drivers/staging/sm750fb/ddk750_chip.c - nest-learning-thermostat/6.0/linux-imx-4.9.88 - Git at Google

 #include <linux/kernel.h>
 #include <linux/sizes.h>

 #include "ddk750_help.h"
 #include "ddk750_reg.h"
 #include "ddk750_chip.h"
 #include "ddk750_power.h"

 #define MHz(x) ((x) * 1000000)

 logical_chip_type_t sm750_get_chip_type(void)
 {
 	unsigned short physicalID;
 	char physicalRev;
 	logical_chip_type_t chip;

 	physicalID = devId750; /* either 0x718 or 0x750 */
 	physicalRev = revId750;

 	if (physicalID == 0x718)
 		chip = SM718;
 	else if (physicalID == 0x750) {
 		chip = SM750;
 		/* SM750 and SM750LE are different in their revision ID only. */
 		if (physicalRev == SM750LE_REVISION_ID)
 			chip = SM750LE;
 	} else
 		chip = SM_UNKNOWN;

 	return chip;
 }

 static unsigned int get_mxclk_freq(void)
 {
 	unsigned int pll_reg;
 	unsigned int M, N, OD, POD;

 	if (sm750_get_chip_type() == SM750LE)
 		return MHz(130);

 	pll_reg = PEEK32(MXCLK_PLL_CTRL);
 	M = (pll_reg & PLL_CTRL_M_MASK) >> PLL_CTRL_M_SHIFT;
 	N = (pll_reg & PLL_CTRL_N_MASK) >> PLL_CTRL_M_SHIFT;
 	OD = (pll_reg & PLL_CTRL_OD_MASK) >> PLL_CTRL_OD_SHIFT;
 	POD = (pll_reg & PLL_CTRL_POD_MASK) >> PLL_CTRL_POD_SHIFT;

 	return DEFAULT_INPUT_CLOCK * M / N / (1 << OD) / (1 << POD);
 }

 /*
  * This function set up the main chip clock.
  *
  * Input: Frequency to be set.
  */
 static void setChipClock(unsigned int frequency)
 {
 	pll_value_t pll;
 	unsigned int ulActualMxClk;

 	/* Cheok_0509: For SM750LE, the chip clock is fixed. Nothing to set. */
 	if (sm750_get_chip_type() == SM750LE)
 		return;

 	if (frequency) {
 		/*
 		* Set up PLL, a structure to hold the value to be set in clocks.
 		*/
 		pll.inputFreq = DEFAULT_INPUT_CLOCK; /* Defined in CLOCK.H */
 		pll.clockType = MXCLK_PLL;

 		/*
 		* Call calcPllValue() to fill the other fields of PLL structure.
 		* Sometime, the chip cannot set up the exact clock
 		* required by the User.
 		* Return value of calcPllValue gives the actual possible clock.
 		*/
 		ulActualMxClk = calcPllValue(frequency, &pll);

 		/* Master Clock Control: MXCLK_PLL */
 		POKE32(MXCLK_PLL_CTRL, formatPllReg(&pll));
 	}
 }

 static void setMemoryClock(unsigned int frequency)
 {
 	unsigned int reg, divisor;

 	/* Cheok_0509: For SM750LE, the memory clock is fixed.
 	 * Nothing to set.
 	 */
 	if (sm750_get_chip_type() == SM750LE)
 		return;

 	if (frequency) {
 		/*
 		 * Set the frequency to the maximum frequency
 		 * that the DDR Memory can take which is 336MHz.
 		 */
 		if (frequency > MHz(336))
 			frequency = MHz(336);

 		/* Calculate the divisor */
 		divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency);

