Exemplo n.º 1
0
Arquivo: gpt.c Projeto: 12019/mtktest
/*
* FUNCTION                                                            
*	GPT_ResetTimer
*
* DESCRIPTION                                                           
*   	This function is to setup GPT parameters
*
* CALLS  
*	It is called to setup GPT parameters
*
* PARAMETERS
*	timerNum = 1(GPT1) or 2(GPT2)
*	countValue = GPT count
*	autoReload = KAL_TRUE,autoReload mode
*		     KAL_FALSE, Single shot mode
*	
* RETURNS
*	None
*
* GLOBALS AFFECTED
*   external_global
*/
void GPT_ResetTimer(kal_uint8 timerNum,kal_uint16 countValue,kal_bool autoReload)
{
	if (timerNum == 1)
	{
	   DRV_WriteReg(GPT1_LEN,countValue);
		if (autoReload == KAL_TRUE)
		{
			DRV_Reg(GPT1_CTRL) |= GPT_CTRL_AUTOMODE;
		}
		else
		{
			DRV_Reg(GPT1_CTRL) &= ~GPT_CTRL_AUTOMODE;
		}
	}

	if (timerNum == 2)
	{
	   DRV_WriteReg(GPT2_LEN,countValue);
		if (autoReload == KAL_TRUE)
		{
			DRV_Reg(GPT2_CTRL) |= GPT_CTRL_AUTOMODE;
		}
		else
		{
			DRV_Reg(GPT2_CTRL) &= ~GPT_CTRL_AUTOMODE;
		}		
	}
}
Exemplo n.º 2
0
Arquivo: pwm.c Projeto: 12019/mtktest
void PWM2_Configure(kal_uint32 freq, kal_uint8 duty)
{
   kal_uint32 clock;
   kal_uint32 tmp;
   kal_uint16 clkdiv;
   kal_uint16 reg;
   

   ASSERT(duty <= 100);
   PWM2_FRE_SAVE=freq;
   PWM2_DUTY_SAVE=duty;
   reg = DRV_Reg(PWM2_CTRL);
   
   clkdiv = (1 << (reg & 0x0003));
   
   if (reg & 0x0004)
      clock = 32000;
   else
      clock = 13000000;
   
   clock = clock/clkdiv;
   
   if(0==freq)
      tmp = clock/(freq+1);
   else 
      tmp = clock/(freq); 
   
   tmp--;
   DRV_WriteReg(PWM2_COUNT,(kal_uint16)tmp);
   tmp = ((tmp+1)*duty)/100;
   DRV_WriteReg(PWM2_THRESHOLD,(kal_uint16)tmp);
}
Exemplo n.º 3
0
static void mtk_wdt_reset(char mode)
{
    /* Watchdog Rest */
    unsigned short wdt_mode_val;
    DRV_WriteReg16(MTK_WDT_RESTART, MTK_WDT_RESTART_KEY); 

    wdt_mode_val = DRV_Reg(MTK_WDT_MODE);
    /* clear autorestart bit: autoretart: 1, bypass power key, 0: not bypass power key */
    wdt_mode_val &=(~MTK_WDT_MODE_AUTO_RESTART);
    /* make sure WDT mode is hw reboot mode, can not config isr mode  */
    wdt_mode_val &=(~(MTK_WDT_MODE_IRQ|MTK_WDT_MODE_ENABLE));
    
    if(mode){ /* mode != 0 means by pass power key reboot, We using auto_restart bit as by pass power key flag */
        wdt_mode_val = wdt_mode_val | (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN|MTK_WDT_MODE_AUTO_RESTART);
        //DRV_WriteReg(MTK_WDT_MODE, wdt_mode_val);
        //DRV_WriteReg(MTK_WDT_MODE, (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN|MTK_WDT_MODE_AUTO_RESTART));
    }else{
         wdt_mode_val = wdt_mode_val | (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN);
         //DRV_WriteReg(MTK_WDT_MODE,wdt_mode_val); 
        //DRV_WriteReg(MTK_WDT_MODE, (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN));
    }
    DRV_WriteReg(MTK_WDT_MODE,wdt_mode_val);  
    //DRV_WriteReg(MTK_WDT_LENGTH, MTK_WDT_LENGTH_KEY);
    gpt_busy_wait_us(100);
    DRV_WriteReg(MTK_WDT_SWRST, MTK_WDT_SWRST_KEY);
}
Exemplo n.º 4
0
static void tv_power_on(void)
{
	kal_uint32 save_irq_mask;

