arch/arm/cpu/armv8/gxtvbb/pll.c - u-boot - Git at Google

 /*
  * rev history:
  * 2017.04.06 structure done
  *
  *
  *
  *
  */

 #include <common.h>
 #include <command.h>
 #include <asm/cpu_id.h>
 #include <malloc.h>
 #include <asm/io.h>
 #include <asm/arch/clock.h>
 #include <asm/arch/secure_apb.h>
 #include <asm/arch/timer.h>
 #include <asm/arch/pll.h>

 #define STR_PLL_TEST_ALL	"all"
 #define STR_PLL_TEST_SYS	"sys"
 #define STR_PLL_TEST_FIX	"fix"
 #define STR_PLL_TEST_DDR	"ddr"
 #define STR_PLL_TEST_HDMI	"hdmi"
 #define STR_PLL_TEST_GP0	"gp0"

 #define PLL_LOCK_CHECK_MAX		20

 #define RET_PLL_LOCK_FAIL		0x1000
 #define RET_CLK_NOT_MATCH		0x1
 #define SYS_CLK_DIV16_GATE		(1<<1)
 #define SYS_PLL_TEST_DIV		4	/* div16 */
 #define HDMI_PLL_DIV_CNTL		(1<<18)
 #define HDMI_PLL_DIV_GATE		(1<<19)
 #define HDMI_PLL_TEST_DIV		4	/* div2/2/4 */
 #define GP0_PLL_TEST_DIV		0	/* div1 */

 #define Wr(addr, data) writel(data, addr)
 #define Rd(addr) readl(addr)

 static int sys_pll_init(sys_pll_set_t * sys_pll_set);
 static int sys_pll_test(sys_pll_set_t * sys_pll_set);
 static int sys_pll_test_all(sys_pll_cfg_t * sys_pll_cfg);
 static int fix_pll_test(void);
 static int ddr_pll_test(void);
 static int hdmi_pll_init(hdmi_pll_set_t * hdmi_pll_set);
 static int hdmi_pll_test(hdmi_pll_set_t * hdmi_pll_set);
 static int hdmi_pll_test_all(hdmi_pll_cfg_t * hdmi_pll_cfg);
 static int gp0_pll_test(gp0_pll_set_t * gp0_pll);
 static int gp0_pll_test_all(void);

 #if 0
 static unsigned int pll_range[PLL_ENUM][2] = {
 	{101, 202}, //sys pll range
 	{303, 404}, //fix pll range
 	{505, 606}, //ddr pll range
 	{707, 808}, //hdmi pll range
 	{909, 999}, // pll range
 };

 static char pll_range_ind[PLL_ENUM][10] = {
 	"sys",
 	"fix",
 	"ddr",
 	"hdmi",
 	"gp0",
 };
 #endif

 static void update_bits(size_t reg, size_t mask, unsigned int val)
 {
 	unsigned int tmp, orig;
 	orig = readl(reg);
 	tmp = orig & ~mask;
 	tmp |= val & mask;
 	writel(tmp, reg);
 }

 hdmi_pll_cfg_t hdmi_pll_cfg = {
 	.hdmi_pll[0] = {
 		.pll_clk   = 5940, /* MHz */
 		.pll_cntl  = 0x5800027b,
 		.pll_cntl2 = 0x000E4300, /* cntl2[23:20] use 5 = div4 */
 		.pll_cntl3 = 0x12dc5081,
 		.pll_cntl4 = 0x801da72c,
 		.pll_cntl5 = 0x71486980,
 		.pll_cntl6 = 0x00002e55
 	},
 	.hdmi_pll[1] = {
 		.pll_clk   = 4320,
 		.pll_cntl  = 0x5800025a,
 		.pll_cntl2 = 0x000E0000,
 		.pll_cntl3 = 0x0d5c5091,
 		.pll_cntl4 = 0x801da72c,
 		.pll_cntl5 = 0x71486980,
 		.pll_cntl6 = 0x00002e55
 	},
 	.hdmi_pll[2] = {
 		.pll_clk   = 3712,
 		.pll_cntl  = 0x5800024d,
 		.pll_cntl2 = 0x000E4160,
 		.pll_cntl3 = 0x0d5c5091,
 		.pll_cntl4 = 0x801da72c,
 		.pll_cntl5 = 0x71486980,
 		.pll_cntl6 = 0x00002e55
 	},
 #if 0
 	.hdmi_pll[3] = {
 		.pll_clk   = 2970,
 		.pll_cntl  = 0x400002b4,
 		.pll_cntl2 = 0x000E4380,
 		.pll_cntl3 = 0x0d5c5091,
 		.pll_cntl4 = 0x801da72c,
 		.pll_cntl5 = 0x71486980,
 		.pll_cntl6 = 0x00002e55
 	},
 #endif
 };

 sys_pll_cfg_t sys_pll_cfg = {
 	/* 960M*/
 #if 0
 	.sys_pll[0] = {
 		.cpu_clk   = 960,
 		.pll_cntl  = 0x60000228,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1056M*/
 	.sys_pll[1] = {
 		.cpu_clk   = 1056,
 		.pll_cntl  = 0x6000022c,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 #endif
 	/*1152M*/
 	.sys_pll[0] = {
 		.cpu_clk   = 1152,
 		.pll_cntl  = 0x60000230,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1248M*/
 	.sys_pll[1] = {
 		.cpu_clk   = 1248,
 		.pll_cntl  = 0x60000234,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1344M*/
 	.sys_pll[2] = {
 		.cpu_clk   = 1344,
 		.pll_cntl  = 0x60000238,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1440M*/
 	.sys_pll[3] = {
 		.cpu_clk   = 1440,
 		.pll_cntl  = 0x6000023c,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1536M*/
 	.sys_pll[4] = {
 		.cpu_clk   = 1536,
 		.pll_cntl  = 0x60000240,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 	/*1632M*/
 	.sys_pll[5] = {
 		.cpu_clk   = 1632,
 		.pll_cntl  = 0x60000244,
 		//.pll_cntl1 = 0xc4258100,
 		.pll_cntl2 = 0x5ac80000,
 		.pll_cntl3 = 0x8e452015,
 		.pll_cntl4 = 0x0401d40c,
 		.pll_cntl5 = 0x00000870
 	},
 };

 #define GPLL0_RATE(_rate, _m, _n, _od) \
 {							\
 		.rate	=	(_rate),				\
 		.m		=	(_m),					\
 		.n		=	(_n),					\
 		.od		=	(_od),					\
 }

 static gpll_rate_table_t gpll0_tbl[] = {
 	GPLL0_RATE(504, 42, 1, 1),
 	GPLL0_RATE(516, 43, 1, 1),
 	GPLL0_RATE(528, 44, 1, 1),
 	GPLL0_RATE(540, 45, 1, 1),
 	GPLL0_RATE(552, 46, 1, 1),
 	GPLL0_RATE(564, 47, 1, 1),
 	GPLL0_RATE(576, 48, 1, 1),
 	GPLL0_RATE(588, 49, 1, 1),
 	GPLL0_RATE(600, 50, 1, 1),
 	GPLL0_RATE(612, 51, 1, 1),
 	GPLL0_RATE(624, 52, 1, 1),
 	GPLL0_RATE(636, 53, 1, 1),
 	GPLL0_RATE(648, 54, 1, 1),
 	GPLL0_RATE(660, 55, 1, 1),
 	GPLL0_RATE(672, 56, 1, 1),
 	GPLL0_RATE(684, 57, 1, 1),
 	GPLL0_RATE(696, 58, 1, 1),
 	GPLL0_RATE(708, 59, 1, 1),
 	GPLL0_RATE(720, 60, 1, 1),
 	GPLL0_RATE(732, 61, 1, 1),
 };

 static void pll_report(unsigned int flag, char * name) {
 	if (flag)
 		printf("%s pll test failed!\n", name);
 	else
 		printf("%s pll test pass!\n", name);
 	return;
 }

 static int clk_around(unsigned int clk, unsigned int cmp) {
 	if (((cmp-1) <= clk) && (clk <= (cmp+1)))
 		return 1;
 	else
 		return 0;
 }

 static void clocks_set_sys_cpu_clk(uint32_t freq, uint32_t pclk_ratio, uint32_t aclkm_ratio, uint32_t atclk_ratio )
 {
 	uint32_t	control = 0;
 	uint32_t	dyn_pre_mux = 0;
 	uint32_t	dyn_post_mux = 0;
 	uint32_t	dyn_div = 0;

