rt-thread-official/bsp/nuvoton/libraries/n9h30/Driver/Source/nu_cap.c

1521 lines
52 KiB
C

/**************************************************************************//**
* @file cap.c
* @version V1.00
* @brief N9H30 CAP driver source file
*
* SPDX-License-Identifier: Apache-2.0
* @copyright (C) 2018 Nuvoton Technology Corp. All rights reserved.
*****************************************************************************/
#include <stdio.h>
#include <string.h>
#include "N9H30.h"
#include "nu_sys.h"
#include "nu_cap.h"
/** @addtogroup N9H30_Device_Driver N9H30 Device Driver
@{
*/
/** @addtogroup N9H30_CAP_Driver CAP Driver
@{
*/
/** @addtogroup N9H30_CAP_EXPORTED_FUNCTIONS CAP Exported Functions
@{
*/
/// @cond HIDDEN_SYMBOLS
PFN_CAP_CALLBACK(pfnCAP_IntHandlerTable)[4] = {0};
/// @endcond HIDDEN_SYMBOLS
/**
* @brief CAP interrupt Handler
*
* @param None
*
* @return None
*
* @details Driver internal use API to process the interrupt of CAP
* As interrupt occurrence, the register call back function will be executed
*/
static UINT32 u32EscapeFrame = 0;
//static UINT32 g_u32DeviceType = 0;
static void CAP_IntHandler(void)
{
UINT32 u32CapInt;
UINT32 uBuf = 0;
if ((inp32(REG_CLK_HCLKEN) & (0x1 << 26)) == (0x1 << 26)) /* CMOS sensor interface controller clock enabled */
{
u32CapInt = inp32(REG_CAP_INT);
if ((u32CapInt & (VIEN | VINTF)) == (VIEN | VINTF))
{
if (pfnCAP_IntHandlerTable[0] != 0)
pfnCAP_IntHandlerTable[0](uBuf, uBuf, u32EscapeFrame);
outp32(REG_CAP_INT, (u32CapInt & ~(MDINTF | ADDRMINTF | MEINTF))); /* Clear Frame end interrupt */
u32EscapeFrame = u32EscapeFrame + 1;
}
else if ((u32CapInt & (ADDRMIEN | ADDRMINTF)) == (ADDRMIEN | ADDRMINTF))
{
if (pfnCAP_IntHandlerTable[1] != 0)
pfnCAP_IntHandlerTable[1](uBuf, uBuf, u32EscapeFrame);
outp32(REG_CAP_INT, (u32CapInt & ~(MDINTF | VINTF | MEINTF))); /* Clear Address match interrupt */
}
else if ((u32CapInt & (MEIEN | MEINTF)) == (MEIEN | MEINTF))
{
if (pfnCAP_IntHandlerTable[2] != 0)
pfnCAP_IntHandlerTable[2](uBuf, uBuf, u32EscapeFrame);
outp32(REG_CAP_INT, (u32CapInt & ~(MDINTF | VINTF | ADDRMINTF))); /* Clear Memory error interrupt */
}
else if ((u32CapInt & (MDIEN | MDINTF)) == (MDIEN | MDINTF))
{
if (pfnCAP_IntHandlerTable[3] != 0)
pfnCAP_IntHandlerTable[3](uBuf, uBuf, u32EscapeFrame);
outp32(REG_CAP_INT, (u32CapInt & ~(VINTF | MEINTF | ADDRMINTF))); /* Clear Memory error interrupt */
}
}
}
/**
* @brief Set Inital Frame
*
* @return None
*
* @details If enable interrupt, there is internal counter that records how many frames have pass.
* Set the internal counters to zero. The internal counter may be not a constant
*/
void CAP_SetInitFrame(void)
{
u32EscapeFrame = 0;
}
/**
* @brief Get Inital Frame
*
* @retval >0 Internal counters
*
* @details If enable interrupt, there is internal counter that records how many frames have pass.
* Get the internal counters. The internal counter may be not a constant
*/
UINT32 CAP_GetSkipFrame(void)
{
return u32EscapeFrame;
}
/**
* @brief CAP Initial
*
* @param[in] bIsEnableSnrClock Enable/Disable sensor clock
* 1 : Enable
* 0 : Disable
* @param[in] eSnrSrc Set CAP clock source. Including :
* - \ref eCAP_SNR_APLL
* - \ref eCAP_SNR_UPLL
* @param[in] u32SensorFreqKHz Specify the sensor clock
*
* @return None
*
* @details To Initial sensor source clock and frequency for CAP interface
*/
void CAP_Init(BOOL bIsEnableSnrClock, E_CAP_SNR_SRC eSnrSrc, UINT32 u32SensorFreqKHz/*KHz unit*/)
{
UINT32 u32PllClock, u32SenDiv;// u32ExtFreq;
UINT32 u32Div0, u32Div1;
UINT32 u32SenSrc;
volatile UINT32 u32Divider;
/* MFP_GPI_L : I3=SEN_CLK0, I4=SEN_PCLK, I5=SEN_HSYNC, I6=SEN_VSYNC, I7=SEN_FIFLD*/
outpw(REG_SYS_GPI_MFPL, (inpw(REG_SYS_GPI_MFPL) & (0x00000FFF)) | 0x33333000);
/* MFP_GPI_H : SEN_PDATA[0~7]*/
outpw(REG_SYS_GPI_MFPH, (inpw(REG_SYS_GPI_MFPH) & (0xFFFFFFFF)) | 0x33333333);
u32SensorFreqKHz = u32SensorFreqKHz * 1000;
switch (eSnrSrc)
{
case eCAP_SNR_APLL:
u32PllClock = sysGetClock(SYS_APLL) * 1000000;
u32SenSrc = 0x2 << 19; //APLL for sensor clock
break;
case eCAP_SNR_UPLL:
u32PllClock = sysGetClock(SYS_UPLL) * 1000000;
u32SenSrc = 0x3 << 19; //UPLL for sensor clock
break;
}
u32SenDiv = u32PllClock / (u32SensorFreqKHz);
if (u32PllClock % u32SensorFreqKHz != 0) u32SenDiv = u32SenDiv + 1;
for (u32Div1 = 1; u32Div1 <= 16; u32Div1 = u32Div1 + 1)
{
for (u32Div0 = 1; u32Div0 <= 8; u32Div0 = u32Div0 + 1)
if (u32SenDiv == u32Div0 * u32Div1) break;
if (u32Div0 >= 9) continue;
if (u32SenDiv == u32Div0 * u32Div1) break;
}
//sysprintf("Div0 and Div1 = %d, %d ", u32Div0, u32Div1);
u32Div0 = u32Div0 - 1;
u32Div1 = u32Div1 - 1;
if (bIsEnableSnrClock)
{
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) | (1 << 27)); /* CMOS Sensor Reference Clock Output Enable */
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) | (1 << 26)); /* CMOS Sensor Interface Controller Clock Enable */
}
else
{
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) & ~(1 << 27)); /* CMOS Sensor Reference Clock Output Disabled */
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) & ~(1 << 26)); /* CMOS Sensor Interface Controller Clock Disabled */
}
u32Divider = u32SenSrc | ((u32Div0 << 16) | (u32Div1 << 24)) ;
//sysprintf("Sensor Divider = 0x%08x\n", u32Divider);
outp32(REG_CLK_DIVCTL3, (inp32(REG_CLK_DIVCTL3) & ~((0x3 << 19) | (0x7 << 16) | (0xF << 24))) | u32Divider);