   /// Turn off TV PLL clock
	#if defined(DRV_TVOUT_6228_SERIES)
	DRV_Reg(DRVPDN_CON0_CLR) = DRVPDN_CON0_TPLL;
	#elif defined(DRV_TVOUT_6238_SERIES)
	   //KKKKK
	DRV_WriteReg(TPLL,0xe0);	   	   	   	   
	DRV_WriteReg(TPLL2,0x0);	   	   	   	   	   
	#endif
	
	/// Power on TV module
	DRV_Reg(DRVPDN_CON3_CLR) = DRVPDN_CON3_TV;

	save_irq_mask=SaveAndSetIRQMask();
	UPLL_Enable(UPLL_OWNER_TV);
	RestoreIRQMask(save_irq_mask);
	tv_operation_state=TV_DETECTION_STATE;

	/* turn on TV DAC */
	ENABLE_TV_HALF_BIAS_POWER;
	ENABLE_TV_DAC2_POWER;
	ENABLE_TV_DAC1_POWER;
	ENABLE_TV_DAC0_POWER;
	ENABLE_TV_BGVREF_POWER;
	ENABLE_TV_DAC_POWER;
	ENABLE_TV_ENCODER;
}	/* tv_power_on() */
Exemplo n.º 5
0
Arquivo: gpt.c Projeto: 12019/mtktest
/*
* FUNCTION                                                            
*	GPTI_BusyWait
*
* DESCRIPTION                                                           
*   	Use GPT2 as a counter to perform a busy waiting
*
* CALLS
*
* PARAMETERS
*	len: length of the counter in unit of 1ms
*
* RETURNS
*	None
*
* GLOBALS AFFECTED
*   
*/
void GPTI_BusyWait(kal_uint16 len)
{
	// disable PDN
   #if defined(DRV_MISC_PDN_NO_SET_CLR)
		DRV_Reg(DRVPDN_CON1) &= ~DRVPDN_CON1_GPT;
	#else
		DRV_WriteReg(DRVPDN_CON1_CLR, DRVPDN_CON1_GPT);
	#endif
	
	DRV_WriteReg(GPT2_LEN, len);
	DRV_WriteReg(GPT2_PRESCALER, clk_1k); // 1K HZ
	// one shot
	DRV_WriteReg(GPT2_CTRL, GPT_CTRL_Enable);
	while(!(DRV_Reg(GPT_STS) & GPT_STS_2));
	
	// set PDN
   #if defined(DRV_MISC_PDN_NO_SET_CLR)
		DRV_Reg(DRVPDN_CON1) |= DRVPDN_CON1_GPT;
	#else
		DRV_WriteReg(DRVPDN_CON1_SET, DRVPDN_CON1_GPT);
	#endif	
	
	
	
}
Exemplo n.º 6
0
void MT6573_sw_watchdog_reset(void)
{
    /* Watchdog Rest */
    DRV_WriteReg16(MT6573_WDT_RESTART, MT6573_WDT_RESTART_KEY); 
    DRV_WriteReg(MT6573_WDT_MODE, (MT6573_WDT_MODE_KEY|MT6573_WDT_MODE_EXTEN|MT6573_WDT_MODE_ENABLE));
    //DRV_WriteReg(MT6573_WDT_LENGTH, MT6573_WDT_LENGTH_KEY);
    DRV_WriteReg(MT6573_WDT_SWRST, MT6573_WDT_SWRST_KEY);
}
void B2PSI_write_fast(kal_uint8 data, kal_uint16 register_index)
{
#ifdef  __USB_DOWNLOAD__
   kal_uint16     write_data=0;   
   kal_uint16     i, status=0;
//   extern kal_uint8 pmic_reg_save[];
   