 	// Make sure not busy from last setting and we currently match the last setting
 	do {
 		control = Rd(HHI_SYS_CPU_CLK_CNTL);
 	} while( (control & (1 << 28)) );

 	control = control | (1 << 26);				// Enable

 	// Switching to System PLL...just change the final mux
 	if ( freq == 1 ) {
 		// wire			cntl_final_mux_sel		= control[11];
 		control = control | (1 << 11);
 	} else {
 		switch ( freq ) {
 			case	0:		// If Crystal
 							dyn_pre_mux		= 0;
 							dyn_post_mux	= 0;
 							dyn_div			= 0;	// divide by 1
 							break;
 			case	1000:		// If Crystal
 							dyn_pre_mux = 1;
 							dyn_post_mux = 0;
 							dyn_div = 0;
 							break;
 		}
 		if ( control & (1 << 10) ) { 	// if using Dyn mux1, set dyn mux 0
 			// Toggle bit[10] indicating a dynamic mux change
 			control = (control & ~((1 << 10) | (0x3f << 4)	| (1 << 2)	| (0x3 << 0)))
 					| ((0 << 10)
 					| (dyn_div << 4)
 					| (dyn_post_mux << 2)
 					| (dyn_pre_mux << 0));
 		} else {
 			// Toggle bit[10] indicating a dynamic mux change
 			control = (control & ~((1 << 10) | (0x3f << 20) | (1 << 18) | (0x3 << 16)))
 					| ((1 << 10)
 					| (dyn_div << 20)
 					| (dyn_post_mux << 18)
 					| (dyn_pre_mux << 16));
 		}
 		// Select Dynamic mux
 		control = control & ~(1 << 11);
 	}
 	Wr(HHI_SYS_CPU_CLK_CNTL,control);
 	//
 	// Now set the divided clocks related to the System CPU
 	//
 	// This function changes the clock ratios for the
 	// PCLK, ACLKM (AXI) and ATCLK
 	//		.clk_clken0_i	( {clk_div2_en,clk_div2}	),
 	//		.clk_clken1_i	( {clk_div3_en,clk_div3}	),
 	//		.clk_clken2_i	( {clk_div4_en,clk_div4}	),
 	//		.clk_clken3_i	( {clk_div5_en,clk_div5}	),
 	//		.clk_clken4_i	( {clk_div6_en,clk_div6}	),
 	//		.clk_clken5_i	( {clk_div7_en,clk_div7}	),
 	//		.clk_clken6_i	( {clk_div8_en,clk_div8}	),

 	uint32_t	control1 = Rd(HHI_SYS_CPU_CLK_CNTL1);

 	//		.cntl_PCLK_mux				( hi_sys_cpu_clk_cntl1[5:3]	 ),
 	if ( (pclk_ratio >= 2) && (pclk_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 3)) | ((pclk_ratio-2) << 3) ; }
 	//		.cntl_ACLKM_clk_mux		 ( hi_sys_cpu_clk_cntl1[11:9]	),	// AXI matrix
 	if ( (aclkm_ratio >= 2) && (aclkm_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 9)) | ((aclkm_ratio-2) << 9) ; }
 	//		.cntl_ATCLK_clk_mux		 ( hi_sys_cpu_clk_cntl1[8:6]	 ),
 	if ( (atclk_ratio >= 2) && (atclk_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 6)) | ((atclk_ratio-2) << 6) ; }
 	Wr( HHI_SYS_CPU_CLK_CNTL1, control1 );
 }

 static int sys_pll_init(sys_pll_set_t * sys_pll_set) {
 	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
 	do {
 		Wr(HHI_SYS_PLL_CNTL, sys_pll_set->pll_cntl|(1<<29));
 		//Wr(HHI_SYS_PLL_CNTL1, sys_pll_set->pll_cntl1);
 		Wr(HHI_SYS_PLL_CNTL2, sys_pll_set->pll_cntl2);
 		Wr(HHI_SYS_PLL_CNTL3, sys_pll_set->pll_cntl3);
 		Wr(HHI_SYS_PLL_CNTL4, sys_pll_set->pll_cntl4);
 		Wr(HHI_SYS_PLL_CNTL5, sys_pll_set->pll_cntl5);
 		Wr(HHI_SYS_PLL_CNTL, ((1<<30)|(1<<29)|sys_pll_set->pll_cntl));
 		Wr(HHI_SYS_PLL_CNTL, Rd(HHI_SYS_PLL_CNTL)&(~(1<<29)));
 		_udelay(20);
 		//printf("pll lock check %d\n", lock_check);
 	} while((!((readl(HHI_SYS_PLL_CNTL)>>31)&0x1)) && --lock_check);
 	if (lock_check != 0)
 		return 0;
 	else
 		return RET_PLL_LOCK_FAIL;
 }

 static int sys_pll_test_all(sys_pll_cfg_t * sys_pll_cfg) {
 	unsigned int i=0;
 	int ret=0;
 	for (i=0; i<(sizeof(sys_pll_cfg_t)/sizeof(sys_pll_set_t)); i++) {
 		ret += sys_pll_test(&(sys_pll_cfg->sys_pll[i]));
 	}
 	return ret;
 }

 static int sys_pll_test(sys_pll_set_t * sys_pll_set) {
 	unsigned int clk_msr_reg = 0;
 	unsigned int clk_msr_val = 0;
 	unsigned int sys_clk = 0;
 	int ret=0;

 	/* store current sys pll cntl */
 	sys_pll_set_t sys_pll;
 	sys_pll.pll_cntl = readl(HHI_SYS_PLL_CNTL);
 	//sys_pll.pll_cntl1 = readl(HHI_SYS_PLL_CNTL1);
 	sys_pll.pll_cntl2 = readl(HHI_SYS_PLL_CNTL2);
 	sys_pll.pll_cntl3 = readl(HHI_SYS_PLL_CNTL3);
 	sys_pll.pll_cntl4 = readl(HHI_SYS_PLL_CNTL4);
 	sys_pll.pll_cntl5 = readl(HHI_SYS_PLL_CNTL5);

 	/* store CPU clk msr reg, restore it when test done */
 	clk_msr_reg = readl(HHI_SYS_CPU_CLK_CNTL1);

 	/* enable CPU clk msr cntl bit */
 	writel(clk_msr_reg | SYS_CLK_DIV16_GATE , HHI_SYS_CPU_CLK_CNTL1);

 	//printf("HHI_SYS_CPU_CLK_CNTL: 0x%x\n", readl(HHI_SYS_CPU_CLK_CNTL));
 	//printf("HHI_SYS_CPU_CLK_CNTL1: 0x%x\n", readl(HHI_SYS_CPU_CLK_CNTL1));

 	if (0 == sys_pll_set->pll_cntl) {
 		printf("sys pll cntl equal NULL, skip\n");
 		return -1;
 	}

 	/* test sys pll */
 	if (sys_pll_set->cpu_clk)
 		sys_clk = sys_pll_set->cpu_clk;
 	else
 		sys_clk = (24/((sys_pll_set->pll_cntl>>9)&0x1F)*(sys_pll_set->pll_cntl&0x1FF)/(1<<((sys_pll_set->pll_cntl>>16)&0x3)));