}
/**
* @brief CAP Open
*
* @param[in] u32SensorFreqKHz Specify the sensor clock
*
* @retval 0 Success
* @retval <0 Error code
*
* @details Initialize the CAP engine. Register a call back for driver internal using
*/
INT32 CAP_Open(UINT32 u32SensorFreqKHz)
{
UINT32 u32PllClock;// u32ExtFreq;
UINT32 u32SenDiv;
UINT32 u32Div0, u32Div1;
UINT32 u32SenSrc;
volatile UINT32 u32Divider;
u32SensorFreqKHz = u32SensorFreqKHz * 1000;
outp32(REG_CLK_PMCON, inpw(REG_CLK_PMCON) | (0x1 << 4)) ; /* Sensor clock keep on high level */
outp32(REG_CLK_HCLKEN, inpw(REG_CLK_HCLKEN) | (0x1 << 26)); /* CMOS sensor interface controller clock enable */
outp32(REG_SYS_AHBIPRST, inp32(REG_SYS_AHBIPRST) | (1 << 10)); /* Video capture (CMOS sensor interface) reset enable. */
outp32(REG_SYS_AHBIPRST, inp32(REG_SYS_AHBIPRST) & ~(1 << 10)); /* Video capture (CMOS sensor interface) reset disable */
switch ((inpw(REG_CLK_DIVCTL3) >> 19) & 0x3)
{
case eCAP_SNR_APLL:
u32PllClock = sysGetClock(SYS_APLL) * 1000000;
u32SenSrc = 0x2 << 19; //APLL for sensor clock
break;
case eCAP_SNR_UPLL:
u32PllClock = sysGetClock(SYS_UPLL) * 1000000;
u32SenSrc = 0x3 << 19; //APLL for sensor clock
break;
}
u32SenDiv = u32PllClock / (u32SensorFreqKHz);
if (u32PllClock % u32SensorFreqKHz != 0)
u32SenDiv = u32SenDiv + 1;
for (u32Div1 = 1; u32Div1 <= 16; u32Div1 = u32Div1 + 1)
{
for (u32Div0 = 1; u32Div0 <= 8; u32Div0 = u32Div0 + 1)
{
if (u32SenDiv == u32Div0 * u32Div1)
break;
}
if (u32Div0 >= 9) continue;
if (u32SenDiv == u32Div0 * u32Div1)
break;
}
//sysprintf("Div0 and Div1 = %d, %d ", u32Div0, u32Div1);
u32Div0 = u32Div0 - 1;
u32Div1 = u32Div1 - 1;
u32Divider = u32SenSrc | ((u32Div0 << 16) | (u32Div1 << 24)) ;
//sysprintf("Sensor Divider = 0x%08x\n", u32Divider);
outp32(REG_CLK_DIVCTL3, (inp32(REG_CLK_DIVCTL3) & ~((0x3 << 19) | (0x7 << 16) | (0xF << 24))) | u32Divider);
sysInstallISR(IRQ_LEVEL_1, CAP_IRQn, (PVOID)CAP_IntHandler);
sysEnableInterrupt(CAP_IRQn);
return Successful;
}
/**
* @brief videoIn Reset
*
* @return None
*
* @details Capture interface reset.
*/
void CAP_Reset(void)
{
outp32(REG_CAP_CTL, inp32(REG_CAP_CTL) | (VPRST));
outp32(REG_CAP_CTL, inp32(REG_CAP_CTL) & (~VPRST));
}
/**
* @brief videoIn Close
*
* @return None
*
* @details Disable pin function,engine clock and interrupt
*/
void CAP_Close(void)
{
// 1. Disable IP's interrupt
sysDisableInterrupt(CAP_IRQn);
// 2. Disable IP's clock
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) & ~(0x1 << 25));
CAP_Reset();
outp32(REG_CLK_HCLKEN, inp32(REG_CLK_HCLKEN) & ~(0x1 << 26));
// 3. Disable Capture pin function
}
/**
* @brief Configure packet frame buffer.
*
* @param[in] bFrameSwitch Software mode buffer select
* 0: Packet buffer 0
* 1: Packet buffer 1
* @return None
*
* @details This function set packet frame buffer control
*/
void CAP_SetPacketFrameBufferControl(BOOL bFrameSwitch)
{
UINT32 u32Ctl;
u32Ctl = inp32(REG_CAP_CTL) & ~(ADDRSW);
outp32(REG_CAP_CTL, u32Ctl | (bFrameSwitch ? ADDRSW : 0));
}
/**
* @brief Get packet frame buffer.
*
* @param pbFrameSwitch Software mode buffer select
* 0: Packet buffer 0
* 1: Packet buffer 1
* @return None
*
* @details This function get packet frame buffer control
*/
void CAP_GetPacketFrameBufferControl(PBOOL pbFrameSwitch)
{
UINT32 u32Ctl = inp32(REG_CAP_CTL);
*pbFrameSwitch = (u32Ctl & ADDRSW) >> 3;
}
/**
* @brief Configure callback function
*
* @param[in] eIntType Set interrupt type. Including :
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @param[in] pfnCallback Set Callback function.
* The callbakc function :
* void (*PFN_CAP_CALLBACK)(UINT8 u8PacketBufID,UINT8 u8PlanarBufID, UINT8 u8FrameRate);
* @param[in] pfnOldCallback Set Old callback function
* The callbakc function :
* void *(*PFN_CAP_CALLBACK)(UINT8 u8PacketBufID,UINT8 u8PlanarBufID, UINT8 u8FrameRate);
* @retval 0 Success
* @retval <0 Error code
*
* @details This function configure callback function and set trigger level
*/
INT32 CAP_InstallCallback(E_CAP_INT_TYPE eIntType, PFN_CAP_CALLBACK pfnCallback, PFN_CAP_CALLBACK *pfnOldCallback)
{
if (eIntType == eCAP_VINTF)
{
*pfnOldCallback = pfnCAP_IntHandlerTable[0];
pfnCAP_IntHandlerTable[0] = (PFN_CAP_CALLBACK)(pfnCallback);
}
else if (eIntType == eCAP_ADDRMINTF)
{
*pfnOldCallback = pfnCAP_IntHandlerTable[1];
pfnCAP_IntHandlerTable[1] = (PFN_CAP_CALLBACK)(pfnCallback);
}
else if (eIntType == eCAP_MEINTF)
{
*pfnOldCallback = pfnCAP_IntHandlerTable[2];
pfnCAP_IntHandlerTable[2] = (PFN_CAP_CALLBACK)(pfnCallback);
}
else if (eIntType == eCAP_MDINTF)
{
*pfnOldCallback = pfnCAP_IntHandlerTable[3];
pfnCAP_IntHandlerTable[3] = (PFN_CAP_CALLBACK)(pfnCallback);
}
else
return E_CAP_INVALID_INT;
return Successful;
}
/**
* @brief Enable videoIn interrupt.
*
* @param[in] eIntType Interrupt type. Incuding:
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to enable videoIn interrupt.
*/
INT32 CAP_EnableInt(E_CAP_INT_TYPE eIntType)
{
switch (eIntType)
{
case eCAP_MDINTF:
case eCAP_ADDRMINTF:
case eCAP_MEINTF:
case eCAP_VINTF:
outp32(REG_CAP_INT, inp32(REG_CAP_INT) | eIntType);
break;
default:
return E_CAP_INVALID_INT;
}
return Successful;
}
/**
* @brief Disable videoIn interrupt
*
* @param[in] eIntType Interrupt type. Incuding:
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to disable videoIn interrupt.