#if defined(__DRV_B2SPI_SHARE_PIN__)
	b2spi_serial_lock();
	B2PSI_init_sharePin();	
#endif   
   

   write_data=(register_index|B2PSI_WRITE_MASK|data);         
   DRV_WriteReg(DRVPDN_CON1+0x20,(kal_uint16)DRVPDN_CON1_B2SPI);
#if (defined(SUPERMAN29_DEMO_BB)&&defined(PCB01))
   GPIO_WriteIO(0, B2PSI_CS_PIN);
   for(debug_loop=0;debug_loop<debug_loop_cnt;debug_loop++){};
#endif
   //L1D_MeasureMaxDuration_Start( &b2psi_duration );
   DRV_WriteReg(B2PSI_DATA,B2PSI_DATA_KEY);   
#if (defined(SUPERMAN29_DEMO_BB)&&defined(PCB01))
   GPIO_WriteIO(1, B2PSI_CS_PIN);
#endif
   /*this short loop is becasue B2PSI needs this to change his state machine*/
   for(i=0;i<B2SPI_WAIT_CNT;i++){}   
#if (defined(SUPERMAN29_DEMO_BB)&&defined(PCB01))
   GPIO_WriteIO(0, B2PSI_CS_PIN);
   for(debug_loop=0;debug_loop<debug_loop_cnt;debug_loop++){};
#endif
   DRV_WriteReg(B2PSI_DATA,write_data); 
   //L1D_MeasureMaxDuration_Stop( &b2psi_duration );
   /*write data to reg_save*/     
   //pmic_reg_save[(register_index>>PMIC_SHIFT_BITS)]=data;
   //dbg_data=data;
   //dbg_index=register_index;  
   do 
   {
      status=DRV_Reg(B2PSI_STAT);       
   }
   while(!(status&=0x2));
#if (defined(SUPERMAN29_DEMO_BB)&&defined(PCB01))
   GPIO_WriteIO(1, B2PSI_CS_PIN);
#endif
    
#if defined(__DRV_B2SPI_SHARE_PIN__)
	serial_init_sharePin();
	b2spi_serial_unlock();
#endif

   DRV_WriteReg(DRVPDN_CON1+0x10,(kal_uint16)DRVPDN_CON1_B2SPI);
#endif  /* __USB_DOWNLOAD__ */
}
Exemplo n.º 8
0
/*
* FUNCTION                                                            
*	GPIO_PullenSetup
*
* DESCRIPTION                                                           
*   	This function is to enable or disable the pull up/down of the related GPIO pin.
*		You can not decide to pull up or down, it is set inside the chip.
*		And, the setting is different from pin by pin.
*
* PARAMETERS
 
*	enable: enable the pull up/down
*	
* RETURNS
*	None
*
* GLOBALS AFFECTED
*
*/
   void GPIO_PullenSetup(kal_uint16 pin, kal_bool enable)
   {
      kal_uint16 modeno;
      kal_uint16 remainder;
      
      modeno = pin/16;
      remainder = pin % 16;

		if(enable)
      	DRV_WriteReg(GPIO_PULLEN_SET(modeno), 1 << remainder);
      else
      	DRV_WriteReg(GPIO_PULLEN_CLR(modeno), 1 << remainder);
   }
Exemplo n.º 9
0
/*
* FUNCTION
*	   IMGPROC_SetBrightContrast
*
* DESCRIPTION
*   	Set the parameters for brightness and contrast
*
* CALLS
*
* PARAMETERS
*
* RETURNS
*	   None
*
* GLOBALS AFFECTED
*     None
*/
kal_int32 API IMGPROC_SetBrightContrast(MMDI_SCENERIO_ID owner, IMGPROC_BRI_CON_STURCT* s)
{
#if (defined(DRV_IDP_6219_SERIES))
	ASSERT(owner == imgproc_dcb.owner);
#elif (defined(DRV_IDP_6228_SERIES))
	if (current_image_data_path_owner!=owner)
		ASSERT(0);
#endif
	DRV_WriteReg(IMGPROC_BRIADJ1,s->bright);
	DRV_WriteReg(IMGPROC_BRIADJ2,s->dark);
	DRV_WriteReg(IMGPROC_CONADJ,s->contrast);