 	/* switch sys clk to oscillator */
 	clocks_set_sys_cpu_clk( 0, 0, 0, 0);
 	ret = sys_pll_init(sys_pll_set);
 	_udelay(100);
 	if (ret) {
 		printf("SYS pll lock Failed! - %4d MHz\n", sys_clk);
 	}
 	else {
 		clocks_set_sys_cpu_clk( 1, 0, 0, 0);
 		printf("SYS pll lock OK! - %4d MHz. Div16 - %4d MHz. ", sys_clk, sys_clk>>HDMI_PLL_TEST_DIV);
 		clk_msr_val = clk_util_clk_msr(18);
 		printf("CLKMSR(18) - %4d MHz ", clk_msr_val);
 		if (clk_around(clk_msr_val, sys_clk>>SYS_PLL_TEST_DIV)) {
 			/* sys clk/pll div16 */
 			printf(": Match\n");
 		}
 		else {
 			ret = RET_CLK_NOT_MATCH;
 			printf(": MisMatch\n");
 		}
 	}

 	/* restore sys pll */
 	clocks_set_sys_cpu_clk( 0, 0, 0, 0);
 	sys_pll_init(&sys_pll);
 	clocks_set_sys_cpu_clk( 1, 0, 0, 0);

 	/* restore clk msr reg */
 	writel(clk_msr_reg, HHI_SYS_CPU_CLK_CNTL1);
 	return ret;
 }

 static int fix_pll_test(void) {
 	return 0;
 }

 static int ddr_pll_test(void) {
 	return 0;
 }

 static int hdmi_pll_init(hdmi_pll_set_t * hdmi_pll_set) {
 	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
 	do {
 		Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) | (1<<28));
 		Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) & (~(1<<28)));
 		Wr(P_HHI_HDMI_PLL_CNTL, hdmi_pll_set->pll_cntl);
 		//Wr(P_HHI_HDMI_PLL_CNTL1, hdmi_pll_set->pll_cntl1);
 		Wr(P_HHI_HDMI_PLL_CNTL2, hdmi_pll_set->pll_cntl2);
 		Wr(P_HHI_HDMI_PLL_CNTL3, hdmi_pll_set->pll_cntl3);
 		Wr(P_HHI_HDMI_PLL_CNTL4, hdmi_pll_set->pll_cntl4);
 		Wr(P_HHI_HDMI_PLL_CNTL5, hdmi_pll_set->pll_cntl5);
 		Wr(P_HHI_HDMI_PLL_CNTL6, hdmi_pll_set->pll_cntl6);
 		Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) & (~(1<<28)));
 		//printf("lock_check: %d\n", lock_check);
 		_udelay(20);
 	} while ((!((readl(P_HHI_HDMI_PLL_CNTL)>>31)&0x1)) && --lock_check);
 	if (lock_check != 0)
 		return 0;
 	else
 		return RET_PLL_LOCK_FAIL;
 }

 static int hdmi_pll_test_all(hdmi_pll_cfg_t * hdmi_pll_cfg) {
 	unsigned int i=0;
 	int ret=0;
 	for (i=0; i<(sizeof(hdmi_pll_cfg_t)/sizeof(hdmi_pll_set_t)); i++) {
 		ret += hdmi_pll_test(&(hdmi_pll_cfg->hdmi_pll[i]));
 	}
 	return ret;
 }

 static int hdmi_pll_test(hdmi_pll_set_t * hdmi_pll_set) {
 	unsigned int i=0;
 	unsigned int pll_clk = 0;
 	unsigned int clk_msr_val = 0;
 	unsigned int clk_msr_reg = 0;
 	int ret = 0;

 #if 0
 	/* store current pll cntl */
 	hdmi_pll_set_t hdmi_pll;
 	hdmi_pll.pll_cntl = readl(P_HHI_HDMI_PLL_CNTL);
 	hdmi_pll.pll_cntl1 = readl(P_HHI_HDMI_PLL_CNTL1);
 	hdmi_pll.pll_cntl2 = readl(P_HHI_HDMI_PLL_CNTL2);
 	hdmi_pll.pll_cntl3 = readl(P_HHI_HDMI_PLL_CNTL3);
 	hdmi_pll.pll_cntl4 = readl(P_HHI_HDMI_PLL_CNTL4);
 	hdmi_pll.pll_cntl5 = readl(P_HHI_HDMI_PLL_CNTL5);
 #endif

 	/* store pll div setting */
 	clk_msr_reg = readl(HHI_VID_PLL_CLK_DIV);
 	/* connect vid_pll_div to HDMIPLL directly */
 	writel(clk_msr_reg | HDMI_PLL_DIV_CNTL | HDMI_PLL_DIV_GATE, HHI_VID_PLL_CLK_DIV);

 	/* test pll */
 	for (i=0; i<(sizeof(hdmi_pll_cfg_t)/sizeof(hdmi_pll_set_t)); i++) {
 		if (hdmi_pll_set->pll_cntl == hdmi_pll_cfg.hdmi_pll[i].pll_cntl) {
 			pll_clk = hdmi_pll_cfg.hdmi_pll[i].pll_clk;
 		}
 	}
 	_udelay(100);
 	ret = hdmi_pll_init(hdmi_pll_set);
 	_udelay(100);
 	if (ret) {
 		printf("HDMI pll lock Failed! - %4d MHz\n", pll_clk);
 	}
 	else {
 		printf("HDMI pll lock OK! - %4d MHz. Div16 - %4d MHz. ", pll_clk, pll_clk>>HDMI_PLL_TEST_DIV);
 		/* get [  55][1485 MHz] vid_pll_div_clk_out */
 		clk_msr_val = clk_util_clk_msr(55);
 		printf("CLKMSR(55) - %4d MHz ", clk_msr_val);
 		if (clk_around(clk_msr_val, pll_clk>>HDMI_PLL_TEST_DIV)) {
 			printf(": Match\n");
 		}
 		else {
 			ret = RET_CLK_NOT_MATCH;
 			printf(": MisMatch\n");
 		}
 	}

 	/* restore pll */
 	//hdmi_pll_init(hdmi_pll);
 	//hdmi_pll_init(hdmi_pll_cfg->hdmi_pll[0]);

 	/* restore div cntl bit */
 	writel(clk_msr_reg, HHI_VID_PLL_CLK_DIV);

 	return ret;
 }

 static int gp0_pll_test(gp0_pll_set_t * gp0_pll) {
 	int ret=0;
 	unsigned int i=0, pll_clk=0;
 	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
 	unsigned int clk_msr_val = 0;

 	for (i=0; i<(sizeof(gpll0_tbl)/sizeof(gpll0_tbl[0])); i++) {
 		if ((gp0_pll->pll_cntl & 0xFF) == gpll0_tbl[i].m) {
 			pll_clk = gpll0_tbl[i].rate;
 		}
 	}

 	writel(gp0_pll->pll_cntl, HHI_GP0_PLL_CNTL);
 	//writel(gp0_pll->pll_cntl1, HHI_GP0_PLL_CNTL1);
 	writel(gp0_pll->pll_cntl2, HHI_GP0_PLL_CNTL2);
 	writel(gp0_pll->pll_cntl3, HHI_GP0_PLL_CNTL3);
 	writel(gp0_pll->pll_cntl4, HHI_GP0_PLL_CNTL4);
 	writel(gp0_pll->pll_cntl5, HHI_GP0_PLL_CNTL5);
 	lock_check = PLL_LOCK_CHECK_MAX;
 	do {
 		update_bits(HHI_GP0_PLL_CNTL, 1<<29, 1 << 29);
 		_udelay(10);
 		update_bits(HHI_GP0_PLL_CNTL, 1<<29, 0);
 		_udelay(100);
 		//printf("gp0 lock_check: %4d\n", lock_check);
 	} while ((!((readl(HHI_GP0_PLL_CNTL)>>31)&0x1)) && --lock_check);
 	if (0 == lock_check) {
 		printf("GP0 pll lock Failed! - %4d MHz\n", pll_clk);
 		ret = RET_PLL_LOCK_FAIL;
 	}
 	else {
 		printf("GP0 pll lock OK! - %4d MHz. ", pll_clk);
 		/* get gp0_pll_clk */
 		clk_msr_val = clk_util_clk_msr(4);
 		printf("CLKMSR(4) - %4d MHz ", clk_msr_val);
 		if (clk_around(clk_msr_val, pll_clk)) {
 			printf(": Match\n");
 		}
 		else {
 			printf(": MisMatch\n");
 			ret = RET_CLK_NOT_MATCH;
 		}
 	}
 	return ret;
 }