*/
INT32 CAP_DisableInt(E_CAP_INT_TYPE eIntType)
{
switch (eIntType)
{
case eCAP_MDINTF:
case eCAP_ADDRMINTF:
case eCAP_MEINTF:
case eCAP_VINTF:
outp32(REG_CAP_INT, inp32(REG_CAP_INT) & ~eIntType);
break;
default:
return E_CAP_INVALID_INT;
}
return Successful;
}
/**
* @brief Check videoIn interrupt
*
* @param[in] eIntType Interrupt type. Incuding:
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @retval 1 Enable
* @retval 0 Disable
*
* @details This function is used to check videoIn interrupt.
*/
BOOL CAP_IsIntEnabled(E_CAP_INT_TYPE eIntType)
{
UINT32 u32IntEnable = inp32(REG_CAP_INT);
switch (eIntType)
{
case eCAP_MDINTF:
u32IntEnable = u32IntEnable & eCAP_MDINTF;
break;
case eCAP_ADDRMINTF:
u32IntEnable = u32IntEnable & eCAP_ADDRMINTF;
break;
case eCAP_MEINTF:
u32IntEnable = u32IntEnable & eCAP_MEINTF;
break;
case eCAP_VINTF:
u32IntEnable = u32IntEnable & eCAP_VINTF;
break;
}
return (u32IntEnable ? TRUE : FALSE);
}
/**
* @brief Clear videoIn interrupt flag.
*
* @param[in] eIntType Interrupt type. Incuding:
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to clear videoIn interrupt flag.
*/
INT32 CAP_ClearInt(E_CAP_INT_TYPE eIntType)
{
UINT32 u32IntChannel = eIntType >> 16;
switch (eIntType)
{
case eCAP_MDINTF:
outp32(REG_CAP_INT, (inp32(REG_CAP_INT) & ~((eCAP_ADDRMINTF | eCAP_MEINTF | eCAP_VINTF) >> 16)) |
u32IntChannel);
break;
case eCAP_ADDRMINTF:
outp32(REG_CAP_INT, (inp32(REG_CAP_INT) & ~((eCAP_MDINTF | eCAP_MEINTF | eCAP_VINTF) >> 16)) |
u32IntChannel);
break;
case eCAP_MEINTF:
outp32(REG_CAP_INT, (inp32(REG_CAP_INT) & ~((eCAP_MDINTF | eCAP_ADDRMINTF | eCAP_VINTF) >> 16)) |
u32IntChannel);
break;
case eCAP_VINTF:
outp32(REG_CAP_INT, (inp32(REG_CAP_INT) & ~((eCAP_MDINTF | eCAP_MEINTF | eCAP_ADDRMINTF) >> 16)) |
u32IntChannel);
break;
default:
return E_CAP_INVALID_INT;
}
return Successful;
}
/**
* @brief Polling videoIn interrupt flag.
*
* @param[in] eIntType Interrupt type. Incuding:
* - \ref eCAP_MDINTF
* - \ref eCAP_ADDRMINTF
* - \ref eCAP_MEINTF
* - \ref eCAP_VINTF
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to poll videoIn interrupt flag.
*/
BOOL CAP_PollInt(E_CAP_INT_TYPE eIntType)
{
UINT32 u32IntStatus = inp32(REG_CAP_INT);
switch (eIntType)
{
case eCAP_MDINTF:
u32IntStatus = u32IntStatus & (eCAP_MDINTF >> 16);
break;
case eCAP_ADDRMINTF:
u32IntStatus = u32IntStatus & (eCAP_ADDRMINTF >> 16);
break;
case eCAP_MEINTF:
u32IntStatus = u32IntStatus & (eCAP_MEINTF >> 16);
break;
case eCAP_VINTF:
u32IntStatus = u32IntStatus & (eCAP_VINTF >> 16);
break;
}
return (u32IntStatus ? TRUE : FALSE);
}
/**
* @brief Enable engine clock and turn on the pipe.
*
* @param[in] bEngEnable Enable engine clock.
* 1 : Enable engine clock.
* 0 : Disable engine clock.
* @param[in] ePipeEnable Enable pipe type. Incuding:
* - \ref eCAP_BOTH_PIPE_DISABLE
* - \ref eCAP_PLANAR
* - \ref eCAP_PACKET
* - \ref eCAP_BOTH_PIPE_ENABLE
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to enable engine clock and pipe type.
*/
void CAP_SetPipeEnable(
BOOL bEngEnable,
E_CAP_PIPE ePipeEnable
)
{
outp32(REG_CAP_CTL, (inp32(REG_CAP_CTL) & ~(CAPEN | PKTEN | PLNEN))
| (((bEngEnable ? CAPEN : 0x0))
// | ((ePipeEnable & ~(PKTEN | PLNEN))<<5)) );
| ((ePipeEnable & 0x03) << 5)));
} // DrvVideoIn_SetPipeEnable
/**
* @brief Get engine clock and pipe type.
*
* @param[out] pbEngEnable Enable engine clock.
* 1 : Enable engine clock.
* 0 : Disable engine clock.
* @param[out] pePipeEnable Pipe type. Incuding:
* - \ref eCAP_BOTH_PIPE_DISABLE
* - \ref eCAP_PLANAR
* - \ref eCAP_PACKET
* - \ref eCAP_BOTH_PIPE_ENABLE
* @return None
*
* @details This function is used to get engin clock and pipe type.
*/
void CAP_GetPipeEnable(PBOOL pbEngEnable, E_CAP_PIPE *pePipeEnable)
{
UINT32 u32Temp = inp32(REG_CAP_CTL);
*pbEngEnable = (u32Temp & CAPEN) ? TRUE : FALSE;
*pePipeEnable = (E_CAP_PIPE)((u32Temp & (PKTEN | PLNEN)) >> 5);
} // DrvVideoIn_GetPipeEnable
/**
* @brief Set Shadow(Update) Register
*
* @details This function is used to reload frame buffer address after
* setting shoaw(update) register.
*/
void CAP_SetShadowRegister(void)
{
outp32(REG_CAP_CTL, inp32(REG_CAP_CTL) | UPDATE);
} // DrvVideoIn_SetShadowRegister
/**
* @brief Set sensor polarity.
*
* @param[in] bVsync Sensor Vsync Polarity.
* 1 : High Active
* 0 : Low Active
* @param[in] bHsync Sensor Hsync Polarity.
* 1 : High Active
* 0 : Low Active
* @param[in] bPixelClk Sensor Vsync Polarity.
* 1 : Falling Edge
* 0 : Rising Edig
* @return None
*
* @details This function is used to set sensor polarity.
*/
void CAP_SetSensorPolarity(BOOL bVsync, BOOL bHsync, BOOL bPixelClk)
{
UINT32 u32Polarity, u32RegVal;
u32RegVal = inp32(REG_CAP_PAR);
//sysprintf("Enter Register addr = 0x%x\n", (REG_CAP_PAR));
//sysprintf("Enter Register value = 0x%x\n", u32RegVal);
u32Polarity = (((bVsync ? VSP : 0x0) | (bHsync ? HSP : 0x0)) | (bPixelClk ? PCLKP : 0x0));
u32RegVal = (inp32(REG_CAP_PAR) & ~(VSP | HSP | PCLKP)) ;
//sysprintf("REG_VPEPAR = 0x%x", (u32RegVal | u32Polarity));
outp32((REG_CAP_PAR), (u32RegVal | u32Polarity));
}
/**
* @brief Get sensor polarity.