	return NO_ERROR;
}
Exemplo n.º 10
0
/*
* FUNCTION
*	   IMGPROC_SetHUE
*
* DESCRIPTION
*   	set the parameters for HUE adjustment
*
* CALLS
*
* PARAMETERS
*
* RETURNS
*	   None
*
* GLOBALS AFFECTED
*     None
*/
kal_int32 API IMGPROC_SetHUE(MMDI_SCENERIO_ID owner, IMGPROC_HUE_STURCT* s)
{
#if (defined(DRV_IDP_6219_SERIES))
	ASSERT(owner == imgproc_dcb.owner);
#elif (defined(DRV_IDP_6228_SERIES))
	if (current_image_data_path_owner!=owner)
		ASSERT(0);
#endif

	DRV_WriteReg(IMGPROC_HUE11,s->c11);
	DRV_WriteReg(IMGPROC_HUE12,s->c12);
	DRV_WriteReg(IMGPROC_HUE21,s->c21);
	DRV_WriteReg(IMGPROC_HUE22,s->c22);

	return NO_ERROR;
}
Exemplo n.º 11
0
static void tv_power_off(void)
{
	kal_uint32 save_irq_mask;

	/* turn off TV DAC */
	DISABLE_TV_HALF_BIAS_POWER;
	DISABLE_TV_DAC2_POWER;
	DISABLE_TV_DAC1_POWER;
	DISABLE_TV_DAC0_POWER;
	DISABLE_TV_BGVREF_POWER;
	DISABLE_TV_DAC_POWER;

	DISABLE_TV_ENCODER;
	DISABLE_TV_CONTROLLER;
	RESET_TV_CONTROLLER;
	tv_src_width=0;
	tv_src_height=0;

   /// Turn off TV PLL clock
	#if defined(DRV_TVOUT_6228_SERIES)
	DRV_Reg(DRVPDN_CON0_SET) = DRVPDN_CON0_TPLL;
	#elif defined(DRV_TVOUT_6238_SERIES)
	   //KKKKK
	   DRV_WriteReg(TPLL2,0x1);	   	   	   	   
	#endif
	/// Power off TV module
	DRV_Reg(DRVPDN_CON3_SET) = DRVPDN_CON3_TV;

	save_irq_mask=SaveAndSetIRQMask();
	UPLL_Disable(UPLL_OWNER_TV);
	RestoreIRQMask(save_irq_mask);

	tv_operation_state=TV_IDLE_STATE;
}	/* tv_power_off() */
Exemplo n.º 12
0
/**********************************************************
Description : Wait for 32KHz clock srouce stable.
Input       : None
Output      : None
***********************************************************/
void WaitFor32KStable(void)
{
   kal_uint32 result;
   kal_uint16 result_low;
   kal_uint16 result_high;
   
   * (volatile kal_uint16 *) DRVPDN_CON2_CLR = DRVPDN_CON2_TDMA;
   
   DRV_WriteReg(SM_FMDURATION,0);
       
   while(1)
   {
      DRV_Reg(SM_CTRL) |= SM_CTRL_FM_START;
      
      while(!(DRV_Reg(SM_STAT) & SM_STAT_FM_RDY));
      
      result_low = DRV_Reg(SM_FM_RESULT_LOW);
      result_high = DRV_Reg(SM_FM_RESULT_HIGH) & SM_FM_RESULT_HIGH_MASK;
      result = (result_low | (result_high << 16));
      