 		/* Set the corresponding divisor in the register. */
 		reg = PEEK32(CURRENT_GATE) & ~CURRENT_GATE_M2XCLK_MASK;
 		switch (divisor) {
 		default:
 		case 1:
 			reg |= CURRENT_GATE_M2XCLK_DIV_1;
 			break;
 		case 2:
 			reg |= CURRENT_GATE_M2XCLK_DIV_2;
 			break;
 		case 3:
 			reg |= CURRENT_GATE_M2XCLK_DIV_3;
 			break;
 		case 4:
 			reg |= CURRENT_GATE_M2XCLK_DIV_4;
 			break;
 		}

 		setCurrentGate(reg);
 	}
 }

 /*
  * This function set up the master clock (MCLK).
  *
  * Input: Frequency to be set.
  *
  * NOTE:
  *      The maximum frequency the engine can run is 168MHz.
  */
 static void setMasterClock(unsigned int frequency)
 {
 	unsigned int reg, divisor;

 	/* Cheok_0509: For SM750LE, the memory clock is fixed.
 	 * Nothing to set.
 	 */
 	if (sm750_get_chip_type() == SM750LE)
 		return;

 	if (frequency) {
 		/* Set the frequency to the maximum frequency
 		 * that the SM750 engine can run, which is about 190 MHz.
 		 */
 		if (frequency > MHz(190))
 			frequency = MHz(190);

 		/* Calculate the divisor */
 		divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency);

 		/* Set the corresponding divisor in the register. */
 		reg = PEEK32(CURRENT_GATE) & ~CURRENT_GATE_MCLK_MASK;
 		switch (divisor) {
 		default:
 		case 3:
 			reg |= CURRENT_GATE_MCLK_DIV_3;
 			break;
 		case 4:
 			reg |= CURRENT_GATE_MCLK_DIV_4;
 			break;
 		case 6:
 			reg |= CURRENT_GATE_MCLK_DIV_6;
 			break;
 		case 8:
 			reg |= CURRENT_GATE_MCLK_DIV_8;
 			break;
 		}

 		setCurrentGate(reg);
 		}
 }

 unsigned int ddk750_getVMSize(void)
 {
 	unsigned int reg;
 	unsigned int data;

 	/* sm750le only use 64 mb memory*/
 	if (sm750_get_chip_type() == SM750LE)
 		return SZ_64M;

 	/* for 750,always use power mode0*/
 	reg = PEEK32(MODE0_GATE);
 	reg |= MODE0_GATE_GPIO;
 	POKE32(MODE0_GATE, reg);

 	/* get frame buffer size from GPIO */
 	reg = PEEK32(MISC_CTRL) & MISC_CTRL_LOCALMEM_SIZE_MASK;
 	switch (reg) {
 	case MISC_CTRL_LOCALMEM_SIZE_8M:
 		data = SZ_8M;  break; /* 8  Mega byte */
 	case MISC_CTRL_LOCALMEM_SIZE_16M:
 		data = SZ_16M; break; /* 16 Mega byte */
 	case MISC_CTRL_LOCALMEM_SIZE_32M:
 		data = SZ_32M; break; /* 32 Mega byte */
 	case MISC_CTRL_LOCALMEM_SIZE_64M:
 		data = SZ_64M; break; /* 64 Mega byte */
 	default:
 		data = 0;
 		break;
 	}
 	return data;
 }

 int ddk750_initHw(initchip_param_t *pInitParam)
 {
 	unsigned int reg;

 	if (pInitParam->powerMode != 0)
 		pInitParam->powerMode = 0;
 	setPowerMode(pInitParam->powerMode);

 	/* Enable display power gate & LOCALMEM power gate*/
 	reg = PEEK32(CURRENT_GATE);
 	reg |= (CURRENT_GATE_DISPLAY | CURRENT_GATE_LOCALMEM);
 	setCurrentGate(reg);

 	if (sm750_get_chip_type() != SM750LE) {
 		/*	set panel pll and graphic mode via mmio_88 */
 		reg = PEEK32(VGA_CONFIGURATION);
 		reg |= (VGA_CONFIGURATION_PLL | VGA_CONFIGURATION_MODE);
 		POKE32(VGA_CONFIGURATION, reg);
 	} else {
 #if defined(__i386__) || defined(__x86_64__)
 		/* set graphic mode via IO method */
 		outb_p(0x88, 0x3d4);
 		outb_p(0x06, 0x3d5);
 #endif
 	}