*
* @param[out] pbVsync Sensor Vsync Polarity.
* 1 : High Active
* 0 : Low Active
* @param[out] pbHsync Sensor Hsync Polarity.
* 1 : High Active
* 0 : Low Active
* @param[out] pbPixelClk Sensor Vsync Polarity.
* 1 : Falling Edge
* 0 : Rising Edig
* @return None
*
* @details This function is used to get sensor polarity.
*/
void CAP_GetSensorPolarity(PBOOL pbVsync, PBOOL pbHsync, PBOOL pbPixelClk)
{
UINT32 u32Temp = inp32(REG_CAP_PAR);
*pbVsync = (u32Temp & VSP) ? TRUE : FALSE;
*pbHsync = (u32Temp & HSP) ? TRUE : FALSE;
*pbPixelClk = (u32Temp & PCLKP) ? TRUE : FALSE;
}
/**
* @brief Set data format and order.
*
* @param[in] eInputOrder Data order for input format.Including :
* - \ref eCAP_IN_UYVY = Y0 U0 Y1 V0
* - \ref eCAP_IN_YUYV = Y0 V0 Y1 U0
* - \ref eCAP_IN_VYUY = U0 Y0 V0 Y1
* - \ref eCAP_IN_YVYU = V0 Y0 U0 Y1
* @param[in] eInputFormat Input data format.Including :
* - \ref eCAP_IN_YUV422
* - \ref eCAP_IN_RGB565
* @param[in] eOutputFormat Sensor Vsync Polarity.Including :
* - \ref eCAP_OUT_YUV422 = YCbCr422
* - \ref eCAP_OUT_ONLY_Y = only output Y
* - \ref eCAP_OUT_RGB555 = rgb555
* - \ref eCAP_OUT_RGB565 = rgb565
* @return None
*
* @details This function is used to set data format and order.
*/
void CAP_SetDataFormatAndOrder(E_CAP_ORDER eInputOrder, E_CAP_IN_FORMAT eInputFormat, E_CAP_OUT_FORMAT eOutputFormat)
{
outp32((REG_CAP_PAR), (inp32(REG_CAP_PAR) & ~(OUTFMT | INDATORD | INFMT))
| ((((eInputOrder << 2) & INDATORD)
| (eInputFormat & INFMT))
| ((eOutputFormat << 4) & OUTFMT)));
} // DrvVideoIn_SetDataFormatAndOrder
/**
* @brief Get data format and order.
*
* @param[out] peInputOrder Data order for input format.Including :
* - \ref eCAP_IN_UYVY
* - \ref eCAP_IN_YUYV
* - \ref eCAP_IN_VYUY
* - \ref eCAP_IN_YVYU
* @param[out] peInputFormat Input data format.Including :
* - \ref eCAP_IN_YUV422
* - \ref eCAP_IN_RGB565
* @param[out] peOutputFormat Sensor Vsync Polarity.Including :
* - \ref eCAP_OUT_YUV422 = YCbCr422
* - \ref eCAP_OUT_ONLY_Y = only output Y
* - \ref eCAP_OUT_RGB555 = rgb555
* - \ref eCAP_OUT_RGB565 = rgb565
* @return None
*
* @details This function is used to get data format and order.
*/
void CAP_GetDataFormatAndOrder(E_CAP_ORDER *peInputOrder, E_CAP_IN_FORMAT *peInputFormat, E_CAP_OUT_FORMAT *peOutputFormat)
{
UINT32 u32Temp = inp32(REG_CAP_PAR);
*peInputOrder = (E_CAP_ORDER)((u32Temp & INDATORD) >> 2);
*peInputFormat = (E_CAP_IN_FORMAT)(u32Temp & INFMT);
*peOutputFormat = (E_CAP_OUT_FORMAT)((u32Temp & OUTFMT) >> 4);
}
/**
* @brief Set planar format.
*
* @param[in] ePlanarFmt Data order for input format.Including :
* - \ref eCAP_PLANAR_YUV422
* - \ref eCAP_PLANAR_YUV420
* @return None
*
* @details This function is used to set planar format.
*/
void CAP_SetPlanarFormat(E_CAP_PLANAR_FORMAT ePlanarFmt)
{
switch (ePlanarFmt)
{
case eCAP_PLANAR_YUV422:
outp32((REG_CAP_PAR), (inp32(REG_CAP_PAR) & ~(PLNFMT)));
break;
case eCAP_PLANAR_YUV420:
outp32((REG_CAP_PAR), ((inp32(REG_CAP_PAR) | (PLNFMT))));
break;
}
}
/**
* @brief Get planar format.
*
* @retval - \ref eCAP_PLANAR_YUV422 : Planar format is YUV420.
* @retval - \ref eCAP_PLANAR_YUV420 : Planar format is YUV422.
*
* @details This function is used to get planar format.
*/
BOOL CAP_GetPlanarFormat(void)
{
return ((inp32(REG_CAP_PAR) & PLNFMT) >> 7);
}
/**
* @brief Set motion detection parameter.
*
* @param[in] bEnable Enable Motion Detection.Including :
* 0 : Disable motion detection.
* 1 : Enable motion detection.
* @param[in] bBlockSize Motion Detection Block Size.Including :
* 0 : Block size is set to 16x16.
* 1 : Block size is set to 8x8.
* @param[in] bSaveMode Motion Detection Save Mode.Including :
* 0 : 1 bit DIFF + 7 Y Differential.
* 1 : 1 bit DIFF only.
* @return None
*
* @details This function is used to set motion detection parameter.
*/
void CAP_SetMotionDet(BOOL bEnable, BOOL bBlockSize, BOOL bSaveMode)
{
outp32(REG_CAP_MD, (inp32(REG_CAP_MD) & ~(MDSM | MDBS | MDEN)) |
(((bEnable ? MDEN : 0) | (bBlockSize ? MDBS : 0)) |
(bSaveMode ? MDSM : 0)));
}
/**
* @brief Get motion detection parameter.
*
* @param[out] pbEnable Enable Motion Detection.Including :
* 0 : Disable motion detection.
* 1 : Enable motion detection.
* @param[out] pbBlockSize Motion Detection Block Size.Including :
* 0 : Block size is set to 16x16.
* 1 : Block size is set to 8x8.
* @param[out] pbSaveMode Motion Detection Save Mode.Including :
* 0 : 1 bit DIFF + 7 Y Differential.
* 1 : 1 bit DIFF only.
* @return None
*
* @details This function is used to get motion detection parameter.
*/
void CAP_GetMotionDet(PBOOL pbEnable, PBOOL pbBlockSize, PBOOL pbSaveMode)
{
UINT32 u32RegData = inp32(REG_CAP_MD);
*pbEnable = (u32RegData & MDEN);
*pbBlockSize = (u32RegData & MDBS) >> 8;
*pbSaveMode = (u32RegData & MDSM) >> 9;
}
/**
* @brief Set motion detection parameter externtion.