 static int gp0_pll_test_all(void) {
 	unsigned int i=0;
 	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
 	unsigned int clk_msr_val = 0;
 	int ret=0;

 	for (i=0; i<(sizeof(gpll0_tbl)/sizeof(gpll0_tbl[0])); i++) {
 		writel(0x40010250, HHI_GP0_PLL_CNTL);
 		//writel(0xc084a000, HHI_GP0_PLL_CNTL1);
 		writel(0xb75020be, HHI_GP0_PLL_CNTL2);
 		writel(0x0a59a288, HHI_GP0_PLL_CNTL3);
 		writel(0xc000004d, HHI_GP0_PLL_CNTL4);
 		writel(0x00078000, HHI_GP0_PLL_CNTL5);
 		update_bits(HHI_GP0_PLL_CNTL, (0x1ff << 0), (gpll0_tbl[i].m)<<0);
 		update_bits(HHI_GP0_PLL_CNTL, (0x1f << 9), (gpll0_tbl[i].n)<<9);
 		update_bits(HHI_GP0_PLL_CNTL, (0x3 << 16), (gpll0_tbl[i].od)<<16);
 /* dump paras */
 #if 0
 		printf("gp0 %d:\n", gpll0_tbl[i].rate);
 		printf("HHI_GP0_PLL_CNTL: 0x%8x\n", readl(HHI_GP0_PLL_CNTL));
 		printf("HHI_GP0_PLL_CNTL2: 0x%8x\n", readl(HHI_GP0_PLL_CNTL2));
 		printf("HHI_GP0_PLL_CNTL3: 0x%8x\n", readl(HHI_GP0_PLL_CNTL3));
 		printf("HHI_GP0_PLL_CNTL4: 0x%8x\n", readl(HHI_GP0_PLL_CNTL4));
 		printf("HHI_GP0_PLL_CNTL5: 0x%8x\n", readl(HHI_GP0_PLL_CNTL5));
 #endif
 		lock_check = PLL_LOCK_CHECK_MAX;
 		do {
 			update_bits(HHI_GP0_PLL_CNTL, 1<<29, 1 << 29);
 			_udelay(10);
 			update_bits(HHI_GP0_PLL_CNTL, 1<<29, 0);
 			_udelay(100);
 			//printf("gp0 lock_check: %4d\n", lock_check);
 		} while ((!((readl(HHI_GP0_PLL_CNTL)>>31)&0x1)) && --lock_check);
 		if (0 == lock_check) {
 			printf("GP0 pll lock Failed! - %4d MHz\n", gpll0_tbl[i].rate);
 			ret += RET_PLL_LOCK_FAIL;
 		}
 		else {
 			printf("GP0 pll lock OK! - %4d MHz. ", gpll0_tbl[i].rate);
 			/* get gp0_pll_clk */
 			clk_msr_val = clk_util_clk_msr(4);
 			printf("CLKMSR(4) - %4d MHz ", clk_msr_val);
 			if (clk_around(clk_msr_val, gpll0_tbl[i].rate)) {
 				printf(": Match\n");
 			}
 			else {
 				printf(": MisMatch\n");
 				ret += RET_CLK_NOT_MATCH;
 			}
 		}
 	}

 	return ret;
 }

 static int pll_test_all(unsigned char * pll_list) {
 	int ret = 0;
 	unsigned char i=0;
 	for (i=0; i<PLL_ENUM; i++) {
 		switch (pll_list[i]) {
 			case PLL_SYS:
 				ret = sys_pll_test_all(&sys_pll_cfg);
 				pll_report(ret, STR_PLL_TEST_SYS);
 				break;
 			case PLL_FIX:
 				ret = fix_pll_test();
 				pll_report(ret, STR_PLL_TEST_FIX);
 				break;
 			case PLL_DDR:
 				ret = ddr_pll_test();
 				pll_report(ret, STR_PLL_TEST_DDR);
 				break;
 			case PLL_HDMI:
 				ret = hdmi_pll_test_all(&hdmi_pll_cfg);
 				pll_report(ret, STR_PLL_TEST_HDMI);
 				break;
 			case PLL_GP0:
 				ret = gp0_pll_test_all();
 				pll_report(ret, STR_PLL_TEST_GP0);
 				break;
 			default:
 				break;
 		}
 	}
 	return ret;
 }

 int pll_test(int argc, char * const argv[])
 {
 	int ret = 0;

 	sys_pll_set_t sys_pll_set = {0};
 	hdmi_pll_set_t hdmi_pll_set = {0};
 	gp0_pll_set_t gp0_pll_set = {0};

 	unsigned char plls[PLL_ENUM] = {
 		PLL_SYS,
 		0xff,//	PLL_FIX, //0xff will skip this pll
 		0xff,//	PLL_DDR,
 		PLL_HDMI,
 		PLL_GP0,
 	};

 	if (0 == strcmp(STR_PLL_TEST_ALL, argv[1])) {
 		printf("Test all plls\n");
 		pll_test_all(plls);
 	}
 	else if(0 == strcmp(STR_PLL_TEST_SYS, argv[1])) {
 		if (argc == 2) {
 			ret = sys_pll_test_all(&sys_pll_cfg);
 			pll_report(ret, STR_PLL_TEST_SYS);
 		}
 		else if (argc != 7){
 			printf("%s pll test: args error\n", STR_PLL_TEST_SYS);
 			return -1;
 		}
 		else {
 			sys_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
 			sys_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
 			sys_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
 			sys_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
 			sys_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
 			ret = sys_pll_test(&sys_pll_set);
 			pll_report(ret, STR_PLL_TEST_SYS);
 		}
 	}
 	else if (0 == strcmp(STR_PLL_TEST_HDMI, argv[1])) {
 		if (argc == 2) {
 			ret = hdmi_pll_test_all(&hdmi_pll_cfg);
 			pll_report(ret, STR_PLL_TEST_HDMI);
 		}
 		else if (argc != 8){
 			printf("%s pll test: args error\n", STR_PLL_TEST_HDMI);
 			return -1;
 		}
 		else {
 			hdmi_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
 			hdmi_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
 			hdmi_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
 			hdmi_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
 			hdmi_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
 			hdmi_pll_set.pll_cntl6 = simple_strtoul(argv[7], NULL, 16);
 			ret = hdmi_pll_test(&hdmi_pll_set);
 			pll_report(ret, STR_PLL_TEST_HDMI);
 		}
 	}
 	else if (0 == strcmp(STR_PLL_TEST_GP0, argv[1])) {
 		if (argc == 2) {
 			ret = gp0_pll_test_all();
 			pll_report(ret, STR_PLL_TEST_GP0);
 		}
 		else if (argc != 7){
 			printf("%s pll test: args error\n", STR_PLL_TEST_GP0);
 			return -1;
 		}
 		else {
 			gp0_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
 			gp0_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
 			gp0_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
 			gp0_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
 			gp0_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
 			ret = gp0_pll_test(&gp0_pll_set);
 			pll_report(ret, STR_PLL_TEST_GP0);
 		}
 	}
 	else if (0 == strcmp(STR_PLL_TEST_DDR, argv[1])) {
 		printf("%s pll not support now\n", STR_PLL_TEST_DDR);
 		return -1;
 	}
 	else if (0 == strcmp(STR_PLL_TEST_FIX, argv[1])) {
 		printf("%s pll not support now\n", STR_PLL_TEST_FIX);
 		return -1;
 	}