      if ((result < 950) && (result > 650))
         break;   	
   }
   
   * (volatile kal_uint16 *) DRVPDN_CON2_SET = DRVPDN_CON2_TDMA;
}
Exemplo n.º 13
0
void irda_switch_to_mir(void)
{
	/*Vishay 6614*/
	#if defined(__IRDA_VISHAY_6102__)
	GPIO_WriteIO(1, IRDA_GPIO_MODE_SWITCH);	
	#elif defined(__IRDA_VISHAY_6614__)
	DRV_WriteReg(IR_TRANSCEIVER_PDN,0x1);	
	irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x7);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x6);   	   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x4);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x0);
	#endif
}
Exemplo n.º 14
0
Arquivo: gpt.c Projeto: 12019/mtktest
/*
* FUNCTION                                                            
*	GPT_Stop
*
* DESCRIPTION                                                           
*   	Stop GPT timer
*
* CALLS  
*	It is called to stop GPT timer
*
* PARAMETERS
*	timerNum = 1(GPT1) or 2(GPT2)
*	
* RETURNS
*	None
*
* GLOBALS AFFECTED
*   external_global
*/
void GPT_Stop(kal_uint8 timerNum)
{
   kal_uint16 gpt_ctrl1;
   kal_uint16 gpt_ctrl2;
#if defined(DRV_GPT_GPT3)
   kal_uint16 gpt_ctrl3;
#endif   
   gpt_ctrl1 = DRV_Reg(GPT1_CTRL);
   gpt_ctrl2 = DRV_Reg(GPT2_CTRL);
#if defined(DRV_GPT_GPT3)
   gpt_ctrl3 = DRV_Reg(GPT3_CTRL);
#endif   
	if (timerNum == 1)
	{
	   gpt_ctrl1 &= ~GPT_CTRL_Enable;
		DRV_WriteReg(GPT1_CTRL,gpt_ctrl1);
	}
	if (timerNum == 2)
	{
	   gpt_ctrl2 &= ~GPT_CTRL_Enable;
		DRV_WriteReg(GPT2_CTRL,gpt_ctrl2);
	}
#if defined(DRV_GPT_GPT3)
   if (timerNum == 3)
	{
	   gpt_ctrl3 =(kal_uint16) ~GPT3_ENABLE;
		DRV_WriteReg(GPT3_CTRL,gpt_ctrl3);
	}
		
   if ( (((gpt_ctrl1|gpt_ctrl2)&GPT_CTRL_Enable)==0)&& (!(gpt_ctrl3&GPT3_ENABLE)))
#else
	if ( ((gpt_ctrl1|gpt_ctrl2)&GPT_CTRL_Enable)==0  )
#endif	   
   {
	   kal_uint16 GPT_Status;

	   GPT_Status = DRV_Reg(GPT_STS);
      IRQMask(IRQ_GPT_CODE);
      IRQClearInt(IRQ_GPT_CODE);
   #ifdef GPT_DRVPDN_FAST
	   DRVPDN_ENABLE2(DRVPDN_CON1,DRVPDN_CON1_GPT,PDN_GPT);	   
   #else
	   DRVPDN_Enable(DRVPDN_CON1,DRVPDN_CON1_GPT,PDN_GPT);	  
   #endif
   }
}
Exemplo n.º 15
0
static void mtk_wdt_disable(void)
{
    u16 tmp;