 	/* Set the Main Chip Clock */
 	setChipClock(MHz((unsigned int)pInitParam->chipClock));

 	/* Set up memory clock. */
 	setMemoryClock(MHz(pInitParam->memClock));

 	/* Set up master clock */
 	setMasterClock(MHz(pInitParam->masterClock));


 	/* Reset the memory controller.
 	 * If the memory controller is not reset in SM750,
 	 * the system might hang when sw accesses the memory.
 	 * The memory should be resetted after changing the MXCLK.
 	 */
 	if (pInitParam->resetMemory == 1) {
 		reg = PEEK32(MISC_CTRL);
 		reg &= ~MISC_CTRL_LOCALMEM_RESET;
 		POKE32(MISC_CTRL, reg);

 		reg |= MISC_CTRL_LOCALMEM_RESET;
 		POKE32(MISC_CTRL, reg);
 	}

 	if (pInitParam->setAllEngOff == 1) {
 		enable2DEngine(0);

 		/* Disable Overlay, if a former application left it on */
 		reg = PEEK32(VIDEO_DISPLAY_CTRL);
 		reg &= ~DISPLAY_CTRL_PLANE;
 		POKE32(VIDEO_DISPLAY_CTRL, reg);

 		/* Disable video alpha, if a former application left it on */
 		reg = PEEK32(VIDEO_ALPHA_DISPLAY_CTRL);
 		reg &= ~DISPLAY_CTRL_PLANE;
 		POKE32(VIDEO_ALPHA_DISPLAY_CTRL, reg);

 		/* Disable alpha plane, if a former application left it on */
 		reg = PEEK32(ALPHA_DISPLAY_CTRL);
 		reg &= ~DISPLAY_CTRL_PLANE;
 		POKE32(ALPHA_DISPLAY_CTRL, reg);

 		/* Disable DMA Channel, if a former application left it on */
 		reg = PEEK32(DMA_ABORT_INTERRUPT);
 		reg |= DMA_ABORT_INTERRUPT_ABORT_1;
 		POKE32(DMA_ABORT_INTERRUPT, reg);

 		/* Disable DMA Power, if a former application left it on */
 		enableDMA(0);
 	}

 	/* We can add more initialization as needed. */

 	return 0;
 }

 /*
  * monk liu @ 4/6/2011:
  *	re-write the calculatePLL function of ddk750.
  *	the original version function does not use
  *	some mathematics tricks and shortcut
  *	when it doing the calculation of the best N,M,D combination
  *	I think this version gives a little upgrade in speed
  *
  * 750 pll clock formular:
  * Request Clock = (Input Clock * M )/(N * X)
  *
  * Input Clock = 14318181 hz
  * X = 2 power D
  * D ={0,1,2,3,4,5,6}
  * M = {1,...,255}
  * N = {2,...,15}
  */
 unsigned int calcPllValue(unsigned int request_orig, pll_value_t *pll)
 {
 	/* as sm750 register definition,
 	 * N located in 2,15 and M located in 1,255
 	 */
 	int N, M, X, d;
 	int mini_diff;
 	unsigned int RN, quo, rem, fl_quo;
 	unsigned int input, request;
 	unsigned int tmpClock, ret;
 	const int max_OD = 3;
 	int max_d = 6;

 	if (sm750_get_chip_type() == SM750LE) {
 		/* SM750LE don't have
 		 * programmable PLL and M/N values to work on.
 		 * Just return the requested clock.
 		 */
 		return request_orig;
 	}

 	ret = 0;
 	mini_diff = ~0;
 	request = request_orig / 1000;
 	input = pll->inputFreq / 1000;