 #if 0
 	unsigned char * pll_list = NULL;
 	switch (get_cpu_id().family_id) {
 		case MESON_CPU_MAJOR_ID_GXTVBB:
 			pll_list = gxtvbb_plls;
 			break;
 		case MESON_CPU_MAJOR_ID_GXL:
 			pll_list = gxl_plls;
 			break;
 		default:
 			printf("un-support chip\n");
 			break;
 	}
 	if (pll_list) {
 		return plltest(pll_list);
 	}
 #endif

 	return 0;
 }
	/*
	* rev history:
	* 2017.04.06 structure done
	*
	*
	*
	*
	*/

	#include <common.h>
	#include <command.h>
	#include <asm/cpu_id.h>
	#include <malloc.h>
	#include <asm/io.h>
	#include <asm/arch/clock.h>
	#include <asm/arch/secure_apb.h>
	#include <asm/arch/timer.h>
	#include <asm/arch/pll.h>

	#define STR_PLL_TEST_ALL "all"
	#define STR_PLL_TEST_SYS "sys"
	#define STR_PLL_TEST_FIX "fix"
	#define STR_PLL_TEST_DDR "ddr"
	#define STR_PLL_TEST_HDMI "hdmi"
	#define STR_PLL_TEST_GP0 "gp0"

	#define PLL_LOCK_CHECK_MAX 20

	#define RET_PLL_LOCK_FAIL 0x1000
	#define RET_CLK_NOT_MATCH 0x1
	#define SYS_CLK_DIV16_GATE (1<<1)
	#define SYS_PLL_TEST_DIV 4 /* div16 */
	#define HDMI_PLL_DIV_CNTL (1<<18)
	#define HDMI_PLL_DIV_GATE (1<<19)
	#define HDMI_PLL_TEST_DIV 4 /* div2/2/4 */
	#define GP0_PLL_TEST_DIV 0 /* div1 */

	#define Wr(addr, data) writel(data, addr)
	#define Rd(addr) readl(addr)

	static int sys_pll_init(sys_pll_set_t * sys_pll_set);
	static int sys_pll_test(sys_pll_set_t * sys_pll_set);
	static int sys_pll_test_all(sys_pll_cfg_t * sys_pll_cfg);
	static int fix_pll_test(void);
	static int ddr_pll_test(void);
	static int hdmi_pll_init(hdmi_pll_set_t * hdmi_pll_set);
	static int hdmi_pll_test(hdmi_pll_set_t * hdmi_pll_set);
	static int hdmi_pll_test_all(hdmi_pll_cfg_t * hdmi_pll_cfg);
	static int gp0_pll_test(gp0_pll_set_t * gp0_pll);
	static int gp0_pll_test_all(void);

	#if 0
	static unsigned int pll_range[PLL_ENUM][2] = {
	{101, 202}, //sys pll range
	{303, 404}, //fix pll range
	{505, 606}, //ddr pll range
	{707, 808}, //hdmi pll range
	{909, 999}, // pll range
	};

	static char pll_range_ind[PLL_ENUM][10] = {
	"sys",
	"fix",
	"ddr",
	"hdmi",
	"gp0",
	};
	#endif

	static void update_bits(size_t reg, size_t mask, unsigned int val)
	{
	unsigned int tmp, orig;
	orig = readl(reg);
	tmp = orig & ~mask;
	tmp \|= val & mask;
	writel(tmp, reg);
	}

	hdmi_pll_cfg_t hdmi_pll_cfg = {
	.hdmi_pll[0] = {
	.pll_clk = 5940, /* MHz */
	.pll_cntl = 0x5800027b,
	.pll_cntl2 = 0x000E4300, /* cntl2[23:20] use 5 = div4 */
	.pll_cntl3 = 0x12dc5081,
	.pll_cntl4 = 0x801da72c,
	.pll_cntl5 = 0x71486980,
	.pll_cntl6 = 0x00002e55
	},
	.hdmi_pll[1] = {
	.pll_clk = 4320,
	.pll_cntl = 0x5800025a,
	.pll_cntl2 = 0x000E0000,
	.pll_cntl3 = 0x0d5c5091,
	.pll_cntl4 = 0x801da72c,
	.pll_cntl5 = 0x71486980,
	.pll_cntl6 = 0x00002e55
	},
	.hdmi_pll[2] = {
	.pll_clk = 3712,
	.pll_cntl = 0x5800024d,
	.pll_cntl2 = 0x000E4160,
	.pll_cntl3 = 0x0d5c5091,
	.pll_cntl4 = 0x801da72c,
	.pll_cntl5 = 0x71486980,
	.pll_cntl6 = 0x00002e55
	},
	#if 0
	.hdmi_pll[3] = {
	.pll_clk = 2970,
	.pll_cntl = 0x400002b4,
	.pll_cntl2 = 0x000E4380,
	.pll_cntl3 = 0x0d5c5091,
	.pll_cntl4 = 0x801da72c,
	.pll_cntl5 = 0x71486980,
	.pll_cntl6 = 0x00002e55
	},
	#endif
	};

	sys_pll_cfg_t sys_pll_cfg = {
	/* 960M*/
	#if 0
	.sys_pll[0] = {
	.cpu_clk = 960,
	.pll_cntl = 0x60000228,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1056M/
	.sys_pll[1] = {
	.cpu_clk = 1056,
	.pll_cntl = 0x6000022c,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	#endif
	/1152M/
	.sys_pll[0] = {
	.cpu_clk = 1152,
	.pll_cntl = 0x60000230,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1248M/
	.sys_pll[1] = {
	.cpu_clk = 1248,
	.pll_cntl = 0x60000234,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1344M/
	.sys_pll[2] = {
	.cpu_clk = 1344,
	.pll_cntl = 0x60000238,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1440M/
	.sys_pll[3] = {
	.cpu_clk = 1440,
	.pll_cntl = 0x6000023c,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1536M/
	.sys_pll[4] = {
	.cpu_clk = 1536,
	.pll_cntl = 0x60000240,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	/1632M/
	.sys_pll[5] = {
	.cpu_clk = 1632,
	.pll_cntl = 0x60000244,
	//.pll_cntl1 = 0xc4258100,
	.pll_cntl2 = 0x5ac80000,
	.pll_cntl3 = 0x8e452015,
	.pll_cntl4 = 0x0401d40c,
	.pll_cntl5 = 0x00000870
	},
	};

	#define GPLL0_RATE(_rate, _m, _n, _od) \
	{ \
	.rate = (_rate), \
	.m = (_m), \
	.n = (_n), \
	.od = (_od), \
	}

	static gpll_rate_table_t gpll0_tbl[] = {
	GPLL0_RATE(504, 42, 1, 1),
	GPLL0_RATE(516, 43, 1, 1),
	GPLL0_RATE(528, 44, 1, 1),
	GPLL0_RATE(540, 45, 1, 1),
	GPLL0_RATE(552, 46, 1, 1),
	GPLL0_RATE(564, 47, 1, 1),
	GPLL0_RATE(576, 48, 1, 1),
	GPLL0_RATE(588, 49, 1, 1),
	GPLL0_RATE(600, 50, 1, 1),
	GPLL0_RATE(612, 51, 1, 1),
	GPLL0_RATE(624, 52, 1, 1),
	GPLL0_RATE(636, 53, 1, 1),
	GPLL0_RATE(648, 54, 1, 1),
	GPLL0_RATE(660, 55, 1, 1),
	GPLL0_RATE(672, 56, 1, 1),
	GPLL0_RATE(684, 57, 1, 1),
	GPLL0_RATE(696, 58, 1, 1),
	GPLL0_RATE(708, 59, 1, 1),
	GPLL0_RATE(720, 60, 1, 1),
	GPLL0_RATE(732, 61, 1, 1),
	};

	static void pll_report(unsigned int flag, char * name) {
	if (flag)
	printf("%s pll test failed!\n", name);
	else
	printf("%s pll test pass!\n", name);
	return;
	}

	static int clk_around(unsigned int clk, unsigned int cmp) {
	if (((cmp-1) <= clk) && (clk <= (cmp+1)))
	return 1;
	else
	return 0;
	}

	static void clocks_set_sys_cpu_clk(uint32_t freq, uint32_t pclk_ratio, uint32_t aclkm_ratio, uint32_t atclk_ratio )
	{
	uint32_t control = 0;
	uint32_t dyn_pre_mux = 0;
	uint32_t dyn_post_mux = 0;
	uint32_t dyn_div = 0;