*
* @param[in] u32DetFreq Motion Detection frequency.Including :
* 0 : Each frame
* 1 : Every 2 frame
* 2 : Every 3 frame
* 3 : Every 4 frame
* @param[in] u32Threshold Motion detection threshold.It should be 0~31.
*
* @param[in] u32OutBuffer Motion Detection Output Address Register.(Word Alignment)
*
* @param[in] u32LumBuffer Motion Detection Temp Y Output Address Register.(Word Alignment)
*
* @return None
*
* @details This function is used to set motion detection parameter externtion.
*/
void CAP_SetMotionDetEx(UINT32 u32DetFreq, UINT32 u32Threshold, UINT32 u32OutBuffer, UINT32 u32LumBuffer)
{
outp32(REG_CAP_MD, (inp32(REG_CAP_MD) & ~MDDF) | ((u32DetFreq << 10) & MDDF));
outp32(REG_CAP_MD, (inp32(REG_CAP_MD) & ~MDTHR) | ((u32Threshold << 16) & MDTHR));
outp32(REG_CAP_MDADDR, u32OutBuffer);
outp32(REG_CAP_MDYADDR, u32LumBuffer);
}
/**
* @brief Get motion detection parameter externtion.
*
* @param[out] pu32DetFreq Motion Detection frequency.Including :
* 0 : Each frame
* 1 : Every 2 frame
* 2 : Every 3 frame
* 3 : Every 4 frame
* @param[out] pu32Threshold Motion detection threshold.It should be 0~31.
*
* @param[out] pu32OutBuffer Motion Detection Output Address Register.(Word Alignment)
*
* @param[out] pu32LumBuffer Motion Detection Temp Y Output Address Register.(Word Alignment)
*
* @return None
*
* @details This function is used to get motion detection parameter externtion.
*/
void CAP_GetMotionDetEx(PUINT32 pu32DetFreq, PUINT32 pu32Threshold, PUINT32 pu32OutBuffer, PUINT32 pu32LumBuffer)
{
UINT32 u32RegData;
u32RegData = inp32(REG_CAP_MD);
*pu32DetFreq = u32RegData & MDDF;
*pu32Threshold = u32RegData & MDTHR;
*pu32OutBuffer = inp32(REG_CAP_MDADDR);
*pu32LumBuffer = inp32(REG_CAP_MDYADDR);
}
/**
* @brief Set motion detection frequency.
*
* @param[in] u32DetFreq Motion Detection frequency.Including :
* 0 : Each frame
* 1 : Every 2 frame
* 2 : Every 3 frame
* 3 : Every 4 frame
* @return None
*
* @details This function is used to set motion detection frequency.
*/
void CAP_SetMotionDetFreq(UINT32 u32DetFreq)
{
outp32(REG_CAP_MD, (inp32(REG_CAP_MD) & ~MDDF) |
((u32DetFreq << 10) & MDDF));
}
/**
* @brief Get motion detection frequency.
*
* @param[out] pu32DetFreq Motion Detection frequency.Including :
* 0 : Each frame
* 1 : Every 2 frame
* 2 : Every 3 frame
* 3 : Every 4 frame
* @return None
*
* @details This function is used to get motion detection frequency.
*/
void CAP_GetMotionDetFreq(PUINT32 pu32DetFreq)
{
UINT32 u32RegData;
u32RegData = inp32(REG_CAP_MD);
*pu32DetFreq = u32RegData & MDDF;
}
/**
* @brief Set One shutte or continuous mode.
*
* @param[in] bIsOneSutterMode Enable One shutte.Including :
* 1 : Enable One shutte mode.
* 0 : Disable One shutte mode.
* @return None
*
* @details This function is used to set one shutte or continuous mode.
* Image capture interface automatically disable the capture
* inteface after a frame bad been captured.
*/
void CAP_SetOperationMode(BOOL bIsOneSutterMode)
{
outp32(REG_CAP_CTL, (inp32(REG_CAP_CTL) & ~SHUTTER) |
((bIsOneSutterMode << 16) & SHUTTER));
} // DrvVideoIn_SetOperationMode
/**
* @brief Get One shutte or continuous mode.
*
* @retval 1 : Disable one shutte mode
* @retval 0 : Enable one shutte mode
*
* @details This function is used to get one shutte or continuous mode.
* Image capture interface automatically disable the capture
* inteface after a frame bad been captured.
*/
BOOL CAP_GetOperationMode(void)
{
return ((inp32(REG_CAP_CTL) & SHUTTER) ? TRUE : FALSE);
} // DrvVideoIn_GetOperationMode
/**
* @brief Get packet/planar processed data count.
*
* @param[in] ePipe Pipe type. Including :
* - \ref eCAP_PACKET
* - \ref eCAP_PLANAR
*
* @return Get current packet/planar processed data count.
*
* @details This function is used to get packet/planar processed data count.
*/
UINT32 CAP_GetProcessedDataCount(E_CAP_PIPE ePipe)
{
if (ePipe == eCAP_PACKET)
return inp32(REG_CAP_CURADDRP); /* Packet pipe */
else if (ePipe == eCAP_PLANAR)
return inp32(REG_CAP_CURADDRY); /* Planar pipe */
else
return 0;
}
/**
* @brief Set cropping window vertical/horizontal starting address.
*
* @param[in] u32VerticalStart Cropping window vertical starting address.
* @param[in] u32HorizontalStart Cropping window horizontal starting address.
*
* @return None.
*
* @details This function is used to set cropping window vertical/horizontal starting address.
*/
void CAP_SetCropWinStartAddr(UINT32 u32VerticalStart, UINT32 u32HorizontalStart)
{
outp32(REG_CAP_CWSP, (inp32(REG_CAP_CWSP) & ~(CWSADDRV | CWSADDRH)) //(Y|X)
| ((u32VerticalStart << 16)
| u32HorizontalStart));
}
/**
* @brief Get cropping window vertical/horizontal starting address.
*
* @param[out] pu32VerticalStart Cropping window vertical starting address.
* @param[out] pu32HorizontalStart Cropping window horizontal starting address.
*
* @return None.
*
* @details This function is used to get cropping window vertical/horizontal starting address.
*/
void CAP_GetCropWinStartAddr(PUINT32 pu32VerticalStart, PUINT32 pu32HorizontalStart)
{
UINT32 u32Temp = inp32(REG_CAP_CWSP);
*pu32VerticalStart = (u32Temp & CWSADDRV) >> 16;
*pu32HorizontalStart = u32Temp & CWSADDRH;
}
/**
* @brief Set cropping window size.
*
* @param[in] u32Width Cropping window width.
* @param[in] u32Height Cropping window heigh.
*
* @return None.
*
* @details This function is used to set cropping window size.
*/
void CAP_SetCropWinSize(UINT32 u32Height, UINT32 u32Width)
{
outp32(REG_CAP_CWS, (inp32(REG_CAP_CWS) & ~(CWH | CWW))
| ((u32Height << 16)
| u32Width));
}
/**
* @brief Get cropping window size.
*
* @param[out] pu32Width Cropping window width.
* @param[out] pu32Height Cropping window heigh.
*
* @return None.
*
* @details This function is used to get cropping window size.
*/
void CAP_GetCropWinSize(PUINT32 pu32Height, PUINT32 pu32Width)
{
UINT32 u32Temp = inp32(REG_CAP_CWS);
*pu32Height = (u32Temp & CWH) >> 16;
*pu32Width = u32Temp & CWW;
}
/**
* @brief Set packet/planar scaling vertical factor.
