /// Disable it for disable H264 IMI { if (!HAL_VPU_EX_EVDInUsed()) { printf("EVD power on\n"); HAL_EVD_EX_PowerCtrl(u32Id, TRUE); } if(!isAECUsed && (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK))) { HAL_AEC_PowerCtrl(TRUE); } } #endif #endif #if SUPPORT_G2VP9 && defined(VDEC3) if (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { if (!HAL_VPU_EX_G2VP9InUsed()) { printf("G2 VP9 power on\n"); HAL_VP9_EX_PowerCtrl(TRUE); } } #endif if ((!HAL_VPU_EX_HVDInUsed()) ) { pHVDHalContext->_stHVDStream[0].u32BBUWptr = 0; //main pHVDHalContext->_stHVDStream[1].u32BBUWptr = 0; //sub pHVDHalContext->u32VP8BBUWptr = 0; //VP8 _HVD_EX_ResetMainSubBBUWptr(u32Id); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_RESET_SWRST, HVD_REG_RESET_SWRST); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_RESET_IDB_MIU_256 , HVD_REG_RESET_IDB_MIU_256); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_MC_MIU_256 , HVD_REG_MC_MIU_256); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_RESET_MIU_256 , HVD_REG_RESET_MIU_256); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_RESET_MIU1_256 , HVD_REG_RESET_MIU1_256); _HVD_WriteWordMask(HVD_REG_RESET, 0 , HVD_REG_RESET_MIU_128); _HVD_WriteWordMask(HVD_REG_RESET, 0 , HVD_REG_RESET_MIU1_128); #if 0 if((pHVDHalContext->pHVDPreCtrl_Hal[_HVD_EX_GetStreamIdx(u32Id)]->stIapGnShBWMode.bEnable) && ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_AVC)) { _phy_to_miu_offset(u8MiuSel, u32StartOffset, pHVDHalContext->pHVDPreCtrl_Hal[_HVD_EX_GetStreamIdx(u32Id)]->stIapGnShBWMode.u32IapGnBufAddr); _HAL_HVD_Entry(); HAL_HVD_MIF1_MiuClientSel(u8MiuSel); _HAL_HVD_Release(); } #endif } #if SUPPORT_EVD if (isEVD) { #ifdef VDEC3 if (!HAL_VPU_EX_EVDInUsed()) #endif _HVD_WriteWordMask(EVD_REG_RESET, EVD_REG_RESET_SWRST, EVD_REG_RESET_SWRST); } #endif #if SUPPORT_G2VP9 && defined(VDEC3) if (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { if (!HAL_VPU_EX_G2VP9InUsed()) _HVD_WriteWordMask(VP9_REG_RESET, VP9_REG_RESET_SWRST, VP9_REG_RESET_SWRST); } #endif if(pCtrl == NULL) { HVD_EX_MSG_ERR("HAL_HVD_EX_InitHW Ctrl is NULL.\n"); //return FALSE; goto RESET; } #if SUPPORT_EVD if (isEVD && ((E_HVD_INIT_HW_AVC != (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) )) { #ifdef VDEC3 if (!HAL_VPU_EX_EVDInUsed()) #endif { if (E_HVD_INIT_HW_HEVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) _HVD_WriteWordMask(EVD_REG_RESET, EVD_REG_RESET_HK_HEVC_MODE, EVD_REG_RESET_HK_HEVC_MODE); } if ((E_HVD_INIT_MAIN_LIVE_STREAM == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_MAIN_MASK)) ||(E_HVD_INIT_MAIN_FILE_TS == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_MAIN_MASK))) { #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_WriteWordMask(EVD_REG_RESET, EVD_REG_RESET_HK_TSP2EVD_EN, EVD_REG_RESET_HK_TSP2EVD_EN); //for main-DTV mode } else { _HVD_WriteWordMask(EVD_REG_RESET, EVD_REG_RESET_USE_HVD_MIU_EN, EVD_REG_RESET_USE_HVD_MIU_EN); //for sub-DTV mode } } goto RESET; } #endif // HVD4, from JANUS and later chip switch ((pCtrl->InitParams.u32ModeFlag) & E_HVD_INIT_HW_MASK) { case E_HVD_INIT_HW_AVS: { #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_HK_AVS_MODE | HVD_REG_RESET_HK_RM_MODE); } else { _HVD_WriteWordMask(HVD_REG_MODE_BS2, 0, HVD_REG_MODE_HK_AVS_MODE_BS2 | HVD_REG_MODE_HK_RM_MODE_BS2); } break; } case E_HVD_INIT_HW_RM: { #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_HK_AVS_MODE | HVD_REG_RESET_HK_RM_MODE); if (pCtrl->InitParams.pRVFileInfo->RV_Version) // RV 9,10 { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_HK_RV9_DEC_MODE); } else // RV 8 { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_HK_RV9_DEC_MODE); } } else { _HVD_WriteWordMask(HVD_REG_MODE_BS2, 0, HVD_REG_MODE_HK_AVS_MODE_BS2 | HVD_REG_MODE_HK_RM_MODE_BS2); if (pCtrl->InitParams.pRVFileInfo->RV_Version) // RV 9,10 { _HVD_WriteWordMask(HVD_REG_MODE_BS2, 0, HVD_REG_MODE_HK_RV9_DEC_MODE_BS2); } else // RV 8 { _HVD_WriteWordMask(HVD_REG_MODE_BS2, 0, HVD_REG_MODE_HK_RV9_DEC_MODE_BS2); } } break; } default: { #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_HK_AVS_MODE | HVD_REG_RESET_HK_RM_MODE); } else { _HVD_WriteWordMask(HVD_REG_MODE_BS2, 0, HVD_REG_MODE_HK_AVS_MODE_BS2 | HVD_REG_MODE_HK_RM_MODE_BS2); } break; } } RESET: #if 0 //use miu256bit HVD_EX_MSG_DBG("(be)Miu128 bits Status = %x <<<<<<<\n", _HVD_Read2Byte(HVD_REG_RESET)); if (!HAL_VPU_EX_HVDInUsed()) { _HVD_Write2Byte(HVD_REG_RESET, (_HVD_Read2Byte(HVD_REG_RESET) | HVD_REG_RESET_MIU_128)); } HVD_EX_MSG_DBG("(af)Miu128 bits Status = %x <<<<<<<\n", _HVD_Read2Byte(HVD_REG_RESET)); #endif #if SUPPORT_EVD if (isEVD) { #ifdef VDEC3 if (!HAL_VPU_EX_EVDInUsed()) #endif { printf("EVD miu 256 bits\n"); _HVD_Write2Byte(EVD_REG_RESET, (_HVD_Read2Byte(EVD_REG_RESET) & ~EVD_REG_RESET_MIU0_128 & ~EVD_REG_RESET_MIU1_128)); _HVD_Write2Byte(EVD_REG_RESET, (_HVD_Read2Byte(EVD_REG_RESET) | EVD_REG_RESET_MIU0_256 | EVD_REG_RESET_MIU1_256)); _HVD_Write2Byte(REG_CLK_EVD, (_HVD_Read2Byte(REG_CLK_EVD) & ~REG_CLK_EVD_SW_OV_EN & ~REG_CLK_EVD_PPU_SW_OV_EN));//set 0 firmware //_HVD_Write2Byte(REG_CLK_EVD, (_HVD_Read2Byte(REG_CLK_EVD) | REG_CLK_EVD_SW_OV_EN | REG_CLK_EVD_PPU_SW_OV_EN));//set 1 driver printf("EVD BBU 256 bits\n"); _HVD_Write2Byte(EVD_BBU_MIU_SETTING, (_HVD_Read2Byte(EVD_BBU_MIU_SETTING) & ~REG_BBU_MIU_128)); _HVD_Write2Byte(EVD_BBU_MIU_SETTING, (_HVD_Read2Byte(EVD_BBU_MIU_SETTING) | REG_BBU_MIU_256)); } } #endif #if 0 //defined(SUPPORT_NEW_MEM_LAYOUT) || defined(SUPPORT_NEW_VDEC_FLOW) // Only ES buffer addrress needs to be set for VP8 _HVD_EX_SetESBufferAddr(u32Id); #else if(DecoderType != E_VPU_EX_DECODER_MVD) { _HVD_EX_SetBufferAddr(u32Id); } #endif if (!HAL_VPU_EX_HVDInUsed()) { _HVD_WriteWordMask(HVD_REG_RESET, 0, HVD_REG_RESET_SWRST); } #if SUPPORT_EVD if (isEVD) { #ifdef VDEC3 if (!HAL_VPU_EX_EVDInUsed()) #endif _HVD_WriteWordMask(EVD_REG_RESET, 0, EVD_REG_RESET_SWRST); } #endif #if SUPPORT_G2VP9 && defined(VDEC3) if (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (!HAL_VPU_EX_G2VP9InUsed()) _HVD_WriteWordMask(VP9_REG_RESET, 0, VP9_REG_RESET_SWRST); if (pShm->u8FrmPostProcSupport & E_HVD_POST_PROC_DETILE) _HVD_EX_PpTask_Create(u32Id, &pHVDHalContext->_stHVDStream[_HVD_EX_GetStreamIdx(u32Id)]); } #endif return TRUE; } MS_BOOL HAL_HVD_EX_DeinitHW(MS_U32 u32Id) { MS_U16 u16Timeout = 1000; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL isVP8Used = FALSE; MS_BOOL isAECUsed = FALSE; MS_BOOL isAVCUsed = FALSE; HAL_HVD_EX_VP8AECInUsed(u32Id, &isVP8Used, &isAECUsed , &isAVCUsed); #if SUPPORT_EVD if(!isAVCUsed && E_HVD_INIT_HW_AVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) && !HAL_VPU_EX_EVDInUsed()) { HAL_EVD_EX_DeinitHW(u32Id);//no AVC/EVD use , close EVD power } #endif if(TRUE == HAL_VPU_EX_HVDInUsed()) { #if 0 //Power control close Vp8 register in dynamic ,but bs4-nal-ready could be off.(Patch for maxim and maserati) if(!isVP8Used && E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_VP8_PowerCtrl(FALSE); } else #endif if(!isAECUsed && E_HVD_INIT_HW_AVS == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_AEC_PowerCtrl(FALSE); } return FALSE; } else { _HVD_EX_SetMIUProtectMask(TRUE); _HVD_WriteWordMask(HVD_REG_RESET, HVD_REG_RESET_SWRST, HVD_REG_RESET_SWRST); while (u16Timeout) { if ((_HVD_Read2Byte(HVD_REG_RESET) & (HVD_REG_RESET_SWRST_FIN)) == (HVD_REG_RESET_SWRST_FIN)) { break; } u16Timeout--; } HAL_HVD_EX_PowerCtrl(u32Id, FALSE); //Power control close Vp8 register in dynamic ,but bs4-nal-ready could be off.(Patch for maxim and maserati) HAL_VP8_PowerCtrl(FALSE); #if 0 if(!isVP8Used && E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_VP8_PowerCtrl(FALSE); } else #endif if(!isAECUsed && E_HVD_INIT_HW_AVS == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_AEC_PowerCtrl(FALSE); } #ifdef CONFIG_MSTAR_SRAMPD _HVD_WriteByteMask(REG_HICODEC_SRAM_SD_EN, ~HICODEC_SRAM_HICODEC1, HICODEC_SRAM_HICODEC1); HVD_Delay_ms(1); #endif _HVD_EX_SetMIUProtectMask(FALSE); return TRUE; } return FALSE; } void HAL_HVD_EX_FlushMemory(void) { MsOS_FlushMemory(); } void HAL_HVD_EX_ReadMemory(void) { MsOS_ReadMemory(); } void HAL_HVD_EX_SetDrvCtrlsBase(HVD_EX_Drv_Ctrl *pHVDCtrlsBase) { _pHVDCtrls = pHVDCtrlsBase; } void HAL_HVD_EX_CheckMIUSel(MS_BOOL bChange) { return; } MS_U32 HAL_HVD_EX_GetHWVersionID(void) { return _HVD_Read2Byte(HVD_REG_REV_ID); } MS_BOOL HAL_HVD_EX_Init_Share_Mem(void) { #if (defined(MSOS_TYPE_LINUX) || defined(MSOS_TYPE_ECOS) || defined(MSOS_TYPE_LINUX_KERNEL)) #if !defined(SUPPORT_X_MODEL_FEATURE) MS_U32 u32ShmId; MS_VIRT u32Addr; MS_U32 u32BufSize; if (FALSE == MsOS_SHM_GetId( (MS_U8*)"Linux HVD HAL", sizeof(HVD_Hal_CTX), &u32ShmId, &u32Addr, &u32BufSize, MSOS_SHM_QUERY)) { if (FALSE == MsOS_SHM_GetId((MS_U8*)"Linux HVD HAL", sizeof(HVD_Hal_CTX), &u32ShmId, &u32Addr, &u32BufSize, MSOS_SHM_CREATE)) { HVD_EX_MSG_ERR("[%s]SHM allocation failed!!!use global structure instead!!!\n",__FUNCTION__); if(pHVDHalContext == NULL) { pHVDHalContext = &gHVDHalContext; memset(pHVDHalContext,0,sizeof(HVD_Hal_CTX)); _HVD_EX_Context_Init_HAL(); HVD_PRINT("[%s]Global structure init Success!!!\n",__FUNCTION__); } else { HVD_PRINT("[%s]Global structure exists!!!\n",__FUNCTION__); } //return FALSE; } else { memset((MS_U8*)u32Addr,0,sizeof(HVD_Hal_CTX)); pHVDHalContext = (HVD_Hal_CTX*)u32Addr; // for one process _HVD_EX_Context_Init_HAL(); } } else { pHVDHalContext = (HVD_Hal_CTX*)u32Addr; // for another process } #else if(pHVDHalContext == NULL) { pHVDHalContext = &gHVDHalContext; memset(pHVDHalContext,0,sizeof(HVD_Hal_CTX)); _HVD_EX_Context_Init_HAL(); } #endif _HAL_HVD_MutexCreate(); #else if(pHVDHalContext == NULL) { pHVDHalContext = &gHVDHalContext; memset(pHVDHalContext,0,sizeof(HVD_Hal_CTX)); _HVD_EX_Context_Init_HAL(); } #endif return TRUE; } HAL_HVD_StreamId HAL_HVD_EX_GetFreeStream(HAL_HVD_StreamType eStreamType) { MS_U32 i = 0; if (eStreamType == E_HAL_HVD_MVC_STREAM) { if ((FALSE == pHVDHalContext->_stHVDStream[0].bUsed) && (FALSE == pHVDHalContext->_stHVDStream[1].bUsed)) return pHVDHalContext->_stHVDStream[0].eStreamId; } else if (eStreamType == E_HAL_HVD_MAIN_STREAM) { for (i = 0; i < ((E_HAL_HVD_MAIN_STREAM_MAX - E_HAL_HVD_MAIN_STREAM_BASE) + (E_HAL_HVD_SUB_STREAM_MAX - E_HAL_HVD_SUB_STREAM_BASE)); i++) { if ((E_HAL_HVD_MAIN_STREAM_BASE & pHVDHalContext->_stHVDStream[i].eStreamId) && (FALSE == pHVDHalContext->_stHVDStream[i].bUsed)) { return pHVDHalContext->_stHVDStream[i].eStreamId; } } } else if (eStreamType == E_HAL_HVD_SUB_STREAM) { for (i = 0; i < ((E_HAL_HVD_MAIN_STREAM_MAX - E_HAL_HVD_MAIN_STREAM_BASE) + (E_HAL_HVD_SUB_STREAM_MAX - E_HAL_HVD_SUB_STREAM_BASE)); i++) { if ((E_HAL_HVD_SUB_STREAM_BASE & pHVDHalContext->_stHVDStream[i].eStreamId) && (FALSE == pHVDHalContext->_stHVDStream[i].bUsed)) { return pHVDHalContext->_stHVDStream[i].eStreamId; } } } #ifdef VDEC3 else if ((eStreamType >= E_HAL_HVD_N_STREAM) && (eStreamType < E_HAL_HVD_N_STREAM + HAL_HVD_EX_MAX_SUPPORT_STREAM)) { i = eStreamType - E_HAL_HVD_N_STREAM; if (!pHVDHalContext->_stHVDStream[i].bUsed) return pHVDHalContext->_stHVDStream[i].eStreamId; } #endif return E_HAL_HVD_STREAM_NONE; } static void HAL_VP8_PowerCtrl(MS_BOOL bEnable) { if (bEnable) { _HVD_WriteWordMask(REG_TOP_VP8, ~TOP_CKG_VP8_DIS, TOP_CKG_VP8_DIS); switch (pHVDHalContext->u32HVDClockType) { case 384: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_288MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 345: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_288MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 320: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_288MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 288: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_288MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 240: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_240MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 216: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_216MHZ, TOP_CKG_VP8_CLK_MASK); break; } case 172: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_216MHZ, TOP_CKG_VP8_CLK_MASK); break; } default: { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_288MHZ, TOP_CKG_VP8_CLK_MASK); break; } } } else { _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_DIS, TOP_CKG_VP8_DIS); } } static void HAL_AEC_PowerCtrl(MS_BOOL bEnable) { if (bEnable) { _HVD_WriteWordMask(REG_TOP_HVD_AEC, ~TOP_CKG_HVD_AEC_DIS, TOP_CKG_HVD_AEC_DIS); switch (pHVDHalContext->u32HVDClockType) { case 384: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_288MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 345: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_288MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 320: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_288MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 288: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_288MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 240: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_240MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 216: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_216MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } case 172: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_216MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } default: { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_288MHZ, TOP_CKG_HVD_AEC_CLK_MASK); break; } } } else { _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_DIS, TOP_CKG_HVD_AEC_DIS); } } void HAL_HVD_EX_PowerCtrl(MS_U32 u32Id, MS_BOOL bEnable) { if (bEnable) { _HVD_WriteWordMask(REG_TOP_HVD, ~TOP_CKG_HVD_DIS, TOP_CKG_HVD_DIS); //_HVD_WriteWordMask(REG_TOP_HVD_IDB, ~TOP_CKG_HVD_IDB_DIS, TOP_CKG_HVD_IDB_DIS); } else { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_DIS, TOP_CKG_HVD_DIS); //_HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_DIS, TOP_CKG_HVD_IDB_DIS); } // fix to not inverse _HVD_WriteWordMask(REG_TOP_HVD, ~TOP_CKG_HVD_INV, TOP_CKG_HVD_INV); switch (pHVDHalContext->u32HVDClockType) { #if 0 //for overclocking case 432: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_432MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_480MHZ, TOP_CKG_HVD_IDB_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_AEC, TOP_CKG_HVD_AEC_320MHZ, TOP_CKG_HVD_AEC_CLK_MASK); _HVD_WriteWordMask(REG_TOP_VP8, TOP_CKG_VP8_320MHZ, TOP_CKG_VP8_CLK_MASK); break; } #endif case 384: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_384MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_432MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 345: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_345MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_384MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 320: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_320MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_345MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 288: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_288MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_320MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 240: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_240MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_288MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 216: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_216MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_240MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } case 172: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_172MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_216MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } default: { _HVD_WriteWordMask(REG_TOP_HVD, TOP_CKG_HVD_384MHZ, TOP_CKG_HVD_CLK_MASK); _HVD_WriteWordMask(REG_TOP_HVD_IDB, TOP_CKG_HVD_IDB_432MHZ, TOP_CKG_HVD_IDB_CLK_MASK); break; } } return; } void HAL_HVD_EX_InitRegBase(MS_VIRT u32RegBase) { u32HVDRegOSBase = u32RegBase; HAL_VPU_EX_InitRegBase(u32RegBase); } void HAL_HVD_EX_SetPreCtrlVariables(MS_U32 u32Id,MS_VIRT drvprectrl) { HVD_Pre_Ctrl *pHVDPreCtrl_in = (HVD_Pre_Ctrl*)drvprectrl; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); pHVDHalContext->pHVDPreCtrl_Hal[u8Idx] = pHVDPreCtrl_in; } HVD_Return HAL_HVD_EX_InitVariables(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = NULL; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); #if HVD_ENABLE_MVC MS_BOOL bMVC = HAL_HVD_EX_CheckMVCID(u32Id); #endif ///HVD_ENABLE_MVC pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr = 0; pHVDHalContext->_stHVDStream[u8Idx].u32PTSByteCnt = 0; pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum = 0; pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex = 0; pHVDHalContext->_stHVDStream[u8Idx].u32FreeData = 0xFFFF; pHVDHalContext->_stHVDStream[u8Idx].bfirstGetFrmInfoDone = TRUE; int i; for(i = 0; i_s32VDEC_BBU_TaskId[i] = -1; #if HVD_ENABLE_MVC if(bMVC) { pHVDHalContext->_stHVDStream[u8Idx+1].u32PTSPreWptr = 0; pHVDHalContext->_stHVDStream[u8Idx+1].u32PTSByteCnt = 0; pHVDHalContext->_stHVDStream[u8Idx+1].u32BBUWptr = 0; pHVDHalContext->_stHVDStream[u8Idx+1].u32BBUEntryNum = 0; } #endif ///HVD_ENABLE_MVC // set a local copy of FW code address; assuming there is only one copy of FW, // no matter how many task will be created. pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); memset((void *) (pHVDHalContext->g_hvd_nal_fill_pair), 0, 16); // global variables pHVDHalContext->u32HVDCmdTimeout = pCtrl->u32CmdTimeout; // pHVDHalContext->u32VPUClockType = (MS_U32) pCtrl->InitParams.u16DecoderClock; // pHVDHalContext->u32HVDClockType = (MS_U32) pCtrl->InitParams.u16DecoderClock; // Create mutex //_HAL_HVD_MutexCreate(); // fill HVD init variables if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum = VP8_BBU_DRAM_TBL_ENTRY; pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNumTH = VP8_BBU_DRAM_TBL_ENTRY_TH; } else #if HVD_ENABLE_RV_FEATURE if (((pCtrl->InitParams.u32ModeFlag) & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) { pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum = RVD_BBU_DRAM_TBL_ENTRY; pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNumTH = RVD_BBU_DRAM_TBL_ENTRY_TH; #ifdef VDEC3_FB pHVDHalContext->u32RV_VLCTableAddr = 0; #else if (pCtrl->MemMap.u32FrameBufSize > RV_VLC_TABLE_SIZE) { pHVDHalContext->u32RV_VLCTableAddr = pCtrl->MemMap.u32FrameBufSize - RV_VLC_TABLE_SIZE; pCtrl->MemMap.u32FrameBufSize -= RV_VLC_TABLE_SIZE; } else { HVD_EX_MSG_ERR("HAL_HVD_EX_InitVariables failed: frame buffer size too small. FB:%x min:%x\n", (MS_U32) pCtrl->MemMap.u32FrameBufSize, (MS_U32) RV_VLC_TABLE_SIZE); return E_HVD_RETURN_INVALID_PARAMETER; } #endif } else #endif { pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum = HVD_BBU_DRAM_TBL_ENTRY; pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNumTH = HVD_BBU_DRAM_TBL_ENTRY_TH; #if HVD_ENABLE_MVC if(bMVC) { pHVDHalContext->_stHVDStream[u8Idx+1].u32BBUEntryNum = MVC_BBU_DRAM_TBL_ENTRY; pHVDHalContext->_stHVDStream[u8Idx+1].u32BBUEntryNumTH = MVC_BBU_DRAM_TBL_ENTRY_TH; } #endif /// HVD_ENABLE_MVC pHVDHalContext->u32RV_VLCTableAddr = 0; } if ((HAL_VPU_EX_GetShareInfoAddr(u32Id) != 0xFFFFFFFF) || ((MS_VIRT) (pCtrl->MemMap.u32CodeBufVAddr <= (MS_VIRT) pShm) && ((MS_VIRT) pShm <= (pCtrl->MemMap.u32CodeBufVAddr + pCtrl->MemMap.u32CodeBufSize))) || ((MS_VIRT) (pCtrl->MemMap.u32BitstreamBufVAddr <= (MS_VIRT) pShm) && ((MS_VIRT) pShm <= (pCtrl->MemMap.u32BitstreamBufVAddr + pCtrl->MemMap.u32BitstreamBufSize))) || ((MS_VIRT) (pCtrl->MemMap.u32FrameBufVAddr <= (MS_VIRT) pShm) && ((MS_VIRT) pShm <= (pCtrl->MemMap.u32FrameBufVAddr + pCtrl->MemMap.u32FrameBufSize)))) { HVD_EX_MSG_DBG("input memory: Code addr=0x%lx, Bits addr=0x%lx, FB addr=0x%lx, Miu1base=0x%lx, Miu2base=0x%lx\n", (unsigned long)pCtrl->MemMap.u32CodeBufAddr, (unsigned long)pCtrl->MemMap.u32FrameBufAddr, (unsigned long)pCtrl->MemMap.u32BitstreamBufAddr, (unsigned long)pCtrl->MemMap.u32MIU1BaseAddr, (unsigned long)pCtrl->MemMap.u32MIU2BaseAddr); #if HVD_ENABLE_MVC if(bMVC) { HVD_EX_Drv_Ctrl *pHVDCtrl_in_sub = _HVD_EX_GetDrvCtrl(u32Id+0x00011000); if (( (pHVDCtrl_in_sub->MemMap.u32BitstreamBufVAddr) <= (MS_VIRT)pShm)&& ( (MS_VIRT)pShm <= ((pHVDCtrl_in_sub->MemMap.u32BitstreamBufVAddr )+ pHVDCtrl_in_sub->MemMap.u32BitstreamBufSize))) { HVD_EX_MSG_DBG("[MVC] Bitstream2: 0x%lx.