	// Make sure not busy from last setting and we currently match the last setting
	do {
	control = Rd(HHI_SYS_CPU_CLK_CNTL);
	} while( (control & (1 << 28)) );

	control = control \| (1 << 26); // Enable

	// Switching to System PLL...just change the final mux
	if ( freq == 1 ) {
	// wire cntl_final_mux_sel = control[11];
	control = control \| (1 << 11);
	} else {
	switch ( freq ) {
	case 0: // If Crystal
	dyn_pre_mux = 0;
	dyn_post_mux = 0;
	dyn_div = 0; // divide by 1
	break;
	case 1000: // If Crystal
	dyn_pre_mux = 1;
	dyn_post_mux = 0;
	dyn_div = 0;
	break;
	}
	if ( control & (1 << 10) ) { // if using Dyn mux1, set dyn mux 0
	// Toggle bit[10] indicating a dynamic mux change
	control = (control & ~((1 << 10) \| (0x3f << 4) \| (1 << 2) \| (0x3 << 0)))
	\| ((0 << 10)
	\| (dyn_div << 4)
	\| (dyn_post_mux << 2)
	\| (dyn_pre_mux << 0));
	} else {
	// Toggle bit[10] indicating a dynamic mux change
	control = (control & ~((1 << 10) \| (0x3f << 20) \| (1 << 18) \| (0x3 << 16)))
	\| ((1 << 10)
	\| (dyn_div << 20)
	\| (dyn_post_mux << 18)
	\| (dyn_pre_mux << 16));
	}
	// Select Dynamic mux
	control = control & ~(1 << 11);
	}
	Wr(HHI_SYS_CPU_CLK_CNTL,control);
	//
	// Now set the divided clocks related to the System CPU
	//
	// This function changes the clock ratios for the
	// PCLK, ACLKM (AXI) and ATCLK
	// .clk_clken0_i ( {clk_div2_en,clk_div2} ),
	// .clk_clken1_i ( {clk_div3_en,clk_div3} ),
	// .clk_clken2_i ( {clk_div4_en,clk_div4} ),
	// .clk_clken3_i ( {clk_div5_en,clk_div5} ),
	// .clk_clken4_i ( {clk_div6_en,clk_div6} ),
	// .clk_clken5_i ( {clk_div7_en,clk_div7} ),
	// .clk_clken6_i ( {clk_div8_en,clk_div8} ),

	uint32_t control1 = Rd(HHI_SYS_CPU_CLK_CNTL1);

	// .cntl_PCLK_mux ( hi_sys_cpu_clk_cntl1[5:3] ),
	if ( (pclk_ratio >= 2) && (pclk_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 3)) \| ((pclk_ratio-2) << 3) ; }
	// .cntl_ACLKM_clk_mux ( hi_sys_cpu_clk_cntl1[11:9] ), // AXI matrix
	if ( (aclkm_ratio >= 2) && (aclkm_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 9)) \| ((aclkm_ratio-2) << 9) ; }
	// .cntl_ATCLK_clk_mux ( hi_sys_cpu_clk_cntl1[8:6] ),
	if ( (atclk_ratio >= 2) && (atclk_ratio <= 8) ) { control1 = (control1 & ~(0x7 << 6)) \| ((atclk_ratio-2) << 6) ; }
	Wr( HHI_SYS_CPU_CLK_CNTL1, control1 );
	}

	static int sys_pll_init(sys_pll_set_t * sys_pll_set) {
	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
	do {
	Wr(HHI_SYS_PLL_CNTL, sys_pll_set->pll_cntl\|(1<<29));
	//Wr(HHI_SYS_PLL_CNTL1, sys_pll_set->pll_cntl1);
	Wr(HHI_SYS_PLL_CNTL2, sys_pll_set->pll_cntl2);
	Wr(HHI_SYS_PLL_CNTL3, sys_pll_set->pll_cntl3);
	Wr(HHI_SYS_PLL_CNTL4, sys_pll_set->pll_cntl4);
	Wr(HHI_SYS_PLL_CNTL5, sys_pll_set->pll_cntl5);
	Wr(HHI_SYS_PLL_CNTL, ((1<<30)\|(1<<29)\|sys_pll_set->pll_cntl));
	Wr(HHI_SYS_PLL_CNTL, Rd(HHI_SYS_PLL_CNTL)&(~(1<<29)));
	_udelay(20);
	//printf("pll lock check %d\n", lock_check);
	} while((!((readl(HHI_SYS_PLL_CNTL)>>31)&0x1)) && --lock_check);
	if (lock_check != 0)
	return 0;
	else
	return RET_PLL_LOCK_FAIL;
	}

	static int sys_pll_test_all(sys_pll_cfg_t * sys_pll_cfg) {
	unsigned int i=0;
	int ret=0;
	for (i=0; i<(sizeof(sys_pll_cfg_t)/sizeof(sys_pll_set_t)); i++) {
	ret += sys_pll_test(&(sys_pll_cfg->sys_pll[i]));
	}
	return ret;
	}

	static int sys_pll_test(sys_pll_set_t * sys_pll_set) {
	unsigned int clk_msr_reg = 0;
	unsigned int clk_msr_val = 0;
	unsigned int sys_clk = 0;
	int ret=0;

	/* store current sys pll cntl */
	sys_pll_set_t sys_pll;
	sys_pll.pll_cntl = readl(HHI_SYS_PLL_CNTL);
	//sys_pll.pll_cntl1 = readl(HHI_SYS_PLL_CNTL1);
	sys_pll.pll_cntl2 = readl(HHI_SYS_PLL_CNTL2);
	sys_pll.pll_cntl3 = readl(HHI_SYS_PLL_CNTL3);
	sys_pll.pll_cntl4 = readl(HHI_SYS_PLL_CNTL4);
	sys_pll.pll_cntl5 = readl(HHI_SYS_PLL_CNTL5);

	/* store CPU clk msr reg, restore it when test done */
	clk_msr_reg = readl(HHI_SYS_CPU_CLK_CNTL1);

	/* enable CPU clk msr cntl bit */
	writel(clk_msr_reg \| SYS_CLK_DIV16_GATE , HHI_SYS_CPU_CLK_CNTL1);

	//printf("HHI_SYS_CPU_CLK_CNTL: 0x%x\n", readl(HHI_SYS_CPU_CLK_CNTL));
	//printf("HHI_SYS_CPU_CLK_CNTL1: 0x%x\n", readl(HHI_SYS_CPU_CLK_CNTL1));

	if (0 == sys_pll_set->pll_cntl) {
	printf("sys pll cntl equal NULL, skip\n");
	return -1;
	}

	/* test sys pll */
	if (sys_pll_set->cpu_clk)
	sys_clk = sys_pll_set->cpu_clk;
	else
	sys_clk = (24/((sys_pll_set->pll_cntl>>9)&0x1F)*(sys_pll_set->pll_cntl&0x1FF)/(1<<((sys_pll_set->pll_cntl>>16)&0x3)));