*
* @param[in] ePipe Pipe type.Including.
* - \ref eCAP_PACKET.
* - \ref eCAP_PLANAR.
* @param[in] u16Numerator Scaling Vertical Factor N.
* @param[in] u16Denominator Scaling Vertical Factor M.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to set packet/planar scaling vertical factor.
* The output image width will be equal to the image width * N/M.
* Note: The value of N must be equal to or less than M
*/
INT32 CAP_SetVerticalScaleFactor(E_CAP_PIPE ePipe, UINT16 u16Numerator, UINT16 u16Denominator)
{
UINT8 u8NumeratorL = u16Numerator & 0xFF, u8NumeratorH = u16Numerator >> 8;
UINT8 u8DenominatorL = u16Denominator & 0xFF, u8DenominatorH = u16Denominator >> 8;
if (ePipe == eCAP_PACKET)
{
outp32(REG_CAP_PKTSL, (inp32(REG_CAP_PKTSL) & ~(PKTSVNL | PKTSVML))
| ((u8NumeratorL << 24)
| (u8DenominatorL << 16)));
outp32(REG_CAP_PKTSM, (inp32(REG_CAP_PKTSM) & ~(PKTSHMH | PKTSVMH))
| ((u8NumeratorH << 24)
| (u8DenominatorH << 16)));
}
else if (ePipe == eCAP_PLANAR)
{
outp32(REG_CAP_PLNSL, (inp32(REG_CAP_PLNSL) & ~(PKTSVNL | PKTSVML))
| ((u8NumeratorL << 24)
| (u8DenominatorL << 16)));
outp32(REG_CAP_PLNSM, (inp32(REG_CAP_PLNSM) & ~(PKTSHMH | PKTSVMH))
| ((u8NumeratorH << 24)
| (u8DenominatorH << 16)));
}
else
return E_CAP_INVALID_PIPE;
return Successful;
}
/**
* @brief Get packet/planar scaling vertical factor.
*
* @param[in] ePipe Pipe type.Including.
* - \ref eCAP_PACKET.
* - \ref eCAP_PLANAR.
* @param[out] pu16Numerator Scaling Vertical Factor N.
* @param[out] pu16Denominator Scaling Vertical Factor M.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to get packet/planar scaling vertical factor.
* The output image width will be equal to the image width * N/M.
* Note: The value of N must be equal to or less than M
*/
INT32 DrvCAP_GetVerticalScaleFactor(E_CAP_PIPE ePipe, PUINT16 pu16Numerator, PUINT16 pu16Denominator)
{
UINT32 u32Temp1, u32Temp2;
if (ePipe == eCAP_PACKET)
{
u32Temp1 = inp32(REG_CAP_PKTSL);
u32Temp2 = inp32(REG_CAP_PKTSM);
}
else if (ePipe == eCAP_PLANAR)
{
u32Temp1 = inp32(REG_CAP_PLNSL);
u32Temp2 = inp32(REG_CAP_PLNSM);
}
else
return E_CAP_INVALID_PIPE;
*pu16Numerator = ((u32Temp1 & PKTSVNL) >> 24) | (((u32Temp2 & PKTSHMH) >> 24) << 8);
*pu16Denominator = (u32Temp1 & PKTSVML) >> 16 | (((u32Temp2 & PKTSVMH) >> 16) << 8);
return Successful;
}
/**
* @brief Set packet/planar scaling horizontal factor.
*
* @param[in] bPipe Pipe type.Including.
* - \ref eCAP_PACKET.
* - \ref eCAP_PLANAR.
* @param[in] u16Numerator Scaling Horizontal Factor N.
* @param[in] u16Denominator Scaling Horizontal Factor M.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to set packet/planar scaling horizontal factor.
* The output image width will be equal to the image width * N/M.
* Note: The value of N must be equal to or less than M
*/
INT32 CAP_SetHorizontalScaleFactor(E_CAP_PIPE bPipe, UINT16 u16Numerator, UINT16 u16Denominator)
{
UINT8 u8NumeratorL = u16Numerator & 0xFF, u8NumeratorH = u16Numerator >> 8;
UINT8 u8DenominatorL = u16Denominator & 0xFF, u8DenominatorH = u16Denominator >> 8;
if (bPipe == eCAP_PACKET)
{
outp32(REG_CAP_PKTSL, (inp32(REG_CAP_PKTSL) & ~(PKTSHNL | PKTSHML))
| ((u8NumeratorL << 8)
| u8DenominatorL));
outp32(REG_CAP_PKTSM, (inp32(REG_CAP_PKTSM) & ~(PKTSHNH | PKTSHMH))
| ((u8NumeratorH << 8)
| u8DenominatorH));
}
else if (bPipe == eCAP_PLANAR)
{
outp32(REG_CAP_PLNSL, (inp32(REG_CAP_PLNSL) & ~(PKTSHNL | PKTSHML))
| ((u8NumeratorL << 8)
| u8DenominatorL));
outp32(REG_CAP_PLNSM, (inp32(REG_CAP_PLNSM) & ~(PKTSHNH | PKTSHMH))
| ((u8NumeratorH << 8)
| u8DenominatorH));
}
else
return E_CAP_INVALID_PIPE;
return Successful;
}
/**
* @brief Get packet/planar scaling horizontal factor.
*
* @param[in] bPipe Pipe type.Including.
* - \ref eCAP_PACKET.
* - \ref eCAP_PLANAR.
* @param[out] pu16Numerator Scaling Horizontal Factor N.
* @param[out] pu16Denominator Scaling Horizontal Factor M.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to get packet/planar scaling horizontal factor.
* The output image width will be equal to the image width * N/M.
* Note: The value of N must be equal to or less than M.
*/
INT32 CAP_GetHorizontalScaleFactor(E_CAP_PIPE bPipe, PUINT16 pu16Numerator, PUINT16 pu16Denominator)
{
UINT32 u32Temp1, u32Temp2;
if (bPipe == eCAP_PACKET)
{
u32Temp1 = inp32(REG_CAP_PKTSL);
u32Temp2 = inp32(REG_CAP_PKTSM);
}
else if (bPipe == eCAP_PLANAR)
{
u32Temp1 = inp32(REG_CAP_PLNSL);
u32Temp2 = inp32(REG_CAP_PLNSM);
}
else
return E_CAP_INVALID_PIPE;
*pu16Numerator = ((u32Temp1 & PKTSHNL) >> 8) | (u32Temp2 & PKTSHNH);
*pu16Denominator = (u32Temp1 & PKTSHML) | ((u32Temp2 & PKTSHMH) << 8);
return Successful;
}
/**
* @brief Set scaling frame rate factor.
*
* @param[in] u8Numerator Scaling Frame Rate Factor N.
* @param[in] u8Denominator Scaling Frame Rate Factor M.
*
* @return None.
*
* @details This function is used to set scaling frame rate factor..
* The output image frame rate will be equal to input image frame rate * (N/M).
* Note: The value of N must be equal to or less than M.
*/
void DrvCAP_SetFrameRateScaleFactor(UINT8 u8Numerator, UINT8 u8Denominator)
{
outp32(REG_CAP_FRCTL, (inp32(REG_CAP_FRCTL) & ~(FRN | FRM))
| (((u8Numerator << 8) & FRN)
| (u8Denominator & FRM)));
} // DrvVideoIn_SetFrameRateScaleFactor
/**
* @brief Get scaling frame rate factor.