\n", (unsigned long) pCtrl->MemMap.u32BitstreamBufAddr); } } #endif /// HVD_ENABLE_MVC return E_HVD_RETURN_SUCCESS; } else { HVD_EX_MSG_ERR("failed: Shm addr=0x%lx, Code addr=0x%lx, Bits addr=0x%lx, FB addr=0x%lx, Miu1base=0x%lx, Miu2base=0x%lx\n", (unsigned long)MS_VA2PA((MS_VIRT)pShm), (unsigned long)pCtrl->MemMap.u32CodeBufAddr, (unsigned long)pCtrl->MemMap.u32FrameBufAddr, (unsigned long)pCtrl->MemMap.u32BitstreamBufAddr, (unsigned long)pCtrl->MemMap.u32MIU1BaseAddr, (unsigned long)pCtrl->MemMap.u32MIU2BaseAddr); return E_HVD_RETURN_INVALID_PARAMETER; } } #ifdef VDEC3 HVD_Return HAL_HVD_EX_InitShareMem(MS_U32 u32Id, MS_BOOL bFWdecideFB, MS_BOOL bCMAUsed) #else HVD_Return HAL_HVD_EX_InitShareMem(MS_U32 u32Id) #endif { MS_U32 u32Addr = 0; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U32 u32TmpStartOffset; MS_U8 u8TmpMiuSel; memset(pShm, 0, sizeof(HVD_ShareMem)); _phy_to_miu_offset(u8TmpMiuSel, u32Addr, pCtrl->MemMap.u32FrameBufAddr); pShm->u32FrameRate = pCtrl->InitParams.u32FrameRate; pShm->u32FrameRateBase = pCtrl->InitParams.u32FrameRateBase; #ifdef VDEC3 if (bFWdecideFB || bCMAUsed) { pShm->u32FrameBufAddr = 0; pShm->u32FrameBufSize = 0; } else #endif { pShm->u32FrameBufAddr = u32Addr; pShm->u32FrameBufSize = pCtrl->MemMap.u32FrameBufSize; } // FIXME: need to use the avaliable task resource instead of using next task resource if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC_DV) pShm->u8ExternalHeapIdx = u8Idx + 1; else pShm->u8ExternalHeapIdx = 0xFF; pShm->DispInfo.u16DispWidth = 1; pShm->DispInfo.u16DispHeight = 1; pShm->u32CodecType = pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK; pShm->u32CPUClock = pHVDHalContext->u32VPUClockType; pShm->u32UserCCIdxWrtPtr = 0xFFFFFFFF; pShm->DispFrmInfo.u32TimeStamp = 0xFFFFFFFF; //Chip info pShm->u16ChipID = E_MSTAR_CHIP_MAXIM; pShm->u16ChipECONum = pCtrl->InitParams.u16ChipECONum; // PreSetControl if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->bOnePendingBuffer) { pShm->u32PreSetControl |= PRESET_ONE_PENDING_BUFFER; } if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->bCalFrameRate) { pShm->u32PreSetControl |= PRESET_CAL_FRAMERATE; } pShm->bUseTSPInBBUMode = FALSE; if ((pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stIapGnShBWMode.bEnable) && ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_AVC)) { pShm->u32PreSetControl |= PRESET_IAP_GN_SHARE_BW_MODE; _phy_to_miu_offset(u8TmpMiuSel, u32Addr, pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stIapGnShBWMode.u32IapGnBufAddr); pShm->u32IapGnBufAddr = u32Addr; pShm->u32IapGnBufSize = pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stIapGnShBWMode.u32IapGnBufSize; } pShm->u8CodecFeature &= ~E_VDEC_MFCODEC_MASK; switch(pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->eMFCodecMode) { case E_HVD_DEF_MFCODEC_DEFAULT: pShm->u8CodecFeature |= E_VDEC_MFCODEC_DEFAULT; break; case E_HVD_DEF_MFCODEC_FORCE_ENABLE: pShm->u8CodecFeature |= E_VDEC_MFCODEC_FORCE_ENABLE; break; case E_HVD_DEF_MFCODEC_FORCE_DISABLE: pShm->u8CodecFeature |= E_VDEC_MFCODEC_FORCE_DISABLE; break; default: pShm->u8CodecFeature |= E_VDEC_MFCODEC_DEFAULT; } pShm->u8CodecFeature &= ~E_VDEC_DOLBY_VISION_SINGLE_LAYER_MODE; if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->bDVSingleLayerMode) pShm->u8CodecFeature |= E_VDEC_DOLBY_VISION_SINGLE_LAYER_MODE; pShm->u8CodecFeature &= ~E_VDEC_FORCE_8BITS_MASK; if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->bForce8BitMode) pShm->u8CodecFeature |= E_VDEC_FORCE_8BITS_MODE; pShm->u8CodecFeature &= ~E_VDEC_FORCE_MAIN_PROFILE_MASK; if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->eVdecFeature & 1) pShm->u8CodecFeature |= E_VDEC_FORCE_MAIN_PROFILE; if ((pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stPreConnectDispPath.bEnable)) { pShm->u32PreSetControl |= PRESET_CONNECT_DISPLAY_PATH; pShm->stDynmcDispPath.u8Connect = pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stPreConnectDispPath.stDynmcDispPath.bConnect; pShm->stDynmcDispPath.u8DispPath = (MS_U8)(pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stPreConnectDispPath.stDynmcDispPath.eMvopPath); pShm->stDynmcDispPath.u8ConnectStatus = E_DISP_PATH_DYNMC_HANDLING; HVD_EX_MSG_DBG("[NDec][0x%x][%d] preset mvop, connect %d, path 0x%x \n", u32Id, u8Idx, pShm->stDynmcDispPath.u8Connect, pShm->stDynmcDispPath.u8DispPath); } else { pShm->u32PreSetControl |= PRESET_CONNECT_DISPLAY_PATH; MS_U8 u8Connect = FALSE; MS_U8 u8Path = E_CTL_DISPLAY_PATH_NONE; switch (pCtrl->eStream) { case E_HVD_ORIGINAL_MAIN_STREAM: u8Connect = TRUE; u8Path = E_CTL_DISPLAY_PATH_MVOP_0; break; case E_HVD_ORIGINAL_SUB_STREAM: u8Connect = TRUE; u8Path = E_CTL_DISPLAY_PATH_MVOP_1; break; case E_HVD_ORIGINAL_N_STREAM: default: u8Connect = FALSE; u8Path = E_CTL_DISPLAY_PATH_NONE; break; } pShm->stDynmcDispPath.u8Connect = u8Connect; pShm->stDynmcDispPath.u8DispPath = u8Path; pShm->stDynmcDispPath.u8ConnectStatus = E_DISP_PATH_DYNMC_HANDLING; HVD_EX_MSG_DBG("[NDec][0x%x][%d] no preset mvop, connect %d, path 0x%x \n", u32Id, u8Idx, pShm->stDynmcDispPath.u8Connect, u8Path); } if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { if ((pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stPreConnectInputTsp.bEnable)) { pShm->u32PreSetControl |= PRESET_CONNECT_INPUT_TSP; pShm->u8InputTSP = pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->stPreConnectInputTsp.u8InputTsp; HVD_EX_MSG_DBG("[NDec][0x%x][%d] preset tsp, input %d \n", u32Id, u8Idx, pShm->u8InputTSP); } else { pShm->u32PreSetControl |= PRESET_CONNECT_INPUT_TSP; MS_U8 u8Input = E_CTL_INPUT_TSP_NONE; switch (pCtrl->eStream) { case E_HVD_ORIGINAL_MAIN_STREAM: u8Input = E_CTL_INPUT_TSP_0; break; case E_HVD_ORIGINAL_SUB_STREAM: u8Input = E_CTL_INPUT_TSP_1; break; case E_HVD_ORIGINAL_N_STREAM: default: u8Input = E_CTL_INPUT_TSP_NONE; break; } pShm->u8InputTSP = u8Input; HVD_EX_MSG_DBG("[NDec][0x%x][%d] no preset tsp, input %d \n", u32Id, u8Idx, pShm->u8InputTSP); } } else { HVD_EX_MSG_DBG("[NDec][0x%x][%d] not TSP input, ignore PRESET_CONNECT_INPUT_TSP \n", u32Id, u8Idx); } //pShm->bColocateBBUMode = pCtrl->InitParams.bColocateBBUMode;//johnny.ko //pShm->bColocateBBUMode = _stHVDPreSet[u8Idx].bColocateBBUMode;//johnny.ko if(_stHVDPreSet[u8Idx].bColocateBBUMode) pShm->u8BBUMode = E_HVD_FW_AUTO_BBU_MODE; else pShm->u8BBUMode = E_HVD_DRV_AUTO_BBU_MODE; if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_MAIN_MASK) == E_HVD_INIT_MAIN_FILE_RAW) { if((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_DUAL_ES_MASK) == E_HVD_INIT_DUAL_ES_ENABLE) { pShm->u8SrcMode = E_HVD_SRC_MODE_FILE_DUAL_ES; } else { pShm->u8SrcMode = E_HVD_SRC_MODE_FILE; } } else if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_MAIN_MASK) == E_HVD_INIT_MAIN_FILE_TS) { if((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_DUAL_ES_MASK) == E_HVD_INIT_DUAL_ES_ENABLE) { pShm->u8SrcMode = E_HVD_SRC_MODE_TS_FILE_DUAL_ES; } else { pShm->u8SrcMode = E_HVD_SRC_MODE_TS_FILE; } } else { pShm->u8SrcMode = E_HVD_SRC_MODE_DTV; } if (E_HVD_INIT_HW_AVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { pShm->bHVDIMIEnable = TRUE; //AVC FW enable IMI only for 4k2k } #if 0 if (pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->bEnableDynamicCMA) { pShm->u8CodecFeature |= E_VDEC_DYNAMIC_CMA_MODE; } #endif if((E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_HEVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_AVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_AVS == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_RM == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_MJPEG== (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_MVC== (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) || (E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK))) { pShm->bUseWbMvop = 1; } if (E_HVD_INIT_HW_HEVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) || E_HVD_INIT_HW_AVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { if(!(pHVDHalContext->pHVDPreCtrl_Hal[u8Idx]->eVdecFeature & E_HVD_DEF_FEATURE_DISABLE_TEMPORAL_SCALABILITY)) pShm->u8CodecFeature |= E_VDEC_TEMPORAL_SCALABILITY_MODE; } #if 1//From T4 and the later chips, QDMA can support the address more than MIU1 base. #if (VPU_FORCE_MIU_MODE) _phy_to_miu_offset(u8TmpMiuSel, u32TmpStartOffset, pCtrl->MemMap.u32CodeBufAddr); pShm->u32FWBaseAddr = u32TmpStartOffset; #else ///TODO: /* _phy_to_miu_offset(u8TmpMiuSel, u32TmpStartOffset, pCtrl->MemMap.u32CodeBufAddr); if(u8TmpMiuSel == E_CHIP_MIU_0) { pShm->u32FWBaseAddr = pCtrl->MemMap.u32CodeBufAddr; } else if(u8TmpMiuSel == E_CHIP_MIU_1) { pShm->u32FWBaseAddr = u32TmpStartOffset | 0x40000000; ///TODO: } else if(u8TmpMiuSel == E_CHIP_MIU_2) { pShm->u32FWBaseAddr = u32TmpStartOffset | 0x80000000; ///TODO: } */ #endif //printf("QDMA Addr = %lx <<<<<<<<<<<<<<<<<<<<<<<<\n",pShm->u32FWBaseAddr); #else u32Addr = pCtrl->MemMap.u32CodeBufAddr; if (u32Addr >= pCtrl->MemMap.u32MIU1BaseAddr) { u32Addr -= pCtrl->MemMap.u32MIU1BaseAddr; } pShm->u32FWBaseAddr = u32Addr; #endif // RM only #if HVD_ENABLE_RV_FEATURE if ((((pCtrl->InitParams.u32ModeFlag) & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_RM) && (pCtrl->InitParams.pRVFileInfo != NULL)) { MS_U32 i = 0; for (i = 0; i < HVD_RM_INIT_PICTURE_SIZE_NUMBER; i++) { pShm->pRM_PictureSize[i].u16Width = pCtrl->InitParams.pRVFileInfo->ulPicSizes_w[i]; pShm->pRM_PictureSize[i].u16Height = pCtrl->InitParams.pRVFileInfo->ulPicSizes_h[i]; } pShm->u8RM_Version = (MS_U8) pCtrl->InitParams.pRVFileInfo->RV_Version; pShm->u8RM_NumSizes = (MS_U8) pCtrl->InitParams.pRVFileInfo->ulNumSizes; #ifdef VDEC3_FB pShm->u32RM_VLCTableAddr = 0; // HVD_EX_MSG_DBG("===== Set pShm->u32RM_VLCTableAddr = 0 in InitShareMem\n"); #else u32Addr = pCtrl->MemMap.u32FrameBufAddr + pHVDHalContext->u32RV_VLCTableAddr; _phy_to_miu_offset(u8TmpMiuSel, u32TmpStartOffset, u32Addr); u32Addr = u32TmpStartOffset; pShm->u32RM_VLCTableAddr = u32Addr; #endif } #endif if ((E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) && (pCtrl->InitParams.pRVFileInfo != NULL)) { pShm->pRM_PictureSize[0].u16Width = pCtrl->InitParams.pRVFileInfo->ulPicSizes_w[0]; pShm->pRM_PictureSize[0].u16Height = pCtrl->InitParams.pRVFileInfo->ulPicSizes_h[0]; } //if(pCtrl->InitParams.bColocateBBUMode) if(_stHVDPreSet[u8Idx].bColocateBBUMode) { pShm->u32ColocateBBUWritePtr = pShm->u32ColocateBBUReadPtr = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr; } #if SUPPORT_G2VP9 // Enable SW detile support for G2 VP9 if (E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { pShm->u8FrmPostProcSupport |= E_HVD_POST_PROC_DETILE; } #endif HAL_HVD_EX_FlushMemory(); return E_HVD_RETURN_SUCCESS; } #ifdef VDEC3 HVD_Return HAL_HVD_EX_InitRegCPU(MS_U32 u32Id, MS_BOOL bFWdecideFB) #else HVD_Return HAL_HVD_EX_InitRegCPU(MS_U32 u32Id) #endif { MS_BOOL bInitRet = FALSE; #if 0 // check MVD power on if (_HVD_Read2Byte(REG_TOP_MVD) & (TOP_CKG_MHVD_DIS)) { HVD_EX_MSG_INF("HVD warning: MVD is not power on before HVD init.\n"); _HVD_WriteWordMask(REG_TOP_MVD, 0, TOP_CKG_MHVD_DIS); HVD_Delay_ms(1); } // Check VPU power on if (_HVD_Read2Byte(REG_TOP_VPU) & (TOP_CKG_VPU_DIS)) { HVD_EX_MSG_INF("HVD warning: VPU is not power on before HVD init.\n"); _HVD_WriteWordMask(REG_TOP_VPU, 0, TOP_CKG_VPU_DIS); HVD_Delay_ms(1); } // check HVD power on if (_HVD_Read2Byte(REG_TOP_HVD) & (TOP_CKG_HVD_DIS)) { HVD_EX_MSG_INF("HVD warning: HVD is not power on before HVD init.