 	/* for MXCLK register,
 	 * no POD provided, so need be treated differently
 	 */
 	if (pll->clockType == MXCLK_PLL)
 		max_d = 3;

 	for (N = 15; N > 1; N--) {
 		/* RN will not exceed maximum long
 		 * if @request <= 285 MHZ (for 32bit cpu)
 		 */
 		RN = N * request;
 		quo = RN / input;
 		rem = RN % input;/* rem always small than 14318181 */
 		fl_quo = (rem * 10000 / input);

 		for (d = max_d; d >= 0; d--) {
 			X = BIT(d);
 			M = quo * X;
 			M += fl_quo * X / 10000;
 			/* round step */
 			M += (fl_quo * X % 10000) > 5000 ? 1 : 0;
 			if (M < 256 && M > 0) {
 				unsigned int diff;

 				tmpClock = pll->inputFreq * M / N / X;
 				diff = abs(tmpClock - request_orig);
 				if (diff < mini_diff) {
 					pll->M = M;
 					pll->N = N;
 					pll->POD = 0;
 					if (d > max_OD)
 						pll->POD = d - max_OD;
 					pll->OD = d - pll->POD;
 					mini_diff = diff;
 					ret = tmpClock;
 				}
 			}
 		}
 	}
 	return ret;
 }

 unsigned int formatPllReg(pll_value_t *pPLL)
 {
 #ifndef VALIDATION_CHIP
 	unsigned int POD = pPLL->POD;
 #endif
 	unsigned int OD = pPLL->OD;
 	unsigned int M = pPLL->M;
 	unsigned int N = pPLL->N;
 	unsigned int reg = 0;

 	/*
 	 * Note that all PLL's have the same format. Here, we just use
 	 * Panel PLL parameter to work out the bit fields in the
 	 * register. On returning a 32 bit number, the value can be
 	 * applied to any PLL in the calling function.
 	 */
 	reg = PLL_CTRL_POWER |
 #ifndef VALIDATION_CHIP
 		((POD << PLL_CTRL_POD_SHIFT) & PLL_CTRL_POD_MASK) |
 #endif
 		((OD << PLL_CTRL_OD_SHIFT) & PLL_CTRL_OD_MASK) |
 		((N << PLL_CTRL_N_SHIFT) & PLL_CTRL_N_MASK) |
 		((M << PLL_CTRL_M_SHIFT) & PLL_CTRL_M_MASK);

 	return reg;
 }
	#include <linux/kernel.h>
	#include <linux/sizes.h>

	#include "ddk750_help.h"
	#include "ddk750_reg.h"
	#include "ddk750_chip.h"
	#include "ddk750_power.h"

	#define MHz(x) ((x) * 1000000)

	logical_chip_type_t sm750_get_chip_type(void)
	{
	unsigned short physicalID;
	char physicalRev;
	logical_chip_type_t chip;

	physicalID = devId750; /* either 0x718 or 0x750 */
	physicalRev = revId750;

	if (physicalID == 0x718)
	chip = SM718;
	else if (physicalID == 0x750) {
	chip = SM750;
	/* SM750 and SM750LE are different in their revision ID only. */
	if (physicalRev == SM750LE_REVISION_ID)
	chip = SM750LE;
	} else
	chip = SM_UNKNOWN;

	return chip;
	}

	static unsigned int get_mxclk_freq(void)
	{
	unsigned int pll_reg;
	unsigned int M, N, OD, POD;

	if (sm750_get_chip_type() == SM750LE)
	return MHz(130);

	pll_reg = PEEK32(MXCLK_PLL_CTRL);
	M = (pll_reg & PLL_CTRL_M_MASK) >> PLL_CTRL_M_SHIFT;
	N = (pll_reg & PLL_CTRL_N_MASK) >> PLL_CTRL_M_SHIFT;
	OD = (pll_reg & PLL_CTRL_OD_MASK) >> PLL_CTRL_OD_SHIFT;
	POD = (pll_reg & PLL_CTRL_POD_MASK) >> PLL_CTRL_POD_SHIFT;

	return DEFAULT_INPUT_CLOCK * M / N / (1 << OD) / (1 << POD);
	}

	/*
	* This function set up the main chip clock.
	*
	* Input: Frequency to be set.
	*/
	static void setChipClock(unsigned int frequency)
	{
	pll_value_t pll;
	unsigned int ulActualMxClk;