*
* @param[out] pu8Numerator Scaling Frame Rate Factor N.
* @param[out] pu8Denominator Scaling Frame Rate Factor M.
*
* @return None.
*
* @details This function is used to get scaling frame rate factor..
* The output image frame rate will be equal to input image frame rate * (N/M).
* Note: The value of N must be equal to or less than M.
*/
void DrvCAP_GetFrameRateScaleFactor(PUINT8 pu8Numerator, PUINT8 pu8Denominator)
{
UINT32 u32Temp = inp32(REG_CAP_FRCTL);
*pu8Numerator = (u32Temp & FRN) >> 8;
*pu8Denominator = u32Temp & FRM;
}
/**
* @brief Set address match
*
* @param[in] u32AddressMatch Compare Memory Base Address.It should be 0~0xFFFFFFFF.
*
* @return None.
*
* @details This function is used to set compare memory base address.
*/
void DrvCAP_SetAddressMatch(UINT32 u32AddressMatch)
{
outp32(REG_CAP_CMPADDR, u32AddressMatch);
}
/**
* @brief Get address match
*
* @param[out] pu32AddressMatch Compare Memory Base Address.It should be 0~0xFFFFFFFF.
*
* @return None.
*
* @details This function is used to get compare memory base address.
*/
void CAP_GetAddressMatch(PUINT32 pu32AddressMatch)
{
*pu32AddressMatch = inp32(REG_CAP_CMPADDR);
}
/**
* @brief Set frame output pixel stride width.
*
* @param[in] u32PacketStride Packet frame output pixel stride width.It should be 0~0x3FFF.
* @param[in] u32PlanarStride Planar frame output pixel stride width.It should be 0~0x3FFF.
*
* @return None.
*
* @details This function is used to set frame output pixel stride width.
*/
void CAP_SetStride(UINT32 u32PacketStride, UINT32 u32PlanarStride)
{
outp32(REG_CAP_STRIDE, ((u32PlanarStride << 16) & PLNSTRIDE) |
(u32PacketStride & PKTSTRIDE));
}
/**
* @brief Get frame output pixel stride width.
*
* @param[out] pu32PacketStride Packet frame output pixel stride width.It should be 0~0x3FFF.
* @param[out] pu32PlanarStride Planar frame output pixel stride width.It should be 0~0x3FFF.
*
* @return None.
*
* @details This function is used to get frame output pixel stride width.
*/
void CAP_GetStride(PUINT32 pu32PacketStride, PUINT32 pu32PlanarStride)
{
UINT32 u32Tmp = inp32(REG_CAP_STRIDE);
*pu32PlanarStride = (u32Tmp & PLNSTRIDE) >> 16;
*pu32PacketStride = u32Tmp & PKTSTRIDE;
}
/**
* @brief Set system memory packet/planar base address.
*
* @param[in] ePipe Pipe type.Including:
* - \ref eCAP_PACKET
* - \ref eCAP_PLANAR
*
* @param[in] eBuf Packet/Planar buffer address.
* - \ref eCAP_BUF0 :
* Packet : Packet base address 0
* Planar : Planar Y base address
* - \ref eCAP_BUF1
* Packet : Packet base address 1
* Planar : Planar U base address
* - \ref eCAP_BUF2
* Packet : None.
* Planar : Planar V base address
*
* @param[in] u32BaseStartAddr System Memory Base Address.It should be 0~0xFFFFFFFF.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to set system memory packet/planar base address.
*/
INT32 CAP_SetBaseStartAddress(E_CAP_PIPE ePipe, E_CAP_BUFFER eBuf, UINT32 u32BaseStartAddr)
{
if (ePipe == eCAP_PACKET)
{
if (eBuf > eCAP_BUF1)
return E_CAP_INVALID_BUF;
outp32(REG_CAP_PKTBA0 + eBuf * 4, u32BaseStartAddr);
}
else if (ePipe == eCAP_PLANAR)
{
if (eBuf > eCAP_BUF2)
return E_CAP_INVALID_BUF;
outp32(REG_CAP_YBA + eBuf * 4, u32BaseStartAddr);
}
else
return E_CAP_INVALID_PIPE;
return Successful;
}
/**
* @brief Get system memory packet/planar base address.
*
* @param[in] ePipe Pipe type.Including:
* - \ref eCAP_PACKET
* - \ref eCAP_PLANAR
*
* @param[in] eBuf Packet/Planar buffer address.
* - \ref eCAP_BUF0 :
* Packet : Packet base address 0
* Planar : Planar Y base address
* - \ref eCAP_BUF1
* Packet : Packet base address 1
* Planar : Planar U base address
* - \ref eCAP_BUF2
* Packet : None.
* Planar : Planar V base address
*
* @param[out] pu32BaseStartAddr System Memory Base Address.It should be 0~0xFFFFFFFF.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to get system memory packet/planar base address.
*/
INT32 CAP_GetBaseStartAddress(E_CAP_PIPE ePipe, E_CAP_BUFFER eBuf, PUINT32 pu32BaseStartAddr)
{
if (ePipe == eCAP_PACKET)
{
if (eBuf > eCAP_BUF1)
return E_CAP_INVALID_BUF;
*pu32BaseStartAddr = inp32(REG_CAP_PKTBA0 + eBuf * 4);
}
else if (ePipe == eCAP_PLANAR)
{
if (eBuf > eCAP_BUF2)
return E_CAP_INVALID_BUF;
*pu32BaseStartAddr = inp32(REG_CAP_YBA + eBuf * 4);
}
else
return E_CAP_INVALID_PIPE;
return Successful;
}
/**
* @brief Set standard CCIR656.
*
* @param[in] bIsStandard Standard CCIR656.
* - 1 : Standard CCIR656 mode.
* - 0 : Non-Standard CCIR656 mode. (OV7725 or Hynix 702)
* @return None.
*
* @details This function is used to set standard CCIR65/non-standard CCIR65.
*/
void CAP_SetStandardCCIR656(BOOL bIsStandard)
{
if (bIsStandard == TRUE)
outp32(REG_CAP_PAR, inp32(REG_CAP_PAR) & ~FBB); // Standard
else
outp32(REG_CAP_PAR, inp32(REG_CAP_PAR) | FBB); // Non-Standard
}
/**
* @brief Set color effect
*
* @param[in] eColorMode Available as following.
* - \ref eCAP_CEF_NORMAL : Normal Color.
* - \ref eCAP_CEF_SEPIA : Sepia effect,
* corresponding U,V component value is set at register - \ref REG_CAP_SEPIA.
* - \ref eCAP_CEF_NEGATIVE : Negative picture.
* - \ref eCAP_CEF_POSTERIZE : Posterize image,
* the Y, U, V components posterizing factor are set at register - \ref REG_CAP_POSTERIZE.
*
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to set color effect.
*/
INT32 CAP_SetColorEffect(E_CAP_CEF eColorMode)
{
if (eColorMode > eCAP_CEF_POSTERIZE)
return E_CAP_INVALID_COLOR_MODE;
outp32(REG_CAP_PAR, (inp32(REG_CAP_PAR) & ~COLORCTL) |
(eColorMode << 11));
return Successful;
}
/**
* @brief Get color effect
*
* @param[out] peColorMode Available as following.
* - \ref eCAP_CEF_NORMAL : Normal Color.