\n"); HAL_HVD_EX_PowerCtrl(TRUE); HVD_Delay_ms(1); } #endif #ifdef VDEC3 bInitRet = _HVD_EX_SetRegCPU(u32Id, bFWdecideFB); #else bInitRet = _HVD_EX_SetRegCPU(u32Id); #endif if (!bInitRet) { return E_HVD_RETURN_FAIL; } bInitRet = HAL_HVD_EX_RstPTSCtrlVariable(u32Id); if (!bInitRet) { return E_HVD_RETURN_FAIL; } return E_HVD_RETURN_SUCCESS; } HVD_Return HAL_HVD_EX_SetHVDColBBUMode(MS_U32 u32Id, MS_BOOL bEnable) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); _stHVDPreSet[u8Idx].bColocateBBUMode = bEnable; return E_HVD_RETURN_SUCCESS; } HVD_Return HAL_HVD_EX_SetData(MS_U32 u32Id, HVD_SetData u32type, MS_VIRT u32Data) { HVD_Return eRet = E_HVD_RETURN_SUCCESS; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_BOOL bMVC = FALSE; #if HVD_ENABLE_MVC bMVC = HAL_HVD_EX_CheckMVCID(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL bDolbyVision = (E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)); switch (u32type) { // share memory // switch case E_HVD_SDATA_FRAMEBUF_ADDR: { pShm->u32FrameBufAddr = u32Data; break; } case E_HVD_SDATA_FRAMEBUF_SIZE: { pShm->u32FrameBufSize = u32Data; break; } case E_HVD_SDATA_FRAMEBUF2_ADDR: { pShm->u32FrameBuf2Addr = u32Data; break; } case E_HVD_SDATA_FRAMEBUF2_SIZE: { pShm->u32FrameBuf2Size = u32Data; break; } case E_HVD_SDATA_MAX_CMA_SIZE: { pShm->u32MaxCMAFrameBufSize = u32Data; break; } case E_HVD_SDATA_MAX_CMA_SIZE2: { pShm->u32MaxCMAFrameBuf2Size = u32Data; break; } case E_HVD_SDATA_CMA_USED: { pShm->bCMA_Use = u32Data; break; } case E_HVD_SDATA_CMA_ALLOC_DONE: { pShm->bCMA_AllocDone = u32Data; break; } case E_HVD_SDATA_CMA_TWO_MIU: { pShm->bCMA_TwoMIU = u32Data; break; } case E_HVD_SDATA_RM_PICTURE_SIZES: { HVD_memcpy((volatile void *) pShm->pRM_PictureSize, (void *) ((HVD_PictureSize *) u32Data), HVD_RM_INIT_PICTURE_SIZE_NUMBER * sizeof(HVD_PictureSize)); break; } case E_HVD_SDATA_ERROR_CODE: { pShm->u16ErrCode = (MS_U16) u32Data; break; } case E_HVD_SDATA_DISP_INFO_TH: { HVD_memcpy((volatile void *) &(pShm->DispThreshold), (void *) ((HVD_DISP_THRESHOLD *) u32Data), sizeof(HVD_DISP_THRESHOLD)); break; } case E_HVD_SDATA_FW_FLUSH_STATUS: { pShm->u8FlushStatus = (MS_U8)u32Data; break; } case E_HVD_SDATA_DMX_FRAMERATE: { pShm->u32DmxFrameRate = u32Data; break; } case E_HVD_SDATA_DMX_FRAMERATEBASE: { pShm->u32DmxFrameRateBase = u32Data; break; } case E_HVD_SDATA_MIU_SEL: { pShm->u32VDEC_MIU_SEL = u32Data; break; } case E_HVD_SDATA_DV_XC_SHM_SIZE: { pShm->u32DolbyVisionXCShmSize = u32Data; break; } // SRAM // Mailbox case E_HVD_SDATA_TRIGGER_DISP: // HVD HI mbox 0 { if (u32Data != 0) { pShm->bEnableDispCtrl = TRUE; pShm->bIsTrigDisp = TRUE; } else { pShm->bEnableDispCtrl = FALSE; } break; } case E_HVD_SDATA_GET_DISP_INFO_START: { pShm->bSpsChange = FALSE; break; } case E_HVD_SDATA_VIRTUAL_BOX_WIDTH: { pShm->u32VirtualBoxWidth = u32Data; break; } case E_HVD_SDATA_DV_INFO: { pShm->u8DVLevelFromDriverAPI = (MS_U8)(u32Data & 0xff); pShm->u8DVProfileFromDriverAPI = (MS_U8)((u32Data >> 8) & 0xff); pShm->u8DolbyMetaReorder = (MS_U8)((u32Data >> 16) & 0xff); break; } case E_HVD_SDATA_VIRTUAL_BOX_HEIGHT: { pShm->u32VirtualBoxHeight = u32Data; break; } case E_HVD_SDATA_DISPQ_STATUS_VIEW: { if (pShm->DispQueue[u32Data].u32Status == E_HVD_DISPQ_STATUS_INIT) { //printf("DispFrame DqPtr: %d\n", u32Data); pShm->DispQueue[u32Data].u32Status = E_HVD_DISPQ_STATUS_VIEW; } break; } case E_HVD_SDATA_DISPQ_STATUS_DISP: { if(!(pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide)) { if (pShm->DispQueue[u32Data].u32Status == E_HVD_DISPQ_STATUS_VIEW) { //printf("DispFrame DqPtr: %ld\n", u32Data); pShm->DispQueue[u32Data].u32Status = E_HVD_DISPQ_STATUS_DISP; } } break; } case E_HVD_SDATA_DISPQ_STATUS_FREE: { if(pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { if (bMVC || (bDolbyVision && !pShm->bSingleLayer)) { if (pHVDHalContext->_stHVDStream[u8Idx].u32FreeData == 0xFFFF) { //ALOGE("R1: %x", u32Data); pHVDHalContext->_stHVDStream[u8Idx].u32FreeData = u32Data; } else { //ALOGE("R2: %x", (u32Data << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32FreeData); HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_RELEASE_DISPQ, (u32Data << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32FreeData); //pShm->FreeQueue[pShm->u16FreeQWtPtr] = (u32Data << 16) | pHVDHalContext->_stHVDStream[u8Idx].u32FreeData; //pShm->u16FreeQWtPtr = (pShm->u16FreeQWtPtr + 1) % HVD_DISP_QUEUE_MAX_SIZE; pHVDHalContext->_stHVDStream[u8Idx].u32FreeData = 0xFFFF; } } else { HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_RELEASE_DISPQ, u32Data); } } else { if (pShm->DispQueue[u32Data].u32Status == E_HVD_DISPQ_STATUS_VIEW) { pShm->DispQueue[u32Data].u32Status = E_HVD_DISPQ_STATUS_FREE; } } break; } case E_HVD_SDATA_HDR_PERFRAME: { if (u32Data != 0) { pShm->u8IsDoblyHDR10 = TRUE; } else { pShm->u8IsDoblyHDR10 = FALSE; } break; } #if (HVD_ENABLE_IQMEM) case E_HVD_SDATA_FW_IQMEM_CTRL: { pShm->u8IQmemCtrl= (MS_U8)u32Data; break; } case E_HVD_SDATA_FW_IQMEM_ENABLE_IF_SUPPORT: { if (u32Data != 0) { pShm->bIQmemEnableIfSupport= TRUE; } else { pShm->bIQmemEnableIfSupport= FALSE; } break; } #endif case E_HVD_SDATA_DYNMC_DISP_PATH_STATUS: { pShm->stDynmcDispPath.u8ConnectStatus = u32Data; break; } case E_HVD_SDATA_VP9HDR10INFO: { int i,j; HVD_Config_VP9HDR10* stVP9HDR10Info = (HVD_Config_VP9HDR10*) u32Data; pShm->VP9HDR10Info.u32Version = stVP9HDR10Info->u32Version; pShm->VP9HDR10Info.u8MatrixCoefficients = stVP9HDR10Info->u8MatrixCoefficients; pShm->VP9HDR10Info.u8BitsPerChannel = stVP9HDR10Info->u8BitsPerChannel; pShm->VP9HDR10Info.u8ChromaSubsamplingHorz = stVP9HDR10Info->u8ChromaSubsamplingHorz; pShm->VP9HDR10Info.u8ChromaSubsamplingVert = stVP9HDR10Info->u8ChromaSubsamplingVert; pShm->VP9HDR10Info.u8CbSubsamplingHorz = stVP9HDR10Info->u8CbSubsamplingHorz; pShm->VP9HDR10Info.u8CbSubsamplingVert = stVP9HDR10Info->u8CbSubsamplingVert; pShm->VP9HDR10Info.u8ChromaSitingHorz = stVP9HDR10Info->u8ChromaSitingHorz; pShm->VP9HDR10Info.u8ChromaSitingVert = stVP9HDR10Info->u8ChromaSitingVert; pShm->VP9HDR10Info.u8ColorRange = stVP9HDR10Info->u8ColorRange; pShm->VP9HDR10Info.u8TransferCharacteristics = stVP9HDR10Info->u8TransferCharacteristics; pShm->VP9HDR10Info.u8ColourPrimaries = stVP9HDR10Info->u8ColourPrimaries; pShm->VP9HDR10Info.u16MaxCLL = stVP9HDR10Info->u16MaxCLL; pShm->VP9HDR10Info.u16MaxFALL = stVP9HDR10Info->u16MaxFALL; pShm->VP9HDR10Info.u32MaxLuminance = stVP9HDR10Info->u32MaxLuminance; pShm->VP9HDR10Info.u32MinLuminance = stVP9HDR10Info->u32MinLuminance; for(i=0;i<2;i++) { pShm->VP9HDR10Info.u16WhitePoint[i] = stVP9HDR10Info->u16WhitePoint[i]; } for(i=0;i<3;i++) { for(j=0;j<2;j++) { pShm->VP9HDR10Info.u16Primaries[i][j] = stVP9HDR10Info->u16Primaries[i][j]; } } pShm->u8VP9HDR10InfoVaild = TRUE; break; } default: break; } HAL_HVD_EX_FlushMemory(); return eRet; } MS_S64 HAL_HVD_EX_GetData_EX(MS_U32 u32Id, HVD_GetData eType) { MS_S64 s64Ret = 0; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); HAL_HVD_EX_ReadMemory(); switch (eType) { case E_HVD_GDATA_PTS_STC_DIFF: s64Ret = pShm->s64PtsStcDiff; break; default: break; } return s64Ret; } MS_VIRT HAL_HVD_EX_GetData(MS_U32 u32Id, HVD_GetData eType) { MS_VIRT u32Ret = 0; //static MS_U64 u64pts_real = 0; MS_U64 u64pts_low = 0; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); HAL_HVD_EX_ReadMemory(); if(pShm == NULL) { printf("########## VDEC patch for Debug ###########\n"); return 0x0; } switch (eType) { // share memory // switch case E_HVD_GDATA_DISP_INFO_ADDR: { u32Ret = (MS_VIRT) (&pShm->DispInfo); break; } case E_HVD_GDATA_MIU_SEL: u32Ret = pShm->u32VDEC_MIU_SEL; break; case E_HVD_GDATA_FRAMEBUF_ADDR: u32Ret = pShm->u32FrameBufAddr; break; case E_HVD_GDATA_FRAMEBUF_SIZE: u32Ret = pShm->u32FrameBufSize; break; case E_HVD_GDATA_FRAMEBUF2_ADDR: u32Ret = pShm->u32FrameBuf2Addr; break; case E_HVD_GDATA_FRAMEBUF2_SIZE: u32Ret = pShm->u32FrameBuf2Size; break; case E_HVD_GDATA_CMA_ALLOC_DONE: u32Ret = pShm->bCMA_AllocDone; break; case E_HVD_GDATA_CMA_USED: u32Ret = pShm->bCMA_Use; break; case E_HVD_GDATA_DYNMC_DISP_PATH_STATUS: u32Ret = pShm->stDynmcDispPath.u8ConnectStatus;//pShm->u8SetDynmcDispPathStatus; break; // report case E_HVD_GDATA_PTS: { u32Ret = pShm->DispFrmInfo.u32TimeStamp; break; } case E_HVD_GDATA_U64PTS: { u64pts_low = (MS_U64)(pShm->DispFrmInfo.u32TimeStamp); pHVDHalContext->u64pts_real = (MS_U64)(pShm->DispFrmInfo.u32ID_H); pHVDHalContext->u64pts_real = (pHVDHalContext->u64pts_real<<32)|u64pts_low; u32Ret = (MS_VIRT)(&(pHVDHalContext->u64pts_real)); break; } case E_HVD_GDATA_U64PTS_PRE_PARSE: { u64pts_low = (MS_U64)(pShm->u32WRPTR_PTS_LOW); pHVDHalContext->u64pts_real = (MS_U64)(pShm->u32WRPTR_PTS_HIGH); pHVDHalContext->u64pts_real = (pHVDHalContext->u64pts_real<<32)|u64pts_low; u32Ret = (MS_VIRT)(&(pHVDHalContext->u64pts_real)); break; } case E_HVD_GDATA_DECODE_CNT: { u32Ret = pShm->u32DecodeCnt; break; } case E_HVD_GDATA_DATA_ERROR_CNT: { u32Ret = pShm->u32DataErrCnt; break; } case E_HVD_GDATA_DEC_ERROR_CNT: { u32Ret = pShm->u32DecErrCnt; break; } case E_HVD_GDATA_ERROR_CODE: { u32Ret = (MS_U32) (pShm->u16ErrCode); break; } case E_HVD_GDATA_VPU_IDLE_CNT: { u32Ret = pShm->u32VPUIdleCnt; break; } case E_HVD_GDATA_DISP_FRM_INFO: { u32Ret = (MS_VIRT) (&pShm->DispFrmInfo); break; } case E_HVD_GDATA_DEC_FRM_INFO: { u32Ret = (MS_VIRT) (&pShm->DecoFrmInfo); break; } case E_HVD_GDATA_ES_LEVEL: { u32Ret = (MS_U32) (_HVD_EX_GetESLevel(u32Id)); break; } #if HVD_ENABLE_MVC case E_HVD_GDATA_DISP_FRM_INFO_SUB: { u32Ret= (MS_VIRT) (&(pShm->DispFrmInfo_Sub)); break; } case E_HVD_GDATA_DEC_FRM_INFO_SUB: { u32Ret= (MS_VIRT) (&(pShm->DecoFrmInfo_Sub)); break; } #endif // user data case E_HVD_GDATA_USERDATA_WPTR: { u32Ret = (MS_U32) (pShm->u32UserCCIdxWrtPtr); break; } case E_HVD_GDATA_USERDATA_IDX_TBL_ADDR: { u32Ret = (MS_VIRT) (pShm->u8UserCCIdx); break; } case E_HVD_GDATA_USERDATA_PACKET_TBL_ADDR: { u32Ret = (MS_VIRT) (pShm->u32UserCCBase); break; } case E_HVD_GDATA_USERDATA_PACKET_SIZE: { u32Ret = (MS_U32) (sizeof(DTV_BUF_type)); break; } case E_HVD_GDATA_USERDATA_IDX_TBL_SIZE: { u32Ret = (MS_U32) (USER_CC_IDX_SIZE); break; } case E_HVD_GDATA_USERDATA_PACKET_TBL_SIZE: { u32Ret = (MS_U32) (USER_CC_DATA_SIZE); break; } // report - modes case E_HVD_GDATA_IS_SHOW_ERR_FRM: { u32Ret = pShm->ModeStatus.bIsShowErrFrm; break; } case E_HVD_GDATA_IS_REPEAT_LAST_FIELD: { u32Ret = pShm->ModeStatus.bIsRepeatLastField; break; } case E_HVD_GDATA_IS_ERR_CONCEAL: { u32Ret = pShm->ModeStatus.bIsErrConceal; break; } case E_HVD_GDATA_IS_SYNC_ON: { u32Ret = pShm->ModeStatus.bIsSyncOn; break; } case E_HVD_GDATA_IS_PLAYBACK_FINISH: { u32Ret = pShm->ModeStatus.bIsPlaybackFinish; break; } case E_HVD_GDATA_SYNC_MODE: { u32Ret = pShm->ModeStatus.u8SyncType; break; } case E_HVD_GDATA_SKIP_MODE: { u32Ret = pShm->ModeStatus.u8SkipMode; break; } case E_HVD_GDATA_DROP_MODE: { u32Ret = pShm->ModeStatus.u8DropMode; break; } case E_HVD_GDATA_DISPLAY_DURATION: { u32Ret = pShm->ModeStatus.s8DisplaySpeed; break; } case E_HVD_GDATA_FRC_MODE: { u32Ret = pShm->ModeStatus.u8FrcMode; break; } case E_HVD_GDATA_NEXT_PTS: { u32Ret = pShm->u32NextPTS; break; } case E_HVD_GDATA_DISP_Q_SIZE: { u32Ret = pShm->u16DispQSize; break; } case E_HVD_GDATA_DISP_Q_PTR: { u32Ret = (MS_U32) pHVDHalContext->_u16DispQPtr; break; } case E_HVD_GDATA_NEXT_DISP_FRM_INFO: { u32Ret = (MS_VIRT) _HVD_EX_GetNextDispFrame(u32Id); break; } case E_HVD_GDATA_NEXT_DISP_FRM_INFO_EXT: { u32Ret = (MS_VIRT) _HVD_EX_GetNextDispFrameExt(u32Id); break; } case E_HVD_GDATA_REAL_FRAMERATE: { // return VPS/VUI timing info framerate, and 0 if timing info not exist u32Ret = pShm->u32RealFrameRate; break; } case E_HVD_GDATA_IS_ORI_INTERLACE_MODE: u32Ret=(MS_U32)pShm->DispInfo.u8IsOriginInterlace; break; case E_HVD_GDATA_FRM_PACKING_SEI_DATA: u32Ret=((MS_VIRT)(pShm->u32Frm_packing_arr_data_addr)); break; case E_HVD_GDATA_DISPLAY_COLOUR_VOLUME_SEI_DATA: u32Ret=((MS_U32)(pShm->u32DisplayColourVolume_addr)); break; case