	/* switch sys clk to oscillator */
	clocks_set_sys_cpu_clk( 0, 0, 0, 0);
	ret = sys_pll_init(sys_pll_set);
	_udelay(100);
	if (ret) {
	printf("SYS pll lock Failed! - %4d MHz\n", sys_clk);
	}
	else {
	clocks_set_sys_cpu_clk( 1, 0, 0, 0);
	printf("SYS pll lock OK! - %4d MHz. Div16 - %4d MHz. ", sys_clk, sys_clk>>HDMI_PLL_TEST_DIV);
	clk_msr_val = clk_util_clk_msr(18);
	printf("CLKMSR(18) - %4d MHz ", clk_msr_val);
	if (clk_around(clk_msr_val, sys_clk>>SYS_PLL_TEST_DIV)) {
	/* sys clk/pll div16 */
	printf(": Match\n");
	}
	else {
	ret = RET_CLK_NOT_MATCH;
	printf(": MisMatch\n");
	}
	}

	/* restore sys pll */
	clocks_set_sys_cpu_clk( 0, 0, 0, 0);
	sys_pll_init(&sys_pll);
	clocks_set_sys_cpu_clk( 1, 0, 0, 0);

	/* restore clk msr reg */
	writel(clk_msr_reg, HHI_SYS_CPU_CLK_CNTL1);
	return ret;
	}

	static int fix_pll_test(void) {
	return 0;
	}

	static int ddr_pll_test(void) {
	return 0;
	}

	static int hdmi_pll_init(hdmi_pll_set_t * hdmi_pll_set) {
	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
	do {
	Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) \| (1<<28));
	Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) & (~(1<<28)));
	Wr(P_HHI_HDMI_PLL_CNTL, hdmi_pll_set->pll_cntl);
	//Wr(P_HHI_HDMI_PLL_CNTL1, hdmi_pll_set->pll_cntl1);
	Wr(P_HHI_HDMI_PLL_CNTL2, hdmi_pll_set->pll_cntl2);
	Wr(P_HHI_HDMI_PLL_CNTL3, hdmi_pll_set->pll_cntl3);
	Wr(P_HHI_HDMI_PLL_CNTL4, hdmi_pll_set->pll_cntl4);
	Wr(P_HHI_HDMI_PLL_CNTL5, hdmi_pll_set->pll_cntl5);
	Wr(P_HHI_HDMI_PLL_CNTL6, hdmi_pll_set->pll_cntl6);
	Wr(P_HHI_HDMI_PLL_CNTL, Rd(P_HHI_HDMI_PLL_CNTL) & (~(1<<28)));
	//printf("lock_check: %d\n", lock_check);
	_udelay(20);
	} while ((!((readl(P_HHI_HDMI_PLL_CNTL)>>31)&0x1)) && --lock_check);
	if (lock_check != 0)
	return 0;
	else
	return RET_PLL_LOCK_FAIL;
	}

	static int hdmi_pll_test_all(hdmi_pll_cfg_t * hdmi_pll_cfg) {
	unsigned int i=0;
	int ret=0;
	for (i=0; i<(sizeof(hdmi_pll_cfg_t)/sizeof(hdmi_pll_set_t)); i++) {
	ret += hdmi_pll_test(&(hdmi_pll_cfg->hdmi_pll[i]));
	}
	return ret;
	}

	static int hdmi_pll_test(hdmi_pll_set_t * hdmi_pll_set) {
	unsigned int i=0;
	unsigned int pll_clk = 0;
	unsigned int clk_msr_val = 0;
	unsigned int clk_msr_reg = 0;
	int ret = 0;

	#if 0
	/* store current pll cntl */
	hdmi_pll_set_t hdmi_pll;
	hdmi_pll.pll_cntl = readl(P_HHI_HDMI_PLL_CNTL);
	hdmi_pll.pll_cntl1 = readl(P_HHI_HDMI_PLL_CNTL1);
	hdmi_pll.pll_cntl2 = readl(P_HHI_HDMI_PLL_CNTL2);
	hdmi_pll.pll_cntl3 = readl(P_HHI_HDMI_PLL_CNTL3);
	hdmi_pll.pll_cntl4 = readl(P_HHI_HDMI_PLL_CNTL4);
	hdmi_pll.pll_cntl5 = readl(P_HHI_HDMI_PLL_CNTL5);
	#endif

	/* store pll div setting */
	clk_msr_reg = readl(HHI_VID_PLL_CLK_DIV);
	/* connect vid_pll_div to HDMIPLL directly */
	writel(clk_msr_reg \| HDMI_PLL_DIV_CNTL \| HDMI_PLL_DIV_GATE, HHI_VID_PLL_CLK_DIV);

	/* test pll */
	for (i=0; i<(sizeof(hdmi_pll_cfg_t)/sizeof(hdmi_pll_set_t)); i++) {
	if (hdmi_pll_set->pll_cntl == hdmi_pll_cfg.hdmi_pll[i].pll_cntl) {
	pll_clk = hdmi_pll_cfg.hdmi_pll[i].pll_clk;
	}
	}
	_udelay(100);
	ret = hdmi_pll_init(hdmi_pll_set);
	_udelay(100);
	if (ret) {
	printf("HDMI pll lock Failed! - %4d MHz\n", pll_clk);
	}
	else {
	printf("HDMI pll lock OK! - %4d MHz. Div16 - %4d MHz. ", pll_clk, pll_clk>>HDMI_PLL_TEST_DIV);
	/* get [ 55][1485 MHz] vid_pll_div_clk_out */
	clk_msr_val = clk_util_clk_msr(55);
	printf("CLKMSR(55) - %4d MHz ", clk_msr_val);
	if (clk_around(clk_msr_val, pll_clk>>HDMI_PLL_TEST_DIV)) {
	printf(": Match\n");
	}
	else {
	ret = RET_CLK_NOT_MATCH;
	printf(": MisMatch\n");
	}
	}

	/* restore pll */
	//hdmi_pll_init(hdmi_pll);
	//hdmi_pll_init(hdmi_pll_cfg->hdmi_pll[0]);

	/* restore div cntl bit */
	writel(clk_msr_reg, HHI_VID_PLL_CLK_DIV);

	return ret;
	}

	static int gp0_pll_test(gp0_pll_set_t * gp0_pll) {
	int ret=0;
	unsigned int i=0, pll_clk=0;
	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
	unsigned int clk_msr_val = 0;

	for (i=0; i<(sizeof(gpll0_tbl)/sizeof(gpll0_tbl[0])); i++) {
	if ((gp0_pll->pll_cntl & 0xFF) == gpll0_tbl[i].m) {
	pll_clk = gpll0_tbl[i].rate;
	}
	}

	writel(gp0_pll->pll_cntl, HHI_GP0_PLL_CNTL);
	//writel(gp0_pll->pll_cntl1, HHI_GP0_PLL_CNTL1);
	writel(gp0_pll->pll_cntl2, HHI_GP0_PLL_CNTL2);
	writel(gp0_pll->pll_cntl3, HHI_GP0_PLL_CNTL3);
	writel(gp0_pll->pll_cntl4, HHI_GP0_PLL_CNTL4);
	writel(gp0_pll->pll_cntl5, HHI_GP0_PLL_CNTL5);
	lock_check = PLL_LOCK_CHECK_MAX;
	do {
	update_bits(HHI_GP0_PLL_CNTL, 1<<29, 1 << 29);
	_udelay(10);
	update_bits(HHI_GP0_PLL_CNTL, 1<<29, 0);
	_udelay(100);
	//printf("gp0 lock_check: %4d\n", lock_check);
	} while ((!((readl(HHI_GP0_PLL_CNTL)>>31)&0x1)) && --lock_check);
	if (0 == lock_check) {
	printf("GP0 pll lock Failed! - %4d MHz\n", pll_clk);
	ret = RET_PLL_LOCK_FAIL;
	}
	else {
	printf("GP0 pll lock OK! - %4d MHz. ", pll_clk);
	/* get gp0_pll_clk */
	clk_msr_val = clk_util_clk_msr(4);
	printf("CLKMSR(4) - %4d MHz ", clk_msr_val);
	if (clk_around(clk_msr_val, pll_clk)) {
	printf(": Match\n");
	}
	else {
	printf(": MisMatch\n");
	ret = RET_CLK_NOT_MATCH;
	}
	}
	return ret;
	}

