arch/arm/cpu/armv8/g12a/firmware/scp_task/scp_adc.c - u-boot - Git at Google

 #define MESON_CPU_MAJOR_ID_GXBB		0x1F
 #define MESON_CPU_MAJOR_ID_GXTVBB	0x20
 #define MESON_CPU_MAJOR_ID_GXL		0x21
 #define MESON_CPU_MAJOR_ID_GXM		0x22
 #define MESON_CPU_MAJOR_ID_TXL		0x23
 #define MESON_CPU_MAJOR_ID_TXLX		0x24
 #define MESON_CPU_MAJOR_ID_G12A		0x28

 static int adc_type; /*1:12bit; 0:10bit*/

 static void aml_set_reg32_bits(volatile uint32_t *_reg,
 		const uint32_t _value,
 		const uint32_t _start,
 		const uint32_t _len)
 {
 	writel(((readl((volatile unsigned int *)_reg) & \
 		~(((1L << (_len) )-1) << (_start))) | \
 		((unsigned)((_value) & ((1L<<(_len))-1)) << (_start))),
 		(volatile void *)_reg );
 }

 static unsigned int aml_get_reg32_bits(volatile uint32_t *_reg,
 		const unsigned int _start,
 		const unsigned int _len)
 {
 	return	((readl((volatile unsigned int *)_reg) >> (_start)) & \
 		((1L << (_len) ) - 1));
 }

 static void aml_write_reg32(volatile uint32_t *_reg,
 		const uint32_t _value)
 {
 	writel(_value, (volatile unsigned int *)_reg );
 };

 static unsigned int aml_read_reg32(volatile uint32_t *_reg)
 {
 	return readl((volatile unsigned int *)_reg);
 };

 static int get_cpu_family_id(void)
 {
 	return ((aml_read_reg32(P_AO_SEC_SD_CFG8) >> 24) & 0xff);
 }

 /*
  * description: used to enable and disable the clock of the SARADC
  * onoff: 1: enable ; 0: disable
  */
 static void saradc_clock_switch(int onoff)
 {
 /* if the famiy id of the cpu greater than or equal to MESON_CPU_MAJOR_ID_GXBB,
  * the clock switch from the clock tree register, otherwise from
  * the adc module register.
  */
 	if (onoff) {
 		if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB)
 			aml_set_reg32_bits(P_AO_SAR_CLK, 1, 8, 1);
 		else
 			aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 1, 30, 1);
 	} else {
 		if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB)
 			aml_set_reg32_bits(P_AO_SAR_CLK, 0, 8, 1);
 		else
 			aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 0, 30, 1);
 	}
 }
 static inline void saradc_power_control(int on)
 {
 	if (on) {
 		aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 1, 13, 1);
 		if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_G12A)
 			aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 0, 5, 2);
 		else
 			aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 3, 5, 2);
 		aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 1, 21, 1);

 		_udelay(5);

 		saradc_clock_switch(1);
 	}	else {
 		saradc_clock_switch(0);
 		aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 0, 21, 1);
 	}
 }

 /*
  * description: used to set the DIV of the clock
  */
 static void saradc_clock_set(unsigned char val)
 {
 /* if the famiy id of the cpu greater than or equal to MESON_CPU_MAJOR_ID_GXBB,
  * the clock switch from the clock tree register, otherwise from
  * the adc module register.
  */
 	if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB) {
 		/*bit[0-7]: set clk div; bit[9-10]: select clk source*/
 		aml_set_reg32_bits(P_AO_SAR_CLK, 0, 9, 2);
 		aml_set_reg32_bits(P_AO_SAR_CLK, (val & 0xff), 0, 8);
 	} else {
 		/*bit10-bit15: set clk div*/
 		aml_set_reg32_bits(P_AO_SAR_ADC_REG3, (val & 0x3f), 10, 6);
 	}
 }

 void saradc_enable(void)
 {
 	if (get_cpu_family_id() <= MESON_CPU_MAJOR_ID_GXTVBB)
 		adc_type = 0;
 	else
 		adc_type = 1;

 	aml_write_reg32(P_AO_SAR_ADC_REG0, 0x84004040);
 	aml_write_reg32(P_AO_SAR_ADC_CHAN_LIST, 0);
 	/* REG2: all chanel set to 8-samples & median averaging mode */
 	aml_write_reg32(P_AO_SAR_ADC_AVG_CNTL, 0);
 	aml_write_reg32(P_AO_SAR_ADC_REG3, 0x9388000a);

 	if (adc_type)
 		aml_set_reg32_bits(P_AO_SAR_ADC_REG3,0x1,27,1);

 	saradc_clock_set(20);