E_HVD_GDATA_CONTENT_LIGHT_LEVEL_INFO: u32Ret=((MS_U32)(pShm->u32ContentLightLevel_addr)); break; case E_HVD_GDATA_TYPE_FRAME_MBS_ONLY_FLAG: u32Ret=((MS_U32)(pShm->u8FrameMbsOnlyFlag)); break; case E_HVD_GDATA_FW_STATUS_FLAG: u32Ret=((MS_U32)(pShm->u32FWStatusFlag)); break; // internal control case E_HVD_GDATA_IS_1ST_FRM_RDY: { u32Ret = pShm->bIs1stFrameRdy; break; } case E_HVD_GDATA_IS_I_FRM_FOUND: { u32Ret = pShm->bIsIFrmFound; break; } case E_HVD_GDATA_IS_SYNC_START: { u32Ret = pShm->bIsSyncStart; break; } case E_HVD_GDATA_IS_SYNC_REACH: { u32Ret = pShm->bIsSyncReach; break; } case E_HVD_GDATA_FW_VERSION_ID: { u32Ret = pShm->u32FWVersionID; break; } case E_HVD_GDATA_FW_IF_VERSION_ID: { u32Ret = pShm->u32FWIfVersionID; break; } case E_HVD_GDATA_BBU_Q_NUMB: { u32Ret = _HVD_EX_GetBBUQNumb(u32Id); break; } case E_HVD_GDATA_DEC_Q_NUMB: { u32Ret = pShm->u16DecQNumb; break; } case E_HVD_GDATA_DISP_Q_NUMB: { u32Ret = pShm->u16DispQNumb; break; } case E_HVD_GDATA_PTS_Q_NUMB: { u32Ret = _HVD_EX_GetPTSQNumb(u32Id); break; } case E_HVD_GDATA_FW_INIT_DONE: { u32Ret = pShm->bInitDone; break; } // debug case E_HVD_GDATA_SKIP_CNT: { u32Ret = pShm->u32SkipCnt; break; } case E_HVD_GDATA_GOP_CNT: { u32Ret = pShm->u32DropCnt; break; } case E_HVD_GDATA_DISP_CNT: { u32Ret = pShm->u32DispCnt; break; } case E_HVD_GDATA_DROP_CNT: { u32Ret = pShm->u32DropCnt; break; } case E_HVD_GDATA_DISP_STC: { u32Ret = pShm->u32DispSTC; break; } case E_HVD_GDATA_VSYNC_CNT: { u32Ret = pShm->u32VsyncCnt; break; } case E_HVD_GDATA_MAIN_LOOP_CNT: { u32Ret = pShm->u32MainLoopCnt; break; } // AVC case E_HVD_GDATA_AVC_LEVEL_IDC: { u32Ret = pShm->u16AVC_SPS_LevelIDC; break; } case E_HVD_GDATA_AVC_LOW_DELAY: { u32Ret = pShm->u8AVC_SPS_LowDelayHrdFlag; break; } case E_HVD_GDATA_AVC_VUI_DISP_INFO: { u32Ret = _HVD_EX_GetVUIDispInfo(u32Id); break; } case E_HVD_GDATA_FW_FLUSH_STATUS: { u32Ret = (MS_U32) (pShm->u8FlushStatus); break; } case E_HVD_GDATA_FW_CODEC_TYPE: { u32Ret = pShm->u32CodecType; break; } case E_HVD_GDATA_FW_ES_BUF_STATUS: { u32Ret = (MS_U32)pShm->u8ESBufStatus; break; } case E_HVD_GDATA_VIDEO_FULL_RANGE_FLAG: { if(pShm->u32CodecMiscInfo & E_VIDEO_FULL_RANGE) { u32Ret = 1; } else { u32Ret = 0; } break; } // SRAM // Mailbox case E_HVD_GDATA_FW_STATE: // HVD RISC MBOX 0 (esp. FW init done) { u32Ret = pShm->u32FwState; break; } case E_HVD_GDATA_IS_DISP_INFO_UNCOPYED: { u32Ret = pShm->bSpsChange; break; } case E_HVD_GDATA_IS_DISP_INFO_CHANGE: // HVD RISC MBOX 1 (rdy only) { u32Ret = pShm->bSpsChange; if (pShm->bSpsChange && !(pShm->u8FrmPostProcSupport & E_HVD_POST_PROC_DETILE) && IS_TASK_ALIVE(pHVDHalContext->_stHVDStream[_HVD_EX_GetStreamIdx(u32Id)].s32HvdPpTaskId)) { _HVD_EX_PpTask_Delete(&pHVDHalContext->_stHVDStream[_HVD_EX_GetStreamIdx(u32Id)]); } break; } case E_HVD_GDATA_HVD_ISR_STATUS: // HVD RISC MBOX 1 (value only) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if ((pCtrl->HVDISRCtrl.u32IntCount != pShm->u32IntCount) && pShm->u32FwInfo) // fetch ISR status { u32Ret = pShm->u32FwInfo; pCtrl->HVDISRCtrl.u32IntCount = pShm->u32IntCount; } break; } case E_HVD_GDATA_IS_FRAME_SHOWED: // HVD HI mbox 0 ( showed: rdy cleared ; not show: rdy enable ) { if (pShm->bIsTrigDisp) // not clear yet { u32Ret = FALSE; } else { u32Ret = TRUE; } break; } case E_HVD_GDATA_ES_READ_PTR: { u32Ret = _HVD_EX_GetESReadPtr(u32Id, FALSE); break; } case E_HVD_GDATA_ES_WRITE_PTR: { u32Ret = _HVD_EX_GetESWritePtr(u32Id); break; } case E_HVD_GDATA_BBU_READ_PTR: { u32Ret = _HVD_EX_GetBBUReadptr(u32Id); break; } case E_HVD_GDATA_BBU_WRITE_PTR: { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { u32Ret = pHVDHalContext->u32VP8BBUWptr; } else { u32Ret = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr; } break; } case E_HVD_GDATA_BBU_WRITE_PTR_FIRED: { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); u32Ret = pCtrl->u32BBUWptr_Fired; break; } case E_HVD_GDATA_VPU_PC_CNT: { u32Ret = _HVD_EX_GetPC(); break; } case E_HVD_GDATA_ES_QUANTITY: { u32Ret=_HVD_EX_GetESQuantity(u32Id); break; } // FW def case E_HVD_GDATA_FW_MAX_DUMMY_FIFO: // AVC: 256Bytes AVS: 2kB RM:??? u32Ret = HVD_MAX3(HVD_FW_AVC_DUMMY_FIFO, HVD_FW_AVS_DUMMY_FIFO, HVD_FW_RM_DUMMY_FIFO); break; case E_HVD_GDATA_FW_AVC_MAX_VIDEO_DELAY: u32Ret = HVD_FW_AVC_MAX_VIDEO_DELAY; break; case E_HVD_GDATA_FW_BBU_TOTAL_TBL_ENTRY: u32Ret = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNumTH; break; case E_HVD_GDATA_FW_BBU_TBL_ENTRY_NUMB: u32Ret = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum; break; case E_HVD_GDATA_FW_PTS_TOTAL_ENTRY_NUMB: u32Ret = MAX_PTS_TABLE_SIZE; break; case E_HVD_GDATA_FW_DUMMY_WRITE_ADDR: u32Ret = (MS_VIRT) pShm->u32HVD_DUMMY_WRITE_ADDR; break; case E_HVD_GDATA_FW_DS_BUF_ADDR: u32Ret = (MS_VIRT) pShm->u32HVD_DYNAMIC_SCALING_ADDR; break; case E_HVD_GDATA_FW_DS_BUF_SIZE: u32Ret = pShm->u32DSBuffSize; //3k or 6k break; case E_HVD_GDATA_FW_DS_VECTOR_DEPTH: u32Ret = pShm->u8DSBufferDepth; //16 or 24 or 32 break; case E_HVD_GDATA_FW_DS_INFO_ADDR: u32Ret = (MS_VIRT) pShm->u32HVD_SCALER_INFO_ADDR; break; case E_HVD_GDATA_FW_DS_IS_ENABLED: { if (pShm->bDSIsRunning) { u32Ret = TRUE; } else { u32Ret = FALSE; } break; } #if (HVD_ENABLE_IQMEM) case E_HVD_GDATA_FW_IQMEM_CTRL: { u32Ret = (MS_U32)pShm->u8IQmemCtrl; break; } case E_HVD_GDATA_FW_IS_IQMEM_SUPPORT: { if(pShm->bIsIQMEMSupport){ u32Ret = TRUE; } else{ u32Ret = FALSE; } break; } #endif case E_HVD_GDATA_TYPE_IS_LEAST_DISPQ_SIZE: u32Ret = ((MS_U32)(pShm->bIsLeastDispQSize)); break; case E_HVD_GDATA_FIELD_PIC_FLAG: u32Ret = ((MS_U32)(pShm->u8FieldPicFlag)); break; case E_HVD_GDATA_TS_SEAMLESS_STATUS: u32Ret = pShm->u32SeamlessTSStatus; break; case E_HVD_GDATA_HVD_HW_MAX_PIXEL: u32Ret = (MS_U32)(_HAL_EX_GetHwMaxPixel(u32Id)/1000); break; #ifdef VDEC3 case E_HVD_GDATA_FW_VBBU_ADDR: u32Ret = (MS_VIRT) pShm->u32HVD_VBBU_DRAM_ST_ADDR; break; #endif case E_HVD_GDATA_SEQ_CHANGE_INFO: u32Ret = (MS_U32)pShm->u32SeqChangeInfo; break; default: break; } return u32Ret; } MS_U32 HAL_HVD_EX_GetDVSupportProfiles(void) { #if 0 // wait avc finish DV dual job return E_DV_STREAM_PROFILE_ID_DVAV_PER | E_DV_STREAM_PROFILE_ID_DVHE_DER | E_DV_STREAM_PROFILE_ID_DVHE_DTR | E_DV_STREAM_PROFILE_ID_DVHE_STN | E_DV_STREAM_PROFILE_ID_DVHE_DTH; #else return E_DV_STREAM_PROFILE_ID_DVHE_DER | E_DV_STREAM_PROFILE_ID_DVHE_DTR | E_DV_STREAM_PROFILE_ID_DVHE_STN | E_DV_STREAM_PROFILE_ID_DVHE_DTH; #endif } MS_U32 HAL_HVD_EX_GetDVSupportHighestLevel(MS_U32 u32DV_Stream_Profile) { switch (u32DV_Stream_Profile) { #if 0 // wait avc finish DV dual job case E_DV_STREAM_PROFILE_ID_DVAV_PER: return E_DV_STREAM_LEVEL_ID_UHD24;// level 6 #endif #if 0 // unsupported profile case E_DV_STREAM_PROFILE_ID_DVAV_PEN: return E_DV_STREAM_LEVEL_ID_UNSUPPORTED; #endif case E_DV_STREAM_PROFILE_ID_DVHE_DER: return E_DV_STREAM_LEVEL_ID_UHD60;// level 9 #if 0 // unsupported profile case E_DV_STREAM_PROFILE_ID_DVHE_DEN: return E_DV_STREAM_LEVEL_ID_UNSUPPORTED; #endif case E_DV_STREAM_PROFILE_ID_DVHE_DTR: return E_DV_STREAM_LEVEL_ID_UHD60;// level 9 case E_DV_STREAM_PROFILE_ID_DVHE_STN: return E_DV_STREAM_LEVEL_ID_UHD60;// level 9 case E_DV_STREAM_PROFILE_ID_DVHE_DTH: return E_DV_STREAM_LEVEL_ID_UHD60;// level 9 case E_DV_STREAM_PROFILE_ID_UNSUPPORTED: default: return E_DV_STREAM_LEVEL_ID_UNSUPPORTED; } } HVD_Return HAL_HVD_EX_SetCmd(MS_U32 u32Id, HVD_User_Cmd eUsrCmd, MS_U32 u32CmdArg) { HVD_Return eRet = E_HVD_RETURN_SUCCESS; MS_U32 u32Cmd = (MS_U32) eUsrCmd; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); if (pHVDHalContext->_stHVDStream[u8Idx].u32CodecType == E_HAL_HVD_HEVC_DV) { // skip mutex } else { _HAL_HVD_Entry(); } // check if old SVD cmds if (u32Cmd < E_HVD_CMD_SVD_BASE) { HVD_EX_MSG_ERR("Old SVD FW cmd(%x %x) used in HVD.\n", u32Cmd, u32CmdArg); if (pHVDHalContext->_stHVDStream[u8Idx].u32CodecType == E_HAL_HVD_HEVC_DV) { return E_HVD_RETURN_INVALID_PARAMETER; } else { _HAL_HVD_Return(E_HVD_RETURN_INVALID_PARAMETER); } } if (u32Cmd == E_HVD_CMD_ENABLE_DISP_OUTSIDE) { pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide = (MS_BOOL)u32CmdArg; } if (pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { if (u32Cmd == E_HVD_CMD_FLUSH) pHVDHalContext->_stHVDStream[u8Idx].u32DispQIndex = 0; } if (u32Cmd == E_HVD_CMD_FLUSH && IS_TASK_ALIVE(pHVDHalContext->_stHVDStream[u8Idx].s32HvdPpTaskId) && pHVDHalContext->_stHVDStream[u8Idx].ePpTaskState == E_HAL_HVD_STATE_RUNNING) { pHVDHalContext->_stHVDStream[u8Idx].ePpTaskState = E_HAL_HVD_STATE_PAUSING; while (pHVDHalContext->_stHVDStream[u8Idx].ePpTaskState != E_HAL_HVD_STATE_PAUSE_DONE) { if (pHVDHalContext->_stHVDStream[u8Idx].u32CodecType == E_HAL_HVD_HEVC_DV) { HVD_Delay_ms(1); } else { _HAL_HVD_Release(); HVD_Delay_ms(1); _HAL_HVD_Entry(); } } } HVD_EX_MSG_DBG("cmd=0x%x, arg=0x%x\n", u32Cmd, u32CmdArg); eRet = _HVD_EX_SendCmd(u32Id, u32Cmd, u32CmdArg); if (pHVDHalContext->_stHVDStream[u8Idx].u32CodecType == E_HAL_HVD_HEVC_DV) { return eRet; } else { _HAL_HVD_Return(eRet); } } HVD_Return HAL_HVD_EX_DeInit(MS_U32 u32Id) { HVD_Return eRet = E_HVD_RETURN_FAIL; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U32 u32Timeout = HVD_GetSysTime_ms() + 3000; MS_U8 u8MiuSel; MS_U32 u32StartOffset; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); #if HVD_ENABLE_TIME_MEASURE MS_U32 ExitTimeCnt = 0; ExitTimeCnt = HVD_GetSysTime_ms(); #endif pCtrl->MemMap.u32CodeBufVAddr = MS_PA2KSEG1((MS_PHY)pCtrl->MemMap.u32CodeBufAddr); eRet = HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_PAUSE, 0); if (E_HVD_RETURN_SUCCESS != eRet) { HVD_EX_MSG_ERR("HVD fail to PAUSE %d\n", eRet); } eRet = HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_STOP, 0); if (E_HVD_RETURN_SUCCESS != eRet) { HVD_EX_MSG_ERR("HVD fail to STOP %d\n", eRet); } // check FW state to make sure it's STOP DONE while (E_HVD_FW_STOP_DONE != (HVD_FW_State) HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_FW_STATE)) { if (HVD_GetSysTime_ms() > u32Timeout) { HVD_EX_MSG_ERR("FW stop timeout, pc = 0x%x\n", HAL_VPU_EX_GetProgCnt()); //return E_HVD_RETURN_TIMEOUT; eRet = E_HVD_RETURN_TIMEOUT; break; } } if (pShm->u32VdecPlusDecCnt+pShm->u32VdecPlusDropCnt) { HVD_EX_MSG_INF("VDEC PLUS: DropRatio %d, Drop:0.%d (%d), Dec:0.%d (%d), Disp:0.