    tmp = DRV_Reg(MTK_WDT_MODE);
    tmp &= ~MTK_WDT_MODE_ENABLE;       /* disable watchdog */
    tmp |= (MTK_WDT_MODE_KEY);         /* need key then write is allowed */
    DRV_WriteReg(MTK_WDT_MODE,tmp);
}
Exemplo n.º 16
0
void irda_switch_to_fir(void)
{	
	#if defined(__IRDA_VISHAY_6102__)
	/*Vishay 6614*/
	GPIO_WriteIO(1, IRDA_GPIO_MODE_SWITCH);
	/*Vishay 6102, Anilent 3220*/
	#elif defined(__IRDA_AGILENT_3220__)||defined(__IRDA_VISHAY_6614__)
	DRV_WriteReg(IR_TRANSCEIVER_PDN,0x1);	
	irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x7);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x6);   	   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x4);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x0);
   #endif
}   
Exemplo n.º 17
0
Arquivo: pdn.c Projeto: 12019/mtktest
void DRV_PDN_DIS(void *parameter)
{
   PDN_INPUT *pdn_data = (PDN_INPUT *)parameter;
#if defined(MT6208) || defined(MT6205)
   DRV_Reg(pdn_data->addr) |= pdn_data->code;
#else
   DRV_WriteReg((pdn_data->addr+0x20), pdn_data->code);
#endif
}
Exemplo n.º 18
0
/* config SRAM back from L2 cache for DA relocation */
void config_shared_SRAM_size(void)
{
        volatile unsigned int cache_cfg;
        /* set L2C size to 256KB */
        cache_cfg = DRV_Reg(MCUSYS_CFGREG_BASE);
        cache_cfg &= (~0x7) << L2C_SIZE_CFG_OFF;
        cache_cfg |= 0x1 << L2C_SIZE_CFG_OFF;
        DRV_WriteReg(MCUSYS_CFGREG_BASE, cache_cfg);
}
Exemplo n.º 19
0
void hw_watchdog_disable(void)
{
    u16 tmp;
    
    tmp = DRV_Reg(MT6573_WDT_MODE);
    tmp &= ~MT6573_WDT_MODE_ENABLE;		  /* disable watchdog */
    tmp |= (MT6573_WDT_MODE_KEY);       /* need key then write is allowed */
    DRV_WriteReg(MT6573_WDT_MODE,tmp);
}
Exemplo n.º 20
0
 /*conf_data = 0~3*/
 void GPIO_ModeSetup(kal_uint16 pin, kal_uint16 conf_dada)
 {
    kal_uint16 modeno;
    kal_uint16 remainder;
    
    modeno = pin/8;
    remainder = pin % 8;
    #if defined(MT6226)|| defined(MT6227)
    if(pin>=56)/*special case  */
    {
       DRV_WriteReg(GPIO_MODE8_CLR,(0x0003 << (remainder*2)));
       DRV_WriteReg(GPIO_MODE8_SET,(conf_dada << (remainder*2)));
       return;
    }
    #endif                  
    
    DRV_WriteReg(GPIO_MODE_CLR(modeno),(0x0003 << (remainder*2)));
    DRV_WriteReg(GPIO_MODE_SET(modeno),(conf_dada << (remainder*2)));
 }
Exemplo n.º 21
0
   /*conf_data = 0~3*/
   void GPO_ModeSetup(kal_uint16 pin, kal_uint16 conf_dada)
   {

     kal_uint16 mode; 
      
      mode = DRV_Reg(GPI_O_MODE);
      mode &= ~(0x0003 << (pin*2));
      mode |= (conf_dada << (pin*2));
      DRV_WriteReg(GPI_O_MODE,mode);
   }
Exemplo n.º 22
0
static void mtk_wdt_reset(char mode)
{
    /* Watchdog Rest */
    unsigned short wdt_mode_val;
    DRV_WriteReg16(MTK_WDT_RESTART, MTK_WDT_RESTART_KEY); 