	/* Cheok_0509: For SM750LE, the chip clock is fixed. Nothing to set. */
	if (sm750_get_chip_type() == SM750LE)
	return;

	if (frequency) {
	/*
	* Set up PLL, a structure to hold the value to be set in clocks.
	*/
	pll.inputFreq = DEFAULT_INPUT_CLOCK; /* Defined in CLOCK.H */
	pll.clockType = MXCLK_PLL;

	/*
	* Call calcPllValue() to fill the other fields of PLL structure.
	* Sometime, the chip cannot set up the exact clock
	* required by the User.
	* Return value of calcPllValue gives the actual possible clock.
	*/
	ulActualMxClk = calcPllValue(frequency, &pll);

	/* Master Clock Control: MXCLK_PLL */
	POKE32(MXCLK_PLL_CTRL, formatPllReg(&pll));
	}
	}

	static void setMemoryClock(unsigned int frequency)
	{
	unsigned int reg, divisor;

	/* Cheok_0509: For SM750LE, the memory clock is fixed.
	* Nothing to set.
	*/
	if (sm750_get_chip_type() == SM750LE)
	return;

	if (frequency) {
	/*
	* Set the frequency to the maximum frequency
	* that the DDR Memory can take which is 336MHz.
	*/
	if (frequency > MHz(336))
	frequency = MHz(336);

	/* Calculate the divisor */
	divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency);

	/* Set the corresponding divisor in the register. */
	reg = PEEK32(CURRENT_GATE) & ~CURRENT_GATE_M2XCLK_MASK;
	switch (divisor) {
	default:
	case 1:
	reg \|= CURRENT_GATE_M2XCLK_DIV_1;
	break;
	case 2:
	reg \|= CURRENT_GATE_M2XCLK_DIV_2;
	break;
	case 3:
	reg \|= CURRENT_GATE_M2XCLK_DIV_3;
	break;
	case 4:
	reg \|= CURRENT_GATE_M2XCLK_DIV_4;
	break;
	}

	setCurrentGate(reg);
	}
	}

	/*
	* This function set up the master clock (MCLK).
	*
	* Input: Frequency to be set.
	*
	* NOTE:
	* The maximum frequency the engine can run is 168MHz.
	*/
	static void setMasterClock(unsigned int frequency)
	{
	unsigned int reg, divisor;

	/* Cheok_0509: For SM750LE, the memory clock is fixed.
	* Nothing to set.
	*/
	if (sm750_get_chip_type() == SM750LE)
	return;

	if (frequency) {
	/* Set the frequency to the maximum frequency
	* that the SM750 engine can run, which is about 190 MHz.
	*/
	if (frequency > MHz(190))
	frequency = MHz(190);

	/* Calculate the divisor */
	divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency);

	/* Set the corresponding divisor in the register. */
	reg = PEEK32(CURRENT_GATE) & ~CURRENT_GATE_MCLK_MASK;
	switch (divisor) {
	default:
	case 3:
	reg \|= CURRENT_GATE_MCLK_DIV_3;
	break;
	case 4:
	reg \|= CURRENT_GATE_MCLK_DIV_4;
	break;
	case 6:
	reg \|= CURRENT_GATE_MCLK_DIV_6;
	break;
	case 8:
	reg \|= CURRENT_GATE_MCLK_DIV_8;
	break;
	}

	setCurrentGate(reg);
	}
	}

	unsigned int ddk750_getVMSize(void)
	{
	unsigned int reg;
	unsigned int data;