%d\n", pShm->u8VdecPlusDropRatio, 100*pShm->u32VdecPlusDropCnt/(pShm->u32VdecPlusDecCnt+pShm->u32VdecPlusDropCnt), pShm->u32VdecPlusDropCnt, 100*pShm->u32VdecPlusDecCnt/(pShm->u32VdecPlusDecCnt+pShm->u32VdecPlusDropCnt), pShm->u32VdecPlusDecCnt, 100*pShm->u32VdecPlusDispPicCnt/(pShm->u32VdecPlusDecCnt+pShm->u32VdecPlusDropCnt)); } else { HVD_EX_MSG_INF("VDEC PLUS DISABLE: DropRatio %d, Drop: %d, Dec: %d, Disp: %d\n", pShm->u8VdecPlusDropRatio, pShm->u32VdecPlusDropCnt, pShm->u32VdecPlusDecCnt, pShm->u32VdecPlusDispPicCnt); } VPU_EX_FWCodeCfg fwCfg; VPU_EX_TaskInfo taskInfo; VPU_EX_NDecInitPara nDecInitPara; nDecInitPara.pFWCodeCfg = &fwCfg; nDecInitPara.pTaskInfo = &taskInfo; fwCfg.u32DstAddr = pCtrl->MemMap.u32CodeBufVAddr; fwCfg.u8SrcType = E_HVD_FW_INPUT_SOURCE_NONE; HAL_HVD_EX_GetTaskInfo(u32Id,&taskInfo);//power control #if 0 taskInfo.u32Id = u32Id; taskInfo.eDecType = E_VPU_EX_DECODER_HVD; taskInfo.eVpuId = (HAL_VPU_StreamId) (0xFF & u32Id); #endif if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { taskInfo.eSrcType = E_VPU_EX_INPUT_FILE; } else { taskInfo.eSrcType = E_VPU_EX_INPUT_TSP; } if(HAL_VPU_EX_TaskDelete(u32Id, &nDecInitPara) != TRUE) { HVD_EX_MSG_ERR("HAL_VPU_EX_TaskDelete fail\n"); } /* clear es buffer */ if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_TSP) { //printf("Clear ES buffer\n"); memset((void *) pCtrl->MemMap.u32BitstreamBufVAddr, 0, MIN(128, pCtrl->MemMap.u32BitstreamBufSize)); } //_HAL_HVD_MutexDelete(); #if HVD_ENABLE_TIME_MEASURE HVD_EX_MSG_DBG("HVD Stop Time(Wait FW):%d\n", HVD_GetSysTime_ms() - ExitTimeCnt); #endif pHVDHalContext->_stHVDStream[u8Idx].bUsed = FALSE; #ifndef VDEC3 // reset bbu wptr if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { if(TRUE == HAL_VPU_EX_HVDInUsed()) { if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK))//apple { _HVD_EX_SetBBUWriteptr(u32Id, _HVD_EX_GetBBUReadptr(u32Id)); pHVDHalContext->u32VP8BBUWptr = _HVD_EX_GetBBUReadptr(u32Id); } else { if(!_stHVDPreSet[u8Idx].bColocateBBUMode) { _HVD_EX_SetBBUWriteptr(u32Id, _HVD_EX_GetBBUReadptr(u32Id)); } pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr = _HVD_EX_GetBBUReadptr(u32Id); } } else { pHVDHalContext->_stHVDStream[0].u32BBUWptr = 0; //main pHVDHalContext->_stHVDStream[1].u32BBUWptr = 0; //sub pHVDHalContext->u32VP8BBUWptr = 0; //VP8 if (E_HVD_INIT_HW_AVC == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { if(!_stHVDPreSet[u8Idx].bColocateBBUMode) { _HVD_EX_ResetMainSubBBUWptr(u32Id); } } else { _HVD_EX_ResetMainSubBBUWptr(u32Id); } } } #endif _stHVDPreSet[u8Idx].bColocateBBUMode = FALSE; if (IS_TASK_ALIVE(pHVDHalContext->_stHVDStream[u8Idx].s32HvdPpTaskId)) { _HVD_EX_PpTask_Delete(&pHVDHalContext->_stHVDStream[u8Idx]); } if(pHVDHalContext->pHVDPreCtrl_Hal[_HVD_EX_GetStreamIdx(u32Id)]->stIapGnShBWMode.bEnable) { _phy_to_miu_offset(u8MiuSel, u32StartOffset, pCtrl->MemMap.u32FrameBufAddr); _HAL_HVD_Entry(); HAL_HVD_MIF1_MiuClientSel(u8MiuSel); _HAL_HVD_Release(); } pHVDHalContext->_stHVDStream[u8Idx].u32RegBase = 0; HVD_EX_MSG_DBG("success\n"); return eRet; } HVD_Return HAL_HVD_EX_PushPacket(MS_U32 u32Id, HVD_BBU_Info *pInfo) { HVD_Return eRet = E_HVD_RETURN_UNSUPPORTED; MS_U32 u32Addr = 0; HVD_EX_Drv_Ctrl *pCtrl = NULL; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); pCtrl = _HVD_EX_GetDrvCtrl(u32Id); //if (E_HVD_INIT_HW_VP8 != (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) // VP8 PTS table is not ready yet { eRet = _HVD_EX_UpdatePTSTable(u32Id, pInfo); if (E_HVD_RETURN_SUCCESS != eRet) { return eRet; } } //printf(">>> halHVD pts,idH = %lu, %lu\n", pInfo->u32TimeStamp, pInfo->u32ID_H); //STS input //T9: for 128 bit memory. BBU need to get 2 entry at a time. if (E_HVD_INIT_HW_VP8 != (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { eRet = _HVD_EX_UpdateESWptr(u32Id, 0, 0); if (E_HVD_RETURN_SUCCESS != eRet) { return eRet; } } u32Addr = pInfo->u32Staddr; if (pInfo->bRVBrokenPacket) { u32Addr = pInfo->u32Staddr | BIT(HVD_RV_BROKENBYUS_BIT); } if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) // VP8 { eRet = _HVD_EX_UpdateESWptr_VP8(u32Id, pInfo->u32Staddr, pInfo->u32Length, pInfo->u32Staddr2, pInfo->u32Length2); } else { eRet = _HVD_EX_UpdateESWptr(u32Id, u32Addr, pInfo->u32Length); } if (E_HVD_RETURN_SUCCESS != eRet) { return eRet; } if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { //eRet = _HVD_EX_UpdateESWptr_VP8(u32Id, 0, 0, 0, 0); eRet = _HVD_EX_UpdateESWptr_VP8(u32Id, pInfo->u32Staddr, 0, pInfo->u32Staddr2, 0); if (E_HVD_RETURN_SUCCESS != eRet) { return eRet; } } pHVDHalContext->_stHVDStream[u8Idx].u32PTSByteCnt += pInfo->u32Length; // do not add local pointer if ((pCtrl->MemMap.u32DrvProcessBufSize != 0) && (pCtrl->MemMap.u32DrvProcessBufAddr != 0)) { MS_U32 u32PacketStAddr = pInfo->u32Staddr + pCtrl->MemMap.u32BitstreamBufAddr; if (!((pCtrl->MemMap.u32DrvProcessBufAddr <= u32PacketStAddr) && (u32PacketStAddr < (pCtrl->MemMap.u32DrvProcessBufAddr + pCtrl->MemMap.u32DrvProcessBufSize)))) { pCtrl->LastNal.u32NalAddr = pInfo->u32Staddr; pCtrl->LastNal.u32NalSize = pInfo->u32AllocLength; } else { //null packet pCtrl->LastNal.u32NalAddr = pInfo->u32OriPktAddr; pCtrl->LastNal.u32NalSize = 0; } } else { pCtrl->LastNal.u32NalAddr = pInfo->u32Staddr; pCtrl->LastNal.u32NalSize = pInfo->u32AllocLength; } pCtrl->LastNal.bRVBrokenPacket = pInfo->bRVBrokenPacket; pCtrl->u32BBUPacketCnt++; return eRet; } void HAL_HVD_EX_EnableISR(MS_U32 u32Id, MS_BOOL bEnable) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; MS_BOOL bCurrentStatus = HAL_HVD_EX_IsEnableISR(u32Id); if(bCurrentStatus == bEnable) return; if (bEnable) { _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), 0, HVD_REG_RISC_ISR_MSK); } else { _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_RISC_ISR_MSK, HVD_REG_RISC_ISR_MSK); } } void HAL_HVD_EX_SetForceISR(MS_U32 u32Id, MS_BOOL bEnable) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; if (bEnable) { _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_RISC_ISR_FORCE, HVD_REG_RISC_ISR_FORCE); } else { _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), 0, HVD_REG_RISC_ISR_FORCE); } } void HAL_HVD_EX_SetClearISR(HWDEC_ISR_TYPE eISRType) { MS_U32 u32RB = 0; switch(eISRType) { case E_HWDEC_ISR_HVD: u32RB = REG_HVD_BASE; break; #if SUPPORT_EVD case E_HWDEC_ISR_EVD: u32RB = REG_EVD_BASE; break; #endif #if SUPPORT_G2VP9 case E_HWDEC_ISR_G2VP9: break; #endif default: break; } if(u32RB) { _HVD_WriteWordMask(HVD_REG_RISC_MBOX_CLR(u32RB), HVD_REG_RISC_ISR_CLR, HVD_REG_RISC_ISR_CLR); } } MS_BOOL HAL_HVD_EX_IsISROccured(MS_U32 u32Id) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; return (MS_BOOL) (_HVD_Read2Byte(HVD_REG_RISC_MBOX_RDY(u32RB)) & HVD_REG_RISC_ISR_VALID); } MS_BOOL HAL_HVD_EX_IsEnableISR(MS_U32 u32Id) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; if (_HVD_Read2Byte(HVD_REG_RISC_MBOX_CLR(u32RB)) & HVD_REG_RISC_ISR_MSK) { return FALSE; } else { return TRUE; } } MS_BOOL HAL_HVD_EX_IsAlive(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if (pCtrl) { if ((pCtrl->LivingStatus.u32DecCnt == HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_DECODE_CNT)) && (pCtrl->LivingStatus.u32SkipCnt == HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_SKIP_CNT)) && (pCtrl->LivingStatus.u32IdleCnt == HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_VPU_IDLE_CNT)) && (pCtrl->LivingStatus.u32MainLoopCnt == HAL_HVD_EX_GetData(u32Id, E_HVD_GDATA_MAIN_LOOP_CNT))) { return FALSE; } else { return TRUE; } } else { return FALSE; } } MS_BOOL HAL_HVD_EX_RstPTSCtrlVariable(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_INPUT_MASK) == E_HVD_INIT_INPUT_DRV) { HAL_HVD_EX_ReadMemory(); pHVDHalContext->_stHVDStream[u8Idx].u32PTSByteCnt = pShm->u32PTStableByteCnt; pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr = _HVD_EX_GetPTSTableWptr(u32Id); HVD_EX_MSG_DBG("PTS table: WptrAddr:%x RptrAddr:%x ByteCnt:%x PreWptr:%lx\n", pShm->u32PTStableWptrAddr, pShm->u32PTStableRptrAddr, pHVDHalContext->_stHVDStream[u8Idx].u32PTSByteCnt, (unsigned long)pHVDHalContext->_stHVDStream[u8Idx].u32PTSPreWptr); } return TRUE; } MS_BOOL HAL_HVD_EX_FlushRstShareMem(MS_U32 u32Id) { HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); HVD_EX_Drv_Ctrl *pCtrl = NULL; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32Data; pCtrl = _HVD_EX_GetDrvCtrl(u32Id); memset(&pShm->DecoFrmInfo, 0, sizeof(HVD_Frm_Information)); HAL_HVD_EX_FlushMemory(); if (pHVDHalContext->_stHVDStream[u8Idx].bDispOutSide) { u32Data = _HVD_EX_GetESReadPtr(u32Id, FALSE); pCtrl->LastNal.u32NalAddr = u32Data; pCtrl->LastNal.u32NalSize = 0; } if (IS_TASK_ALIVE(pHVDHalContext->_stHVDStream[u8Idx].s32HvdPpTaskId)) pHVDHalContext->_stHVDStream[u8Idx].ePpTaskState = E_HAL_HVD_STATE_RUNNING; return TRUE; } void HAL_HVD_EX_UartSwitch2FW(MS_BOOL bEnable) { if (bEnable) { if (HAL_VPU_EX_IsEVDR2()) _HVD_WriteWordMask(REG_TOP_UART_SEL0, REG_TOP_UART_SEL_MHEG5, REG_TOP_UART_SEL_0_MASK); else _HVD_WriteWordMask(REG_TOP_UART_SEL0, REG_TOP_UART_SEL_VD_MHEG5, REG_TOP_UART_SEL_0_MASK); } else { #if defined (__aeon__) _HVD_WriteWordMask(REG_TOP_UART_SEL0, REG_TOP_UART_SEL_MHEG5, REG_TOP_UART_SEL_0_MASK); #else // defined (__mips__) _HVD_WriteWordMask(REG_TOP_UART_SEL0, REG_TOP_UART_SEL_PIU_0, REG_TOP_UART_SEL_0_MASK); #endif } } MS_U32 HAL_HVD_EX_GetData_Dbg(MS_U32 u32Addr) { return 0; } void HAL_HVD_EX_SetData_Dbg(MS_U32 u32Addr, MS_U32 u32Data) { return; } MS_U16 HAL_HVD_EX_GetCorretClock(MS_U16 u16Clock) { //if( u16Clock == 0 ) return 216; //140; //if( ) } void HAL_HVD_EX_UpdateESWptr_Fire(MS_U32 u32Id) { //MS_BOOL bBitMIU1 = FALSE; //MS_BOOL bCodeMIU1 = FALSE; MS_U8 u8BitMiuSel = 0; MS_U8 u8CodeMiuSel = 0; MS_U32 u32BitStartOffset; MS_U32 u32CodeStartOffset; //MS_U8 u8MiuSel; //MS_U32 u32StartOffset; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_VIRT u32BBU_DRAM_ST_ADDR = (MS_VIRT) pShm->u32HVD_BBU_DRAM_ST_ADDR; #if HVD_ENABLE_MVC if(HAL_HVD_EX_CheckMVCID(u32Id)) { // if MVC_BBU_ADDR and HVD_BBU_ADDR are different, we need to add MVC_BBU_DRAM_ST_ADDR and MVC_BBU2_DRAM_ST_ADDR in share memory u32BBU_DRAM_ST_ADDR = (MS_VIRT) pShm->u32HVD_BBU_DRAM_ST_ADDR; //pShm->u32MVC_BBU_DRAM_ST_ADDR; if(E_VDEC_EX_SUB_VIEW == HAL_HVD_EX_GetView(u32Id)) { u32BBU_DRAM_ST_ADDR = (MS_VIRT) pShm->u32HVD_BBU2_DRAM_ST_ADDR; //pShm->u32MVC_BBU2_DRAM_ST_ADDR; } } #endif /// HVD_ENABLE_MVC _phy_to_miu_offset(u8BitMiuSel, u32BitStartOffset, pCtrl->MemMap.u32BitstreamBufAddr); _phy_to_miu_offset(u8CodeMiuSel, u32CodeStartOffset, pCtrl->MemMap.u32CodeBufAddr); if (u8BitMiuSel != u8CodeMiuSel) { #if HVD_ENABLE_BDMA_2_BITSTREAMBUF BDMA_Result bdmaRlt; MS_VIRT u32DstAdd = 0, u32SrcAdd = 0, u32tabsize = 0; u32DstAdd = pCtrl->MemMap.u32BitstreamBufAddr + pCtrl->u32BBUTblInBitstreamBufAddr; u32SrcAdd = pCtrl->MemMap.u32CodeBufAddr + u32BBU_DRAM_ST_ADDR; u32tabsize = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum << 3; bdmaRlt = HVD_dmacpy(u32DstAdd, u32SrcAdd, u32tabsize); if (E_BDMA_OK != bdmaRlt) { HVD_EX_MSG_ERR("MDrv_BDMA_MemCopy fail ret=%x!