    wdt_mode_val = DRV_Reg(MTK_WDT_MODE);
    if(mode){ /* mode != 0 means by pass power key reboot, We using auto_restart bit as by pass power key flag */
        wdt_mode_val = wdt_mode_val | (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN|MTK_WDT_MODE_AUTO_RESTART);
        DRV_WriteReg(MTK_WDT_MODE, wdt_mode_val);
        //DRV_WriteReg(MTK_WDT_MODE, (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN|MTK_WDT_MODE_AUTO_RESTART));
    }else{
         wdt_mode_val = wdt_mode_val | (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN);
         DRV_WriteReg(MTK_WDT_MODE,wdt_mode_val); 
        //DRV_WriteReg(MTK_WDT_MODE, (MTK_WDT_MODE_KEY|MTK_WDT_MODE_EXTEN));
    }
    //DRV_WriteReg(MTK_WDT_LENGTH, MTK_WDT_LENGTH_KEY);
    gpt_busy_wait_us(100);
    DRV_WriteReg(MTK_WDT_SWRST, MTK_WDT_SWRST_KEY);
}
Exemplo n.º 23
0
/*
* FUNCTION
*	   IMGPROC_SetSAT
*
* DESCRIPTION
*   	set the saturations
*
* CALLS
*
* PARAMETERS
*
* RETURNS
*	   None
*
* GLOBALS AFFECTED
*     None
*/
kal_int32 API IMGPROC_SetSAT(MMDI_SCENERIO_ID owner, kal_uint8 sat)
{
#if (defined(DRV_IDP_6219_SERIES))
	ASSERT(owner == imgproc_dcb.owner);
#elif (defined(DRV_IDP_6228_SERIES))
	if (current_image_data_path_owner!=owner)
		ASSERT(0);
#endif
	DRV_WriteReg(IMGPROC_SAT,sat);
	return NO_ERROR;
}
Exemplo n.º 24
0
void irda_switch_to_sir(void)
{
	#if defined(__IRDA_VISHAY_6102__)
	/*Vishay 6614*/
   #ifndef __CUST_NEW__
   GPIO_ModeSetup(IRDA_GPIO_MODE_SWITCH, 0);
   GPIO_InitIO(OUTPUT, IRDA_GPIO_MODE_SWITCH);   	
   #endif /* __CUST_NEW__ */
	GPIO_WriteIO(0, IRDA_GPIO_MODE_SWITCH);			
	#elif defined(__IRDA_AGILENT_3220__)||defined(__IRDA_VISHAY_6614__)	
		
	
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x1);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x5);   
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x4);         
   irda_delay(irda_test_delay);
   DRV_WriteReg(IR_TRANSCEIVER_PDN,0x0);
   #endif
}	
Exemplo n.º 25
0
Arquivo: gpio.c Projeto: 12019/mtktest
 /*conf_data = 0~3*/
 void GPO_ModeSetup(kal_uint16 pin, kal_uint16 conf_dada)
 {
    kal_uint16 mode; 
    kal_uint32 savedMask;
    
    savedMask = SAVEANDSETIRQMASK();
    mode = DRV_Reg(GPIO_MODE4);
    mode &= ~(0x0003 << (pin*2));
    mode |= (conf_dada << (pin*2));
    DRV_WriteReg(GPIO_MODE4,mode);
    RESTOREIRQMASK(savedMask);
 }
Exemplo n.º 26
0
Arquivo: gpt.c Projeto: 12019/mtktest
/*
* FUNCTION                                                            
*	GPT_clock
*
* DESCRIPTION                                                           
*   	This function is to setup GPT clock
*
* CALLS  
*	It is called to setup GPT clock
*
* PARAMETERS
*	timerNum = 1(GPT1) or 2(GPT2)
*	clock = clk_16k,
*		clk_8k,
*		clk_4k,
*		clk_2k,
*		clk_1k,
*		clk_500,
*		clk_250,
*		clk_125
*	
* RETURNS
*	None
*
* GLOBALS AFFECTED
*   external_global
*/
void GPT_clock(kal_uint8 timerNum ,gpt_clock clock)
{
	kal_uint16 *ptr_addr=0;
	if ( timerNum == 1)
	{
		ptr_addr = (kal_uint16 *)GPT1_PRESCALER;
	}
	if ( timerNum == 2)
	{
		ptr_addr = (kal_uint16 *)GPT2_PRESCALER;
	}
	
	switch(clock)
	{
		case clk_16k:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div2);
			break;
			
		case clk_8k:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div4);
			break;			
			
		case clk_4k:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div8);
			break;			
			
		case clk_2k:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div16);
			break;			
			
		case clk_1k:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div32);
			break;			
			
		case clk_500:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div64);
			break;			
			
		case clk_250:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div128);
			break;			
			
		case clk_125:
		   DRV_WriteReg(ptr_addr,GPT_PRESCALER_div256);
			break;
			
		default:
			break;
	}
}
Exemplo n.º 27
0
   /*conf_data = 0~3*/
   void GPIO_ModeSetup(kal_uint16 pin, kal_uint16 conf_dada)
    {
      kal_uint16 modeno;
      kal_uint16 remainder;
      kal_uint16 data;
      modeno = pin/8;
      remainder = pin % 8;
      data=DRV_Reg(GPIO_MODE(modeno)); 
      data&=~(0x3 << (2*remainder));
      data|= (conf_dada << (remainder*2));
      DRV_WriteReg(GPIO_MODE(modeno),data);
  