 	aml_write_reg32(P_AO_SAR_ADC_DELAY, 0x10a000a);
 	aml_write_reg32(P_AO_SAR_ADC_AUX_SW, 0x3eb1a0c);
 	aml_write_reg32(P_AO_SAR_ADC_CHAN_10_SW, 0x8c000c);
 	aml_write_reg32(P_AO_SAR_ADC_DETECT_IDLE_SW, 0xc000c);

 	saradc_power_control(1);
 }

 int get_adc_sample_gxbb(int ch)
 {
 	int value=0;
 	int count=0;
 	int sum=0;

 	aml_write_reg32(P_AO_SAR_ADC_CHAN_LIST, ch);
 	aml_write_reg32(P_AO_SAR_ADC_DETECT_IDLE_SW, (0xc000c | (ch<<23) | (ch<<7)));
 	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 0, 1);
 	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 2, 1);

 	count = 0;
 	do {
 		_udelay(10);
 		if (!(aml_read_reg32(P_AO_SAR_ADC_REG0) & 0x70000000))
 			break;
 		else if (++count > 10000) {
 			uart_puts("busy error");
 			uart_puts("\n");
 			value = -1;
 			goto end;
 		}
 	} while (1);

 	count = 0;
 	sum = 0;
 	while (aml_get_reg32_bits(P_AO_SAR_ADC_REG0, 21, 5) && (count < 32)) {
         value = aml_read_reg32(P_AO_SAR_ADC_FIFO_RD);
 		if (((value >> 12) & 0x07) == ch) {
 			value &= 0xffc;
 			value >>= 2;
 			sum += value;
 			count++;
 		} else {
 			uart_puts("channel error");
 			uart_puts("\n");
 		}
 	}
 	if (!count) {
 		value = -1;
 		goto end;
 	}
 	value = sum / count;

 end:
 	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 14, 1);
 	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 0, 0, 1);

 	return value;
 }

 int saradc_disable(void)
 {
 	saradc_power_control(0);
 	return 0;
 }

 int check_adc_key_resume(void)
 {
 	int value;
 	int min;
 	int max;

 	/*the sampling value of adc: 0-1023*/
 	min = CONFIG_ADC_POWER_KEY_VAL - 40;
 	if (min < 0)
 		min = 0;
 	max = CONFIG_ADC_POWER_KEY_VAL + 40;
 	if (max > 1023)
 		max = 1023;

 	value = get_adc_sample_gxbb(CONFIG_ADC_POWER_KEY_CHAN);
 	if ((value >= min) && (value <= max))
 		return 1;
 	else
 		return 0;
 }
	#define MESON_CPU_MAJOR_ID_GXBB 0x1F
	#define MESON_CPU_MAJOR_ID_GXTVBB 0x20
	#define MESON_CPU_MAJOR_ID_GXL 0x21
	#define MESON_CPU_MAJOR_ID_GXM 0x22
	#define MESON_CPU_MAJOR_ID_TXL 0x23
	#define MESON_CPU_MAJOR_ID_TXLX 0x24
	#define MESON_CPU_MAJOR_ID_G12A 0x28

	static int adc_type; /1:12bit; 0:10bit/

	static void aml_set_reg32_bits(volatile uint32_t *_reg,
	const uint32_t _value,
	const uint32_t _start,
	const uint32_t _len)
	{
	writel(((readl((volatile unsigned int *)_reg) & \
	~(((1L << (_len) )-1) << (_start))) \| \
	((unsigned)((_value) & ((1L<<(_len))-1)) << (_start))),
	(volatile void *)_reg );
	}

	static unsigned int aml_get_reg32_bits(volatile uint32_t *_reg,
	const unsigned int _start,
	const unsigned int _len)
	{
	return ((readl((volatile unsigned int *)_reg) >> (_start)) & \
	((1L << (_len) ) - 1));
	}

	static void aml_write_reg32(volatile uint32_t *_reg,
	const uint32_t _value)
	{
	writel(_value, (volatile unsigned int *)_reg );
	};

	static unsigned int aml_read_reg32(volatile uint32_t *_reg)
	{
	return readl((volatile unsigned int *)_reg);
	};

	static int get_cpu_family_id(void)
	{
	return ((aml_read_reg32(P_AO_SEC_SD_CFG8) >> 24) & 0xff);
	}

	/*
	* description: used to enable and disable the clock of the SARADC
	* onoff: 1: enable ; 0: disable
	*/
	static void saradc_clock_switch(int onoff)
	{
	/* if the famiy id of the cpu greater than or equal to MESON_CPU_MAJOR_ID_GXBB,
	* the clock switch from the clock tree register, otherwise from
	* the adc module register.
	*/
	if (onoff) {
	if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB)
	aml_set_reg32_bits(P_AO_SAR_CLK, 1, 8, 1);
	else
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 1, 30, 1);
	} else {
	if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB)
	aml_set_reg32_bits(P_AO_SAR_CLK, 0, 8, 1);
	else
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 0, 30, 1);
	}
	}
	static inline void saradc_power_control(int on)
	{
	if (on) {
	aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 1, 13, 1);
	if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_G12A)
	aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 0, 5, 2);
	else
	aml_set_reg32_bits(P_AO_SAR_ADC_REG11, 3, 5, 2);
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 1, 21, 1);