\n", bdmaRlt); } #else MS_VIRT u32DstAdd = 0, u32SrcAdd = 0, u32tabsize = 0; u32DstAdd = pCtrl->MemMap.u32BitstreamBufVAddr + pCtrl->u32BBUTblInBitstreamBufAddr; u32SrcAdd = MsOS_PA2KSEG1(pCtrl->MemMap.u32CodeBufAddr + u32BBU_DRAM_ST_ADDR); u32tabsize = pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum << 3; HVD_memcpy(u32DstAdd, u32SrcAdd, u32tabsize); #endif } //HVD_EX_MSG_DBG("%lu st:%lx size:%lx BBU: %lu\n", pCtrl->u32BBUPacketCnt, pCtrl->LastNal.u32NalAddr, pCtrl->LastNal.u32NalSize, _stHVDStream[u8Idx].u32BBUWptr); HAL_HVD_EX_FlushMemory(); if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { _HVD_EX_SetBBUWriteptr(u32Id, HVD_LWORD(pHVDHalContext->u32VP8BBUWptr)); pCtrl->u32BBUWptr_Fired = pHVDHalContext->u32VP8BBUWptr; } else { _HVD_EX_SetBBUWriteptr(u32Id, HVD_LWORD(pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr)); pCtrl->u32BBUWptr_Fired = pHVDHalContext->_stHVDStream[u8Idx].u32BBUWptr; } } void HAL_HVD_EX_MVD_PowerCtrl(MS_BOOL bEnable) { if (bEnable) { _HVD_WriteWordMask(REG_TOP_MVD, 0, TOP_CKG_MHVD_DIS); _HVD_WriteWordMask(REG_TOP_MVD2, 0, TOP_CKG_MHVD2_DIS); } else { _HVD_WriteWordMask(REG_TOP_MVD, TOP_CKG_MHVD_DIS, TOP_CKG_MHVD_DIS); _HVD_WriteWordMask(REG_TOP_MVD2, TOP_CKG_MHVD2_DIS, TOP_CKG_MHVD2_DIS); } } void HAL_HVD_EX_Dump_FW_Status(MS_U32 u32Id) { MS_U32 tmp1 = 0; MS_U32 tmp2 = 0; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); HAL_HVD_EX_ReadMemory(); _HVD_EX_MBoxRead(u32Id, HAL_HVD_CMD_MBOX, &tmp1); _HVD_EX_MBoxRead(u32Id, HAL_HVD_CMD_ARG_MBOX, &tmp2); if (u32UartCtrl & E_HVD_UART_CTRL_DBG) { MS_U32 u32Tmp = u32UartCtrl; HVD_EX_MSG_DBG("\n"); u32UartCtrl = 0; // turn off debug message to prevent other function prints printf("\tSystime=%u, FWVersionID=0x%x, FwState=0x%x, ErrCode=0x%x, ProgCnt=0x%x\n", HVD_GetSysTime_ms(), pShm->u32FWVersionID, pShm->u32FwState, (MS_U32) pShm->u16ErrCode, HAL_VPU_EX_GetProgCnt()); printf("\tTime: DispSTC=%u, DispT=%u, DecT=%u, CurrentPts=%u, Last Cmd=0x%x, Arg=0x%x, Rdy1=0x%x, Rdy2=0x%x\n", pShm->u32DispSTC, pShm->DispFrmInfo.u32TimeStamp, pShm->DecoFrmInfo.u32TimeStamp, pShm->u32CurrentPts, tmp1, tmp2, (MS_U32) _HVD_EX_MBoxReady(u32Id, HAL_HVD_CMD_MBOX), (MS_U32) _HVD_EX_MBoxReady(u32Id, HAL_HVD_CMD_ARG_MBOX)); printf("\tFlag: InitDone=%d, SpsChange=%d, IsIFrmFound=%d, 1stFrmRdy=%d, SyncStart=%d, SyncReach=%d\n", pShm->bInitDone, pShm->bSpsChange, pShm->bIsIFrmFound, pShm->bIs1stFrameRdy, pShm->bIsSyncStart, pShm->bIsSyncReach); printf("\tQueue: BBUQNumb=%u, DecQNumb=%d, DispQNumb=%d, ESR=%u, ESRfromFW=%u, ESW=%u, ESLevel=%u\n", _HVD_EX_GetBBUQNumb(u32Id), pShm->u16DecQNumb, pShm->u16DispQNumb, _HVD_EX_GetESReadPtr(u32Id, TRUE), pShm->u32ESReadPtr, _HVD_EX_GetESWritePtr(u32Id), _HVD_EX_GetESLevel(u32Id)); printf("\tCounter: DecodeCnt=%u, DispCnt=%u, DataErrCnt=%u, DecErrCnt=%u, SkipCnt=%u, DropCnt=%u, idle=%u, MainLoopCnt=%u, VsyncCnt=%u\n", pShm->u32DecodeCnt, pShm->u32DispCnt, pShm->u32DataErrCnt, pShm->u32DecErrCnt, pShm->u32SkipCnt, pShm->u32DropCnt, pShm->u32VPUIdleCnt, pShm->u32MainLoopCnt, pShm->u32VsyncCnt); printf ("\tMode: ShowErr=%d, RepLastField=%d, SyncOn=%d, FileEnd=%d, Skip=%d, Drop=%d, DispSpeed=%d, FRC=%d, BlueScreen=%d, FreezeImg=%d, 1Field=%d\n", pShm->ModeStatus.bIsShowErrFrm, pShm->ModeStatus.bIsRepeatLastField, pShm->ModeStatus.bIsSyncOn, pShm->ModeStatus.bIsPlaybackFinish, pShm->ModeStatus.u8SkipMode, pShm->ModeStatus.u8DropMode, pShm->ModeStatus.s8DisplaySpeed, pShm->ModeStatus.u8FrcMode, pShm->ModeStatus.bIsBlueScreen, pShm->ModeStatus.bIsFreezeImg, pShm->ModeStatus.bShowOneField); u32UartCtrl = u32Tmp; // recover debug level } } void HAL_HVD_EX_GetBBUEntry(MS_U32 u32Id, HVD_EX_Drv_Ctrl *pDrvCtrl, MS_U32 u32Idx, MS_U32 *u32NalOffset, MS_U32 *u32NalSize) { MS_U8 *u32Addr = NULL; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); if (u32Idx >= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum) { return; } u32Addr = (MS_U8 *)(MsOS_PA2KSEG1(pDrvCtrl->MemMap.u32CodeBufAddr + (MS_PHY)pShm->u32HVD_BBU_DRAM_ST_ADDR + (u32Idx << 3))); *u32NalSize = *(u32Addr + 2) & 0x1f; *u32NalSize <<= 8; *u32NalSize |= *(u32Addr + 1) & 0xff; *u32NalSize <<= 8; *u32NalSize |= *(u32Addr) & 0xff; *u32NalOffset = ((MS_U32) (*(u32Addr + 2) & 0xe0)) >> 5; *u32NalOffset |= ((MS_U32) (*(u32Addr + 3) & 0xff)) << 3; *u32NalOffset |= ((MS_U32) (*(u32Addr + 4) & 0xff)) << 11; *u32NalOffset |= ((MS_U32) (*(u32Addr + 5) & 0xff)) << 19; } void HAL_HVD_EX_Dump_BBUs(MS_U32 u32Id, HVD_EX_Drv_Ctrl *pDrvCtrl, MS_U32 u32StartIdx, MS_U32 u32EndIdx, MS_BOOL bShowEmptyEntry) { MS_U32 u32CurIdx = 0; MS_BOOL bFinished = FALSE; MS_U32 u32NalOffset = 0; MS_U32 u32NalSize = 0; MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); if ((u32StartIdx >= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum) || (u32EndIdx >= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum)) { return; } u32CurIdx = u32StartIdx; do { if (u32CurIdx == u32EndIdx) { bFinished = TRUE; } HAL_HVD_EX_GetBBUEntry(u32Id, pDrvCtrl, u32CurIdx, &u32NalOffset, &u32NalSize); if ((bShowEmptyEntry == FALSE) || (bShowEmptyEntry && (u32NalOffset == 0) && (u32NalSize == 0))) { HVD_EX_MSG_DBG("HVD BBU Entry: Idx:%u Offset:%x Size:%x\n", u32CurIdx, u32NalOffset, u32NalSize); } u32CurIdx++; if (u32CurIdx >= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum) { u32CurIdx %= pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum; } } while (bFinished == TRUE); } void HAL_HVD_EX_Dump_HW_Status(MS_U32 u32Num) { MS_U32 i = 0; MS_U32 value = 0; if (u32UartCtrl & E_HVD_UART_CTRL_DBG) { HVD_EX_MSG_DBG("\n"); for (i = 0; i <= u32Num; i++) { _HVD_Write2Byte(HVD_REG_DEBUG_SEL, i); value = _HVD_Read2Byte(HVD_REG_DEBUG_DAT_L); value |= ((MS_U32) _HVD_Read2Byte(HVD_REG_DEBUG_DAT_H)) << 16; if (value == 0) { break; } printf(" %08x", value); if (((i % 8) + 1) == 8) { printf(" |%u\n", i + 1); } } printf("\nHVD Dump HW status End: total number:%u\n", i); } } void HAL_HVD_EX_SetMiuBurstLevel(HVD_EX_Drv_Ctrl *pDrvCtrl, HVD_MIU_Burst_Cnt_Ctrl eMiuBurstCntCtrl) { if (pDrvCtrl) { pDrvCtrl->Settings.u32MiuBurstLevel = (MS_U32) eMiuBurstCntCtrl; } } #if HVD_ENABLE_MVC MS_BOOL HAL_HVD_EX_CheckMVCID(MS_U32 u32Id) { return ( E_HAL_VPU_MVC_STREAM_BASE == (0xFF & u32Id) ); } VDEC_EX_View HAL_HVD_EX_GetView(MS_U32 u32Id) { if( (0xFF & (u32Id >> 8)) == 0x10) return E_VDEC_EX_MAIN_VIEW; else return E_VDEC_EX_SUB_VIEW; } #endif ///HVD_ENABLE_MVC void HAL_HVD_EX_SpareBandwidth(MS_U32 u32Id) //// For MVC { //HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_DIS_QUART_PIXEL, TRUE); //HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_DIS_DBF, TRUE); return; } void HAL_HVD_EX_PowerSaving(MS_U32 u32Id) //// turn on power saving mode for STB chips, ex. clippers, kano { HAL_HVD_EX_SetCmd(u32Id, E_HVD_CMD_POWER_SAVING, TRUE); return; } MS_BOOL HAL_HVD_EX_GetFrmRateIsSupported(MS_U32 u32Id, MS_U16 u16HSize, MS_U16 u16VSize, MS_U32 u32FrmRate) { MS_U64 _hw_max_pixel = 0; _hw_max_pixel = _HAL_EX_GetHwMaxPixel(u32Id); HVD_EX_MSG_DBG("%s w:%d, h:%d, fr:%d, MAX:%ld\n", __FUNCTION__, u16HSize, u16VSize, u32FrmRate, (unsigned long)_hw_max_pixel); return (((MS_U64)u16HSize*(MS_U64)u16VSize*(MS_U64)u32FrmRate) <= _hw_max_pixel); } MS_U32 HAL_HVD_EX_GetDispFrmNum(MS_U32 u32Id) { #if 1 HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); MS_U16 u16QNum = pShm->u16DispQNumb; MS_U16 u16QPtr = pShm->u16DispQPtr; // MS_U16 u16QSize = pShm->u16DispQSize; //static volatile HVD_Frm_Information *pHvdFrm = NULL; MS_U32 u32DispQNum = 0; #if HVD_ENABLE_MVC MS_BOOL bMVC = HAL_HVD_EX_CheckMVCID(u32Id); HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL bDolbyVision = (E_HVD_INIT_HW_HEVC_DV == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)); if(bMVC || bDolbyVision) { #if 0 if (u16QNum > HVD_DISPQ_PREFETCH_COUNT*3) { u16QNum = HVD_DISPQ_PREFETCH_COUNT*3; } #endif //printf("OQ:%d,DQ:%d.\n",pShm->u16DispQNumb,pShm->u16DecQNumb); //search the next frame to display while (u16QNum > 0) { //printf("Pr:%d,%d.[%ld,%ld,%ld,%ld].\n",u16QPtr,u16QNum,pShm->DispQueue[u16QPtr].u32Status,pShm->DispQueue[u16QPtr+1].u32Status, // pShm->DispQueue[u16QPtr+2].u32Status,pShm->DispQueue[u16QPtr+3].u32Status); pHVDHalContext->pHvdFrm = (volatile HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; //printf("Q2: %ld\n", pHVDShareMem->DispQueue[u16QPtr].u32Status); if (pHVDHalContext->pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) { /// For MVC. Output views after the pair of (base and depend) views were decoded. /// Check the depned view was initial when Output the base view. if((u16QPtr%2) == 0) { volatile HVD_Frm_Information *pHvdFrm_sub = (volatile HVD_Frm_Information *) &pShm->DispQueue[u16QPtr+1]; //if(pHvdFrm_sub->u32Status != E_HVD_DISPQ_STATUS_INIT) if(pHvdFrm_sub->u32Status == E_HVD_DISPQ_STATUS_NONE) { ///printf("[MVC] %d is not E_HVD_DISPQ_STATUS_INIT (%ld).\n",u16QPtr+1,pHvdFrm_sub->u32Status); ///printf("Return NULL.\n"); break; } } u32DispQNum++; } u16QNum--; //go to next frame in the dispQ u16QPtr++; if (u16QPtr >= pShm->u16DispQSize) { u16QPtr -= pShm->u16DispQSize; //wrap to the begin } } } else #endif ///HVD_ENABLE_MVC { #if 0 if (u16QNum > HVD_DISPQ_PREFETCH_COUNT) { u16QNum = HVD_DISPQ_PREFETCH_COUNT; } #endif // printf("Q: %d %d %d\n", u16QNum, u16QPtr, u16QSize); //search the next frame to display while (u16QNum != 0) { pHVDHalContext->pHvdFrm = (volatile HVD_Frm_Information *) &pShm->DispQueue[u16QPtr]; // printf("Q2[%d]: %ld\n", u16QPtr, pShm->DispQueue[u16QPtr].u32Status); if (pHVDHalContext->pHvdFrm->u32Status == E_HVD_DISPQ_STATUS_INIT) { u32DispQNum++; } u16QNum--; //go to next frame in the dispQ u16QPtr++; if (u16QPtr == pShm->u16DispQSize) { u16QPtr = 0; //wrap to the begin } } } //printf("dispQnum = %ld, pShm->u16DispQNumb = %d\n", u32DispQNum, pShm->u16DispQNumb); return u32DispQNum; #else HVD_ShareMem *pShm = (HVD_ShareMem *) _HVD_EX_GetShmAddr(u32Id); return pShm->u16DispQNumb; #endif } void HAL_HVD_EX_SetHwRegBase(MS_U32 u32Id, MS_U32 u32ModeFlag) { MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); if ((u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC || (u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_HEVC_DV) pHVDHalContext->_stHVDStream[u8Idx].u32RegBase = REG_EVD_BASE; else if ((u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_VP9) #if SUPPORT_G2VP9 && defined(VDEC3) pHVDHalContext->_stHVDStream[u8Idx].u32RegBase = REG_G2VP9_BASE; #else // Not using G2 VP9 implies using Mstar EVD VP9 pHVDHalContext->_stHVDStream[u8Idx].u32RegBase = REG_EVD_BASE; #endif else pHVDHalContext->_stHVDStream[u8Idx].u32RegBase = REG_HVD_BASE; } #if SUPPORT_EVD void HAL_EVD_EX_PowerCtrl(MS_U32 u32Id, MS_BOOL bEnable) { #ifdef CONFIG_MSTAR_CLKM HAL_VPU_EX_SetClkManagement(E_VPU_EX_CLKPORT_EVD, bEnable); HAL_VPU_EX_SetClkManagement(E_VPU_EX_CLKPORT_EVD_PPU, bEnable); #else if (bEnable) { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, ~TOP_CKG_EVD_PPU_DIS, TOP_CKG_EVD_PPU_DIS); _HVD_WriteWordMask(REG_TOP_CKG_EVD, ~TOP_CKG_EVD_DIS, TOP_CKG_EVD_DIS); _HVD_WriteWordMask(REG_EVDPLL_PD, ~REG_EVDPLL_PD_DIS, REG_EVDPLL_PD_DIS); } else { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_DIS, TOP_CKG_EVD_PPU_DIS); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_DIS, TOP_CKG_EVD_DIS); _HVD_WriteWordMask(REG_EVDPLL_PD, REG_EVDPLL_PD_DIS, REG_EVDPLL_PD_DIS); } switch (pHVDHalContext->u32EVDClockType) { case 576: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_PLL_BUF, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_480MHZ, TOP_CKG_EVD_MASK); break; } case 