   }
Exemplo n.º 28
0
/*
* FUNCTION
*	   IMGPROC_SetMask
*
* DESCRIPTION
*   	Set the content of the mask(for filtering mode)
*
* CALLS
*
* PARAMETERS
*
* RETURNS
*	   None
*
* GLOBALS AFFECTED
*     None
*/
kal_int32 API IMGPROC_SetMaskContent(MMDI_SCENERIO_ID owner, IMGPROC_MASK_STURCT* s)
{
#if (defined(DRV_IDP_6219_SERIES))
	ASSERT(owner == imgproc_dcb.owner);
#elif (defined(DRV_IDP_6228_SERIES))
	if (current_image_data_path_owner!=owner)
		ASSERT(0);
#endif
	DRV_WriteReg(IMGPROC_MASK11,s->c11);
	DRV_WriteReg(IMGPROC_MASK12,s->c12);
	DRV_WriteReg(IMGPROC_MASK13,s->c13);
	DRV_WriteReg(IMGPROC_MASK21,s->c21);
	DRV_WriteReg(IMGPROC_MASK22,s->c22);
	DRV_WriteReg(IMGPROC_MASK23,s->c23);
	DRV_WriteReg(IMGPROC_MASK31,s->c31);
	DRV_WriteReg(IMGPROC_MASK32,s->c32);
	DRV_WriteReg(IMGPROC_MASK33,s->c33);

	return NO_ERROR;
}
Exemplo n.º 29
0
Arquivo: gcu.c Projeto: 12019/mtktest
/*
* FUNCTION                                                            
*	GCU_InputData
*
* DESCRIPTION                                                           
*   	Input GPRS Encryption Algorithm keys.
*	(Message keys and Secret keys)
*
* CALLS  
*
* PARAMETERS
*	data: the struct of the message keys and secret keys
*	
* RETURNS
*	None
*
* GLOBALS AFFECTED
*   external_global
*/
void GCU_InputData(gcu_input *data)
{
	//Secret Key 0-4
	DRV_WriteReg(GCU_KC0,data->SK0);
	DRV_WriteReg(GCU_KC1,data->SK1);
	DRV_WriteReg(GCU_KC2,data->SK2);
	DRV_WriteReg(GCU_KC3,data->SK3);
	
	//Message Key 0-1
	DRV_WriteReg(GCU_INPUT0,data->MK0);
	DRV_WriteReg(GCU_INPUT1,data->MK1);
	
	if (data->DIRECTION == 1)
	   DRV_WriteReg(GCU_CTRL,(GCU_CTRL_DIR |GCU_CTRL_NORMAL));
	else
	   DRV_WriteReg(GCU_CTRL,GCU_CTRL_NORMAL);
}
Exemplo n.º 30
0
Arquivo: gpio.c Projeto: 12019/mtktest
   /*conf_data = 0~3*/
   void GPIO_ModeSetup(kal_uint16 pin, kal_uint16 conf_dada)
   {
      kal_uint16 modeno;
      kal_uint16 remainder;
      kal_uint16 data;
      kal_uint32 savedMask;

      modeno = pin/8;
      remainder = pin % 8;
      savedMask = SAVEANDSETIRQMASK();
      data=DRV_Reg(GPIO_MODE(modeno)); 
      data&=~(0x3 << (2*remainder));
      data|= (conf_dada << (remainder*2));
      DRV_WriteReg(GPIO_MODE(modeno),data);
      RESTOREIRQMASK(savedMask);
   }