	_udelay(5);

	saradc_clock_switch(1);
	} else {
	saradc_clock_switch(0);
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3, 0, 21, 1);
	}
	}

	/*
	* description: used to set the DIV of the clock
	*/
	static void saradc_clock_set(unsigned char val)
	{
	/* if the famiy id of the cpu greater than or equal to MESON_CPU_MAJOR_ID_GXBB,
	* the clock switch from the clock tree register, otherwise from
	* the adc module register.
	*/
	if (get_cpu_family_id() >= MESON_CPU_MAJOR_ID_GXBB) {
	/bit[0-7]: set clk div; bit[9-10]: select clk source/
	aml_set_reg32_bits(P_AO_SAR_CLK, 0, 9, 2);
	aml_set_reg32_bits(P_AO_SAR_CLK, (val & 0xff), 0, 8);
	} else {
	/bit10-bit15: set clk div/
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3, (val & 0x3f), 10, 6);
	}
	}

	void saradc_enable(void)
	{
	if (get_cpu_family_id() <= MESON_CPU_MAJOR_ID_GXTVBB)
	adc_type = 0;
	else
	adc_type = 1;

	aml_write_reg32(P_AO_SAR_ADC_REG0, 0x84004040);
	aml_write_reg32(P_AO_SAR_ADC_CHAN_LIST, 0);
	/* REG2: all chanel set to 8-samples & median averaging mode */
	aml_write_reg32(P_AO_SAR_ADC_AVG_CNTL, 0);
	aml_write_reg32(P_AO_SAR_ADC_REG3, 0x9388000a);

	if (adc_type)
	aml_set_reg32_bits(P_AO_SAR_ADC_REG3,0x1,27,1);

	saradc_clock_set(20);

	aml_write_reg32(P_AO_SAR_ADC_DELAY, 0x10a000a);
	aml_write_reg32(P_AO_SAR_ADC_AUX_SW, 0x3eb1a0c);
	aml_write_reg32(P_AO_SAR_ADC_CHAN_10_SW, 0x8c000c);
	aml_write_reg32(P_AO_SAR_ADC_DETECT_IDLE_SW, 0xc000c);

	saradc_power_control(1);
	}

	int get_adc_sample_gxbb(int ch)
	{
	int value=0;
	int count=0;
	int sum=0;

	aml_write_reg32(P_AO_SAR_ADC_CHAN_LIST, ch);
	aml_write_reg32(P_AO_SAR_ADC_DETECT_IDLE_SW, (0xc000c \| (ch<<23) \| (ch<<7)));
	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 0, 1);
	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 2, 1);

	count = 0;
	do {
	_udelay(10);
	if (!(aml_read_reg32(P_AO_SAR_ADC_REG0) & 0x70000000))
	break;
	else if (++count > 10000) {
	uart_puts("busy error");
	uart_puts("\n");
	value = -1;
	goto end;
	}
	} while (1);

	count = 0;
	sum = 0;
	while (aml_get_reg32_bits(P_AO_SAR_ADC_REG0, 21, 5) && (count < 32)) {
	value = aml_read_reg32(P_AO_SAR_ADC_FIFO_RD);
	if (((value >> 12) & 0x07) == ch) {
	value &= 0xffc;
	value >>= 2;
	sum += value;
	count++;
	} else {
	uart_puts("channel error");
	uart_puts("\n");
	}
	}
	if (!count) {
	value = -1;
	goto end;
	}
	value = sum / count;

	end:
	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 1, 14, 1);
	aml_set_reg32_bits(P_AO_SAR_ADC_REG0, 0, 0, 1);

	return value;
	}

	int saradc_disable(void)
	{
	saradc_power_control(0);
	return 0;
	}

	int check_adc_key_resume(void)
	{
	int value;
	int min;
	int max;

	/the sampling value of adc: 0-1023/
	min = CONFIG_ADC_POWER_KEY_VAL - 40;
	if (min < 0)
	min = 0;
	max = CONFIG_ADC_POWER_KEY_VAL + 40;
	if (max > 1023)
	max = 1023;

	value = get_adc_sample_gxbb(CONFIG_ADC_POWER_KEY_CHAN);
	if ((value >= min) && (value <= max))
	return 1;
	else
	return 0;
	}