	/* sm750le only use 64 mb memory*/
	if (sm750_get_chip_type() == SM750LE)
	return SZ_64M;

	/* for 750,always use power mode0*/
	reg = PEEK32(MODE0_GATE);
	reg \|= MODE0_GATE_GPIO;
	POKE32(MODE0_GATE, reg);

	/* get frame buffer size from GPIO */
	reg = PEEK32(MISC_CTRL) & MISC_CTRL_LOCALMEM_SIZE_MASK;
	switch (reg) {
	case MISC_CTRL_LOCALMEM_SIZE_8M:
	data = SZ_8M; break; /* 8 Mega byte */
	case MISC_CTRL_LOCALMEM_SIZE_16M:
	data = SZ_16M; break; /* 16 Mega byte */
	case MISC_CTRL_LOCALMEM_SIZE_32M:
	data = SZ_32M; break; /* 32 Mega byte */
	case MISC_CTRL_LOCALMEM_SIZE_64M:
	data = SZ_64M; break; /* 64 Mega byte */
	default:
	data = 0;
	break;
	}
	return data;
	}

	int ddk750_initHw(initchip_param_t *pInitParam)
	{
	unsigned int reg;

	if (pInitParam->powerMode != 0)
	pInitParam->powerMode = 0;
	setPowerMode(pInitParam->powerMode);

	/* Enable display power gate & LOCALMEM power gate*/
	reg = PEEK32(CURRENT_GATE);
	reg \|= (CURRENT_GATE_DISPLAY \| CURRENT_GATE_LOCALMEM);
	setCurrentGate(reg);

	if (sm750_get_chip_type() != SM750LE) {
	/* set panel pll and graphic mode via mmio_88 */
	reg = PEEK32(VGA_CONFIGURATION);
	reg \|= (VGA_CONFIGURATION_PLL \| VGA_CONFIGURATION_MODE);
	POKE32(VGA_CONFIGURATION, reg);
	} else {
	#if defined(__i386__) \|\| defined(__x86_64__)
	/* set graphic mode via IO method */
	outb_p(0x88, 0x3d4);
	outb_p(0x06, 0x3d5);
	#endif
	}

	/* Set the Main Chip Clock */
	setChipClock(MHz((unsigned int)pInitParam->chipClock));

	/* Set up memory clock. */
	setMemoryClock(MHz(pInitParam->memClock));

	/* Set up master clock */
	setMasterClock(MHz(pInitParam->masterClock));


	/* Reset the memory controller.
	* If the memory controller is not reset in SM750,
	* the system might hang when sw accesses the memory.
	* The memory should be resetted after changing the MXCLK.
	*/
	if (pInitParam->resetMemory == 1) {
	reg = PEEK32(MISC_CTRL);
	reg &= ~MISC_CTRL_LOCALMEM_RESET;
	POKE32(MISC_CTRL, reg);

	reg \|= MISC_CTRL_LOCALMEM_RESET;
	POKE32(MISC_CTRL, reg);
	}

	if (pInitParam->setAllEngOff == 1) {
	enable2DEngine(0);

	/* Disable Overlay, if a former application left it on */
	reg = PEEK32(VIDEO_DISPLAY_CTRL);
	reg &= ~DISPLAY_CTRL_PLANE;
	POKE32(VIDEO_DISPLAY_CTRL, reg);

	/* Disable video alpha, if a former application left it on */
	reg = PEEK32(VIDEO_ALPHA_DISPLAY_CTRL);
	reg &= ~DISPLAY_CTRL_PLANE;
	POKE32(VIDEO_ALPHA_DISPLAY_CTRL, reg);

	/* Disable alpha plane, if a former application left it on */
	reg = PEEK32(ALPHA_DISPLAY_CTRL);
	reg &= ~DISPLAY_CTRL_PLANE;
	POKE32(ALPHA_DISPLAY_CTRL, reg);