	static int gp0_pll_test_all(void) {
	unsigned int i=0;
	unsigned int lock_check = PLL_LOCK_CHECK_MAX;
	unsigned int clk_msr_val = 0;
	int ret=0;

	for (i=0; i<(sizeof(gpll0_tbl)/sizeof(gpll0_tbl[0])); i++) {
	writel(0x40010250, HHI_GP0_PLL_CNTL);
	//writel(0xc084a000, HHI_GP0_PLL_CNTL1);
	writel(0xb75020be, HHI_GP0_PLL_CNTL2);
	writel(0x0a59a288, HHI_GP0_PLL_CNTL3);
	writel(0xc000004d, HHI_GP0_PLL_CNTL4);
	writel(0x00078000, HHI_GP0_PLL_CNTL5);
	update_bits(HHI_GP0_PLL_CNTL, (0x1ff << 0), (gpll0_tbl[i].m)<<0);
	update_bits(HHI_GP0_PLL_CNTL, (0x1f << 9), (gpll0_tbl[i].n)<<9);
	update_bits(HHI_GP0_PLL_CNTL, (0x3 << 16), (gpll0_tbl[i].od)<<16);
	/* dump paras */
	#if 0
	printf("gp0 %d:\n", gpll0_tbl[i].rate);
	printf("HHI_GP0_PLL_CNTL: 0x%8x\n", readl(HHI_GP0_PLL_CNTL));
	printf("HHI_GP0_PLL_CNTL2: 0x%8x\n", readl(HHI_GP0_PLL_CNTL2));
	printf("HHI_GP0_PLL_CNTL3: 0x%8x\n", readl(HHI_GP0_PLL_CNTL3));
	printf("HHI_GP0_PLL_CNTL4: 0x%8x\n", readl(HHI_GP0_PLL_CNTL4));
	printf("HHI_GP0_PLL_CNTL5: 0x%8x\n", readl(HHI_GP0_PLL_CNTL5));
	#endif
	lock_check = PLL_LOCK_CHECK_MAX;
	do {
	update_bits(HHI_GP0_PLL_CNTL, 1<<29, 1 << 29);
	_udelay(10);
	update_bits(HHI_GP0_PLL_CNTL, 1<<29, 0);
	_udelay(100);
	//printf("gp0 lock_check: %4d\n", lock_check);
	} while ((!((readl(HHI_GP0_PLL_CNTL)>>31)&0x1)) && --lock_check);
	if (0 == lock_check) {
	printf("GP0 pll lock Failed! - %4d MHz\n", gpll0_tbl[i].rate);
	ret += RET_PLL_LOCK_FAIL;
	}
	else {
	printf("GP0 pll lock OK! - %4d MHz. ", gpll0_tbl[i].rate);
	/* get gp0_pll_clk */
	clk_msr_val = clk_util_clk_msr(4);
	printf("CLKMSR(4) - %4d MHz ", clk_msr_val);
	if (clk_around(clk_msr_val, gpll0_tbl[i].rate)) {
	printf(": Match\n");
	}
	else {
	printf(": MisMatch\n");
	ret += RET_CLK_NOT_MATCH;
	}
	}
	}

	return ret;
	}

	static int pll_test_all(unsigned char * pll_list) {
	int ret = 0;
	unsigned char i=0;
	for (i=0; i<PLL_ENUM; i++) {
	switch (pll_list[i]) {
	case PLL_SYS:
	ret = sys_pll_test_all(&sys_pll_cfg);
	pll_report(ret, STR_PLL_TEST_SYS);
	break;
	case PLL_FIX:
	ret = fix_pll_test();
	pll_report(ret, STR_PLL_TEST_FIX);
	break;
	case PLL_DDR:
	ret = ddr_pll_test();
	pll_report(ret, STR_PLL_TEST_DDR);
	break;
	case PLL_HDMI:
	ret = hdmi_pll_test_all(&hdmi_pll_cfg);
	pll_report(ret, STR_PLL_TEST_HDMI);
	break;
	case PLL_GP0:
	ret = gp0_pll_test_all();
	pll_report(ret, STR_PLL_TEST_GP0);
	break;
	default:
	break;
	}
	}
	return ret;
	}

	int pll_test(int argc, char * const argv[])
	{
	int ret = 0;

	sys_pll_set_t sys_pll_set = {0};
	hdmi_pll_set_t hdmi_pll_set = {0};
	gp0_pll_set_t gp0_pll_set = {0};

	unsigned char plls[PLL_ENUM] = {
	PLL_SYS,
	0xff,// PLL_FIX, //0xff will skip this pll
	0xff,// PLL_DDR,
	PLL_HDMI,
	PLL_GP0,
	};

	if (0 == strcmp(STR_PLL_TEST_ALL, argv[1])) {
	printf("Test all plls\n");
	pll_test_all(plls);
	}
	else if(0 == strcmp(STR_PLL_TEST_SYS, argv[1])) {
	if (argc == 2) {
	ret = sys_pll_test_all(&sys_pll_cfg);
	pll_report(ret, STR_PLL_TEST_SYS);
	}
	else if (argc != 7){
	printf("%s pll test: args error\n", STR_PLL_TEST_SYS);
	return -1;
	}
	else {
	sys_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
	sys_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
	sys_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
	sys_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
	sys_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
	ret = sys_pll_test(&sys_pll_set);
	pll_report(ret, STR_PLL_TEST_SYS);
	}
	}
	else if (0 == strcmp(STR_PLL_TEST_HDMI, argv[1])) {
	if (argc == 2) {
	ret = hdmi_pll_test_all(&hdmi_pll_cfg);
	pll_report(ret, STR_PLL_TEST_HDMI);
	}
	else if (argc != 8){
	printf("%s pll test: args error\n", STR_PLL_TEST_HDMI);
	return -1;
	}
	else {
	hdmi_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
	hdmi_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
	hdmi_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
	hdmi_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
	hdmi_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
	hdmi_pll_set.pll_cntl6 = simple_strtoul(argv[7], NULL, 16);
	ret = hdmi_pll_test(&hdmi_pll_set);
	pll_report(ret, STR_PLL_TEST_HDMI);
	}
	}
	else if (0 == strcmp(STR_PLL_TEST_GP0, argv[1])) {
	if (argc == 2) {
	ret = gp0_pll_test_all();
	pll_report(ret, STR_PLL_TEST_GP0);
	}
	else if (argc != 7){
	printf("%s pll test: args error\n", STR_PLL_TEST_GP0);
	return -1;
	}
	else {
	gp0_pll_set.pll_cntl = simple_strtoul(argv[2], NULL, 16);
	gp0_pll_set.pll_cntl2 = simple_strtoul(argv[3], NULL, 16);
	gp0_pll_set.pll_cntl3 = simple_strtoul(argv[4], NULL, 16);
	gp0_pll_set.pll_cntl4 = simple_strtoul(argv[5], NULL, 16);
	gp0_pll_set.pll_cntl5 = simple_strtoul(argv[6], NULL, 16);
	ret = gp0_pll_test(&gp0_pll_set);
	pll_report(ret, STR_PLL_TEST_GP0);
	}
	}
	else if (0 == strcmp(STR_PLL_TEST_DDR, argv[1])) {
	printf("%s pll not support now\n", STR_PLL_TEST_DDR);
	return -1;
	}
	else if (0 == strcmp(STR_PLL_TEST_FIX, argv[1])) {
	printf("%s pll not support now\n", STR_PLL_TEST_FIX);
	return -1;
	}

	#if 0
	unsigned char * pll_list = NULL;
	switch (get_cpu_id().family_id) {
	case MESON_CPU_MAJOR_ID_GXTVBB:
	pll_list = gxtvbb_plls;
	break;
	case MESON_CPU_MAJOR_ID_GXL:
	pll_list = gxl_plls;
	break;
	default:
	printf("un-support chip\n");
	break;
	}
	if (pll_list) {
	return plltest(pll_list);
	}
	#endif

	return 0;
	}