532: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_MIU128PLL, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_MIU128PLL, TOP_CKG_EVD_MASK); break; } case 456: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_MIU256PLL, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_PLL_BUF, TOP_CKG_EVD_MASK); _HVD_WriteWordMask(REG_EVDPLL_LOOP_DIV_SECOND, REG_EVDPLL_LOOP_DIV_SECOND_456MHZ, REG_EVDPLL_LOOP_DIV_SECOND_MASK); break; } case 466: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_MIU256PLL, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_MIU256PLL, TOP_CKG_EVD_MASK); break; } case 480: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_480MHZ, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_480MHZ, TOP_CKG_EVD_MASK); break; } case 384: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_384MHZ, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_384MHZ, TOP_CKG_EVD_MASK); break; } case 320: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_320MHZ, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_320MHZ, TOP_CKG_EVD_MASK); break; } case 240: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_240MHZ, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_240MHZ, TOP_CKG_EVD_MASK); break; } case 192: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_192MHZ, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_192MHZ, TOP_CKG_EVD_MASK); break; } default: { _HVD_WriteWordMask(REG_TOP_CKG_EVD_PPU, TOP_CKG_EVD_PPU_PLL_BUF, TOP_CKG_EVD_PPU_MASK); _HVD_WriteWordMask(REG_TOP_CKG_EVD, TOP_CKG_EVD_PLL_BUF, TOP_CKG_EVD_MASK); break; } } #endif #ifdef CONFIG_MSTAR_SRAMPD if (bEnable) { _HVD_WriteByteMask(REG_HICODEC_SRAM_SD_EN, HICODEC_SRAM_HICODEC0, HICODEC_SRAM_HICODEC0); HVD_Delay_ms(1); } else { _HVD_WriteByteMask(REG_HICODEC_SRAM_SD_EN, ~HICODEC_SRAM_HICODEC0, HICODEC_SRAM_HICODEC0); HVD_Delay_ms(1); } #endif return; } void HAL_EVD_EX_ClearTSPInput(MS_U32 u32Id) { #ifndef VDEC3 MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; #ifdef VDEC3 if (0 == pCtrl->u32BBUId) #else if (0 == u8TaskId) #endif { _HVD_Write2Byte(EVD_REG_RESET, (_HVD_Read2Byte(EVD_REG_RESET) & ~EVD_REG_RESET_HK_TSP2EVD_EN)); //0: tsp2hvd, coz EVD & HVD use the same MVD parser for main-DTV mode // disable TSP mode in EVD since EVD maybe effected by MVD parser's write pointer used by previous decoder _HVD_Write2Byte(HVD_REG_MIF_BBU(u32RB), _HVD_Read2Byte(HVD_REG_MIF_BBU(u32RB)) & (~HVD_REG_BBU_TSP_INPUT)); HVD_EX_MSG_INF("id %d disable TSP mode, val 0x%x\n", pCtrl->u32BBUId, _HVD_Read2Byte(HVD_REG_MIF_BBU(u32RB))); } else { _HVD_Write2Byte(EVD_REG_RESET, (_HVD_Read2Byte(EVD_REG_RESET) & ~EVD_REG_RESET_USE_HVD_MIU_EN)); //0: tsp2hvd, coz EVD & HVD use the same MVD parser for sub-DTV mode // disable TSP mode in EVD since EVD maybe effected by MVD parser's write pointer used by previous decoder _HVD_Write2Byte(HVD_REG_MIF_BBU_BS2(u32RB), _HVD_Read2Byte(HVD_REG_MIF_BBU_BS2(u32RB)) & (~HVD_REG_BBU_TSP_INPUT_BS2)); HVD_EX_MSG_INF("id %d disable TSP mode, val 0x%x\n", pCtrl->u32BBUId, _HVD_Read2Byte(HVD_REG_MIF_BBU_BS2(u32RB))); } return; } MS_BOOL HAL_EVD_EX_DeinitHW(MS_U32 u32Id) { MS_U16 u16Timeout = 1000; HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_BOOL isVP8Used = FALSE; MS_BOOL isAECUsed = FALSE; MS_BOOL isAVCUsed = FALSE; HAL_HVD_EX_VP8AECInUsed(u32Id, &isVP8Used, &isAECUsed, &isAVCUsed); if(TRUE == HAL_VPU_EX_EVDInUsed()) { if(!isAECUsed && E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_AEC_PowerCtrl(FALSE); } return FALSE; } else if(!isAVCUsed)//no AVC/EVD use , close EVD power { _HVD_EX_SetMIUProtectMask(TRUE); _HVD_WriteWordMask(EVD_REG_RESET, EVD_REG_RESET_SWRST, EVD_REG_RESET_SWRST); while (u16Timeout) { if ((_HVD_Read2Byte(EVD_REG_RESET) & (EVD_REG_RESET_SWRST_FIN)) == (EVD_REG_RESET_SWRST_FIN)) { break; } u16Timeout--; } HAL_EVD_EX_PowerCtrl(u32Id, FALSE); if(!isAECUsed && E_HVD_INIT_HW_VP9 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { HAL_AEC_PowerCtrl(FALSE); } _HVD_EX_SetMIUProtectMask(FALSE); return TRUE; } return FALSE; } #endif #if SUPPORT_G2VP9 && defined(VDEC3) static void HAL_VP9_EX_PowerCtrl(MS_BOOL bEnable) { if (bEnable) { _HVD_WriteWordMask(REG_TOP_VP9, ~TOP_CKG_VP9_DIS, TOP_CKG_VP9_DIS); } else { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_DIS, TOP_CKG_VP9_DIS); } switch (pHVDHalContext->u32VP9ClockType) { case 432: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_432MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 384: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_384MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 345: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_345MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 320: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_320MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 288: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_288MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 240: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_240MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 216: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_216MHZ, TOP_CKG_VP9_CLK_MASK); break; } case 172: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_172MHZ, TOP_CKG_VP9_CLK_MASK); break; } default: { _HVD_WriteWordMask(REG_TOP_VP9, TOP_CKG_VP9_432MHZ, TOP_CKG_VP9_CLK_MASK); break; } } return; } MS_BOOL HAL_VP9_EX_DeinitHW(void) { MS_U16 u16Timeout = 1000; _HVD_WriteWordMask(VP9_REG_RESET, VP9_REG_RESET_SWRST, VP9_REG_RESET_SWRST); while (u16Timeout) { if ((_HVD_Read2Byte(VP9_REG_RESET) & (VP9_REG_RESET_SWRST_FIN)) == (VP9_REG_RESET_SWRST_FIN)) { break; } u16Timeout--; } HAL_VP9_EX_PowerCtrl(FALSE); return TRUE; } #endif MS_BOOL HAL_HVD_EX_GetSupport2ndMVOPInterface(void) { return TRUE; } void HAL_HVD_EX_SetNalTblAddr(MS_U32 u32Id) { MS_VIRT u32StAddr = 0; MS_U8 u8BitMiuSel = 0; MS_U8 u8CodeMiuSel = 0; MS_U8 u8TmpMiuSel = 0; MS_U32 u32BitStartOffset; MS_U32 u32CodeStartOffset; #ifndef VDEC3 MS_U8 u8TaskId = HAL_VPU_EX_GetTaskId(u32Id); #endif HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); MS_U8 u8Idx = _HVD_EX_GetStreamIdx(u32Id); MS_U32 u32RB = pHVDHalContext->_stHVDStream[u8Idx].u32RegBase; HVD_ShareMem *pShm = (HVD_ShareMem *) HAL_HVD_EX_GetShmAddr(u32Id); _HAL_HVD_Entry(); if (pCtrl == NULL) { _HAL_HVD_Return(); } MS_BOOL bNalTblAlreadySet = FALSE; VPU_EX_TaskInfo taskInfo; memset(&taskInfo, 0, sizeof(VPU_EX_TaskInfo)); HAL_HVD_EX_GetTaskInfo(u32Id, &taskInfo); bNalTblAlreadySet = HAL_VPU_EX_CheckBBUSetting(u32Id, pCtrl->u32BBUId, taskInfo.eDecType, VPU_BBU_NAL_TBL); _phy_to_miu_offset(u8BitMiuSel, u32BitStartOffset, pCtrl->MemMap.u32BitstreamBufAddr); _phy_to_miu_offset(u8CodeMiuSel, u32CodeStartOffset, pCtrl->MemMap.u32CodeBufAddr); if (u8BitMiuSel != u8CodeMiuSel) { _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, (pCtrl->MemMap.u32BitstreamBufAddr + pCtrl->u32BBUTblInBitstreamBufAddr)); } else { _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, (pCtrl->MemMap.u32CodeBufAddr + pShm->u32HVD_BBU_DRAM_ST_ADDR)); } if (E_HVD_INIT_HW_VP8 == (pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK)) { #ifdef VDEC3 if (!_HAL_EX_BBU_VP8_InUsed()) #endif { _HVD_Write2Byte(HVD_REG_HK_VP8, HVD_REG_HK_PLAYER_FM); _HVD_Write2Byte(HVD_REG_NAL_TAB_ST_L_BS3, (MS_U16)(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TAB_ST_H_BS3, (MS_U16)(u32StAddr >> 19)); _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN_BS3, (MS_U16)(pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); u32StAddr += VP8_BBU_TBL_SIZE; _HVD_Write2Byte(HVD_REG_NAL_TAB_ST_L_BS4, (MS_U16)(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TAB_ST_H_BS4, (MS_U16)(u32StAddr >> 19)); _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN_BS4, (MS_U16)(pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); } _HAL_HVD_Return(); } HVD_EX_MSG_DBG("NAL start addr=%lx\n", (unsigned long)u32StAddr); #ifdef VDEC3 if (!bNalTblAlreadySet) { if (pCtrl->u32BBUId == 0) { _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_L(u32RB), (MS_U16) (u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_H(u32RB), (MS_U16) (u32StAddr >> 19)); // -1 is for NAL_TAB_LEN counts from zero. _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN(u32RB), (MS_U16) (pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); } else { _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_L_BS2(u32RB), (MS_U16) (u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_H_BS2(u32RB), (MS_U16) (u32StAddr >> 19)); // -1 is for NAL_TAB_LEN counts from zero. _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN_BS2(u32RB), (MS_U16) (pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); } } #else if (0 == u8TaskId) { _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_L(u32RB), (MS_U16) (u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_H(u32RB), (MS_U16) (u32StAddr >> 19)); // -1 is for NAL_TAB_LEN counts from zero. _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN(u32RB), (MS_U16) (pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); } else { _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_L_BS2(u32RB), (MS_U16) (u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_H_BS2(u32RB), (MS_U16) (u32StAddr >> 19)); // -1 is for NAL_TAB_LEN counts from zero. _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN_BS2(u32RB), (MS_U16) (pHVDHalContext->_stHVDStream[u8Idx].u32BBUEntryNum - 1)); } #endif #if (HVD_ENABLE_MVC) if ((pCtrl->InitParams.u32ModeFlag & E_HVD_INIT_HW_MASK) == E_HVD_INIT_HW_MVC) { /// Used sub stream to record sub view data. HVD_EX_Drv_Ctrl *pDrvCtrl_Sub = _HVD_EX_GetDrvCtrl((u32Id+0x00011000)); //printf("**************** Buffer setting for MVC dual-BBU *************\n"); if (u8BitMiuSel != u8CodeMiuSel) { _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, (pDrvCtrl_Sub->MemMap.u32BitstreamBufAddr + pDrvCtrl_Sub->u32BBUTblInBitstreamBufAddr)); } else { _phy_to_miu_offset(u8TmpMiuSel, u32StAddr, (pDrvCtrl_Sub->MemMap.u32CodeBufAddr + pShm->u32HVD_BBU2_DRAM_ST_ADDR)); } HVD_EX_MSG_DBG("[MVC] _HAL_HVD_SetBuffer2Addr: nal StAddr:%lx \n", (unsigned long) u32StAddr); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_L_BS2(u32RB), (MS_U16)(u32StAddr >> 3)); _HVD_Write2Byte(HVD_REG_NAL_TBL_ST_ADDR_H_BS2(u32RB), (MS_U16)(u32StAddr >> 19)); // -1 is for NAL_TAB_LEN counts from zero. _HVD_Write2Byte(HVD_REG_NAL_TAB_LEN_BS2(u32RB), (MS_U16)(pHVDHalContext->_stHVDStream[u8Idx+1].u32BBUEntryNum - 1)); } #endif if (!bNalTblAlreadySet) { HAL_VPU_EX_SetBBUSetting(u32Id, pCtrl->u32BBUId, taskInfo.eDecType, VPU_BBU_NAL_TBL); } _HAL_HVD_Return(); } MS_BOOL HAL_HVD_EX_Is_RM_Supported(MS_U32 u32Id) { HVD_EX_Drv_Ctrl *pCtrl = _HVD_EX_GetDrvCtrl(u32Id); if(pCtrl->InitParams.u16ChipECONum == 0) return FALSE; else return TRUE; } void HAL_HVD_EX_BBU_Proc(MS_U32 u32streamIdx) { } void HAL_HVD_EX_BBU_StopProc(MS_U32 u32streamIdx) { } #endif