	/* Disable DMA Channel, if a former application left it on */
	reg = PEEK32(DMA_ABORT_INTERRUPT);
	reg \|= DMA_ABORT_INTERRUPT_ABORT_1;
	POKE32(DMA_ABORT_INTERRUPT, reg);

	/* Disable DMA Power, if a former application left it on */
	enableDMA(0);
	}

	/* We can add more initialization as needed. */

	return 0;
	}

	/*
	* monk liu @ 4/6/2011:
	* re-write the calculatePLL function of ddk750.
	* the original version function does not use
	* some mathematics tricks and shortcut
	* when it doing the calculation of the best N,M,D combination
	* I think this version gives a little upgrade in speed
	*
	* 750 pll clock formular:
	* Request Clock = (Input Clock * M )/(N * X)
	*
	* Input Clock = 14318181 hz
	* X = 2 power D
	* D ={0,1,2,3,4,5,6}
	* M = {1,...,255}
	* N = {2,...,15}
	*/
	unsigned int calcPllValue(unsigned int request_orig, pll_value_t *pll)
	{
	/* as sm750 register definition,
	* N located in 2,15 and M located in 1,255
	*/
	int N, M, X, d;
	int mini_diff;
	unsigned int RN, quo, rem, fl_quo;
	unsigned int input, request;
	unsigned int tmpClock, ret;
	const int max_OD = 3;
	int max_d = 6;

	if (sm750_get_chip_type() == SM750LE) {
	/* SM750LE don't have
	* programmable PLL and M/N values to work on.
	* Just return the requested clock.
	*/
	return request_orig;
	}

	ret = 0;
	mini_diff = ~0;
	request = request_orig / 1000;
	input = pll->inputFreq / 1000;

	/* for MXCLK register,
	* no POD provided, so need be treated differently
	*/
	if (pll->clockType == MXCLK_PLL)
	max_d = 3;

	for (N = 15; N > 1; N--) {
	/* RN will not exceed maximum long
	* if @request <= 285 MHZ (for 32bit cpu)
	*/
	RN = N * request;
	quo = RN / input;
	rem = RN % input;/* rem always small than 14318181 */
	fl_quo = (rem * 10000 / input);

	for (d = max_d; d >= 0; d--) {
	X = BIT(d);
	M = quo * X;
	M += fl_quo * X / 10000;
	/* round step */
	M += (fl_quo * X % 10000) > 5000 ? 1 : 0;
	if (M < 256 && M > 0) {
	unsigned int diff;

	tmpClock = pll->inputFreq * M / N / X;
	diff = abs(tmpClock - request_orig);
	if (diff < mini_diff) {
	pll->M = M;
	pll->N = N;
	pll->POD = 0;
	if (d > max_OD)
	pll->POD = d - max_OD;
	pll->OD = d - pll->POD;
	mini_diff = diff;
	ret = tmpClock;
	}
	}
	}
	}
	return ret;
	}

	unsigned int formatPllReg(pll_value_t *pPLL)
	{
	#ifndef VALIDATION_CHIP
	unsigned int POD = pPLL->POD;
	#endif
	unsigned int OD = pPLL->OD;
	unsigned int M = pPLL->M;
	unsigned int N = pPLL->N;
	unsigned int reg = 0;

	/*
	* Note that all PLL's have the same format. Here, we just use
	* Panel PLL parameter to work out the bit fields in the
	* register. On returning a 32 bit number, the value can be
	* applied to any PLL in the calling function.
	*/
	reg = PLL_CTRL_POWER \|
	#ifndef VALIDATION_CHIP
	((POD << PLL_CTRL_POD_SHIFT) & PLL_CTRL_POD_MASK) \|
	#endif
	((OD << PLL_CTRL_OD_SHIFT) & PLL_CTRL_OD_MASK) \|
	((N << PLL_CTRL_N_SHIFT) & PLL_CTRL_N_MASK) \|
	((M << PLL_CTRL_M_SHIFT) & PLL_CTRL_M_MASK);

	return reg;
	}