* - \ref eCAP_CEF_SEPIA : Sepia effect,
* corresponding U,V component value is set at register - \ref REG_CAP_SEPIA.
* - \ref eCAP_CEF_NEGATIVE : Negative picture.
* - \ref eCAP_CEF_POSTERIZE : Posterize image,
* the Y, U, V components posterizing factor are set at register - \ref REG_CAP_POSTERIZE.
*
* @return None.
*
* @details This function is used to get color effect.
*/
void DrvCAP_GetColorEffect(E_CAP_CEF *peColorMode)
{
UINT32 u32Tmp = inp32(REG_CAP_PAR);
*peColorMode = (E_CAP_CEF)((u32Tmp & COLORCTL) >> 11);
}
/**
* @brief Set color effect parameter
*
* @param[in] u8YComp The constant Y component.If eColorMode is set to
* eCAP_CEF_SEPIA : the constant Y component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant Y component in - \ref REG_CAP_POSTERIZE.
* @param[in] u8UComp The constant U component.
* eCAP_CEF_SEPIA : the constant U component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant U component in - \ref REG_CAP_POSTERIZE.
* @param[in] u8VComp The constant V component.
* eCAP_CEF_SEPIA : the constant V component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant V component in - \ref REG_CAP_POSTERIZE.
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to set color effect parameter.
*/
INT32 CAP_SetColorEffectParameter(UINT8 u8YComp, UINT8 u8UComp, UINT8 u8VComp)
{
UINT32 u32Tmp = inp32(REG_CAP_PAR);
UINT32 u32ColorMode = (u32Tmp & COLORCTL) >> 11;
if (u32ColorMode == eCAP_CEF_SEPIA)
{
outp32(REG_CAP_SEPIA, (((UINT32)u8UComp << 8) | u8VComp));
}
else if (u32ColorMode == eCAP_CEF_POSTERIZE)
{
outp32(REG_CAP_POSTERIZE, (((UINT32)u8YComp << 16) | ((UINT32)u8UComp << 8) | u8VComp));
}
else
{
return E_CAP_WRONG_COLOR_PARAMETER;
}
return Successful;
}
/**
* @brief Get color effect parameter
*
* @param[out] pu8YComp The constant Y component.If eColorMode is set to
* eCAP_CEF_SEPIA : the constant Y component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant Y component in - \ref REG_CAP_POSTERIZE.
* @param[out] pu8UComp The constant U component.
* eCAP_CEF_SEPIA : the constant U component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant U component in - \ref REG_CAP_POSTERIZE.
* @param[out] pu8VComp The constant V component.
* eCAP_CEF_SEPIA : the constant V component in - \ref REG_CAP_SEPIA.
* eCAP_CEF_POSTERIZE : the constant V component in - \ref REG_CAP_POSTERIZE.
* @retval 0 Success
* @retval <0 Error code
*
* @details This function is used to get color effect parameter.
*/
INT32 CAP_GetColorEffectParameter(PUINT8 pu8YComp, PUINT8 pu8UComp, PUINT8 pu8VComp)
{
UINT32 u32Tmp = inp32(REG_CAP_PAR);
UINT32 u32ColorMode = (u32Tmp & COLORCTL) >> 11;
if (u32ColorMode == eCAP_CEF_SEPIA)
{
u32Tmp = inp32(REG_CAP_SEPIA);
*pu8UComp = (u32Tmp & 0xFF00) >> 8;
*pu8VComp = u32Tmp & 0xFF;
}
else if (u32ColorMode == eCAP_CEF_POSTERIZE)
{
u32Tmp = inp32(REG_CAP_POSTERIZE);
*pu8YComp = (u32Tmp & 0xFF0000) >> 16;
*pu8UComp = (u32Tmp & 0xFF00) >> 8;
*pu8VComp = u32Tmp & 0xFF;
}
else
{
return E_CAP_WRONG_COLOR_PARAMETER;
}
return Successful;
}
/// @cond HIDDEN_SYMBOLS
CAPDEV_T CAP =
{
CAP_Init, // void (*Init)(BOOL bIsEnableSnrClock, E_CAP_SNR_SRC eSnrSrc, UINT32 u32SensorFreqKHz, E_CAP_DEV_TYPE eDevType):
CAP_Open, // INT32 (*Open)(UINT32 u32SensorFreqKHz);
CAP_Close, // void (*Close)(void);
CAP_SetPipeEnable, // void (*SetPipeEnable)(BOOL bEngEnable, E_CAP_PIPE ePipeEnable);
CAP_SetPlanarFormat, // void (*SetPlanarFormat)(E_CAP_PLANAR_FORMAT ePlanarFmt);
CAP_SetCropWinSize, // void (*SetCropWinSize)(UINT32 u32height, UINT32 u32width);
CAP_SetCropWinStartAddr, // void (*SetCropWinStartAddr)(UINT32 u32VerticalStart, UINT32 u32HorizontalStart);
CAP_SetStride, // void (*SetStride)(UINT32 u16packetstride, UINT32 u32planarstride);
CAP_GetStride, // void (*GetStride)(PUINT32 pu32PacketStride, PUINT32 pu32PlanarStride);
CAP_EnableInt, // INT32 (*EnableInt)(E_CAP_INT_TYPE eIntType);
CAP_DisableInt, // INT32 (*DisableInt)(E_CAP_INT_TYPE eIntType);
CAP_InstallCallback, // INT32 (*InstallCallback)(E_CAP_INT_TYPE eIntType, PFN_CAP_CALLBACK pfnCallback, PFN_CAP_CALLBACK *pfnOldCallback);
CAP_SetBaseStartAddress, // INT32 (*SetBaseStartAddress(E_CAP_PIPE ePipe, E_CAP_BUFFER eBuf, UINT32 u32BaseStartAddr);
CAP_SetOperationMode, // void (*SetOperationMode(BOOL bIsOneSutterMode);
CAP_GetOperationMode, // BOOL (*GetOperationMode)(void);
CAP_SetPacketFrameBufferControl, // void (*videoIn1_SetPacketFrameBufferControl)(BOOL bFrameSwitch, BOOL bFrameBufferSel);
CAP_SetSensorPolarity, // void (*videoIn1_SetSensorPolarity)(BOOL bVsync, BOOL bHsync, BOOL bPixelClk);
CAP_SetColorEffectParameter, // INT32 (*SetColorEffectParameter)(UINT8 u8YComp, UINT8 u8UComp, UINT8 u8VComp);
CAP_SetDataFormatAndOrder, // void (*SetDataFormatAndOrder)(E_CAP_ORDER eInputOrder, E_CAP_IN_FORMAT eInputFormat, E_CAP_OUT_FORMAT eOutputFormat)
CAP_SetMotionDet, // void (*SetMotionDet)(BOOL bEnable, BOOL bBlockSize,BOOL bSaveMode);
CAP_SetMotionDetEx, // void (*SetMotionDetEx)(UINT32 u32Threshold, UINT32 u32OutBuffer, UINT32 u32LumBuffer);
CAP_SetStandardCCIR656, // void (*SetStandardCcir656)(BOOL);
CAP_SetShadowRegister // void (*SetShadowRegister)(void);
};
/// @endcond HIDDEN_SYMBOLS
/*@}*/ /* end of group N9H30_CAP_EXPORTED_FUNCTIONS */
/*@}*/ /* end of group N9H30_CAP_Driver */
/*@}*/ /* end of group N9H30_Device_Driver */