[J-u-boot.git] / board / freescale / common / zm7300.c

// SPDX-License-Identifier: GPL-2.0+
/*
 * Copyright 2013 Freescale Semiconductor, Inc.
 */

/* Power-One ZM7300 DPM */
#include "zm7300.h"
#include <log.h>

#define DPM_WP 0x96
#define WRP_OPCODE 0x01
#define WRM_OPCODE 0x02
#define RRP_OPCODE 0x11

#define DPM_SUCCESS 0x01
#define DPM_EXEC_FAIL 0x00

static const uint16_t hex_to_1_10mv[] = {
	5000,
	5125,
	5250,
	5375,
	5500,
	5625,
	5750,
	5875,
	6000,
	6125,
	6250,
	6375,
	6500,
	6625,
	6750,
	6875,
	7000,
	7125,
	7250,
	7375,
	7500,
	7625,
	7750,
	7875,
	8000,
	8125,
	8250,
	8375,
	8500,
	8625,
	8750,
	8875,
	9000,
	9125,
	9250,
	9375,
	9500,  /* 0.95mV */
	9625,
	9750,
	9875,
	10000,  /* 1.0V */
	10125,
	10250,
	10375,
	10500,
	10625,
	10750,
	10875,
	11000,
	11125,
	11250,
	11375,
	11500,
	11625,
	11750,
	11875,
	12000,
	12125,
	12250,
	12375,
	0,	/* reserved */
};


/* Read Data d from Register r of POL p */
u8 dpm_rrp(uchar r)
{
	u8 ret[5];

	ret[0] = RRP_OPCODE;
	/* POL is 0 */
	ret[1] = 0;
	ret[2] = r;
	i2c_read(I2C_DPM_ADDR, 0, -3, ret, 2);
	if (ret[1] == DPM_SUCCESS) { /* the DPM returned success as status */
		debug("RRP_OPCODE returned success data is %x\n", ret[0]);
		return ret[0];
	} else {
		return -1;
	}
}

/* Write Data d into DPM register r (RAM) */
int dpm_wrm(u8 r, u8 d)
{
	u8 ret[5];

	ret[0] = WRM_OPCODE;
	ret[1] = r;
	ret[2] = d;
	i2c_read(I2C_DPM_ADDR, 0, -3, ret, 1);
	if (ret[0] == DPM_SUCCESS) { /* the DPM returned success as status */
		debug("WRM_OPCODE returned success data is %x\n", ret[0]);
		return ret[0];
	} else {
		return -1;
	}
}

/* Write Data d into Register r of POL(s) a */
int dpm_wrp(u8 r, u8 d)
{
	u8 ret[7];

	ret[0] = WRP_OPCODE;
	/* only POL0 is present */
	ret[1] = 0x01;
	ret[2] = 0x00;
	ret[3] = 0x00;
	ret[4] = 0x00;
	ret[5] = r;
	ret[6] = d;
	i2c_read(I2C_DPM_ADDR, 0, -7, ret, 1);
	if (ret[0] == DPM_SUCCESS) { /* the DPM returned success as status */
		debug("WRP_OPCODE returned success data is %x\n", ret[0]);
		return 0;
	} else {
		return -1;
	}
}

/* Uses the DPM command RRP */
u8 zm_read(uchar reg)
{
	return dpm_rrp(reg);
}

/* ZM_write --
	Steps:
	a. Write data to the register
	b. Read data from register and compare to written value
	c. Return return_code & voltage_read
*/
u8 zm_write(u8 reg, u8 data)
{
	u8 d;

	/* write data to register */
	dpm_wrp(reg, data);

	/* read register and compare to written value */
	d = dpm_rrp(reg);
	if (d != data) {
		printf("zm_write : Comparison register data failed\n");
		return -1;
	}

	return d;
}

/* zm_write_out_voltage
 * voltage in 1/10 mV
 */
int zm_write_voltage(int voltage)
{
	u8 reg = 0x7, vid;
	uint16_t voltage_read;
	u8 ret;

	vid =  (voltage - 5000) / ZM_STEP;

	ret = zm_write(reg, vid);
	if (ret != -1) {
		voltage_read = hex_to_1_10mv[ret];
		debug("voltage set to %dmV\n", voltage_read/10);
		return voltage_read;
	}
	return -1;
}

/* zm_read_out_voltage
 * voltage in 1/10 mV
 */
int zm_read_voltage(void)
{
	u8 reg = 0x7;
	u8 ret;
	int voltage;

	ret = zm_read(reg);
	if (ret != -1) {
		voltage =  hex_to_1_10mv[ret];
		debug("Voltage read is %dmV\n", voltage/10);
		return voltage;
	} else {
		return -1;
	}
}

int zm_disable_wp()
{
	u8 new_wp_value;

	/* Disable using Write-Protect register 0x96 */
	new_wp_value = 0x8;
	if ((dpm_wrm(DPM_WP, new_wp_value)) < 0) {
		printf("Disable Write-Protect register failed\n");
		return -1;
	}
	return 0;
}

int zm_enable_wp()
{
	u8 orig_wp_value;
	orig_wp_value = 0x0;

	/* Enable using Write-Protect register 0x96 */
	if ((dpm_wrm(DPM_WP, orig_wp_value)) < 0) {
		printf("Enable Write-Protect register failed\n");
		return -1;
	}
	return 0;
}
Commit	Line	Data
83d290c5	1	// SPDX-License-Identifier: GPL-2.0+
4150f242 SL	2	/*
4150f242 SL	3	* Copyright 2013 Freescale Semiconductor, Inc.
4150f242 SL	4	*/
	5
	6	/* Power-One ZM7300 DPM */
	7	#include "zm7300.h"
f7ae49fc	8	#include <log.h>
4150f242 SL	9
	10	#define DPM_WP 0x96
	11	#define WRP_OPCODE 0x01
	12	#define WRM_OPCODE 0x02
	13	#define RRP_OPCODE 0x11
	14
	15	#define DPM_SUCCESS 0x01
	16	#define DPM_EXEC_FAIL 0x00
	17
	18	static const uint16_t hex_to_1_10mv[] = {
	19	5000,
	20	5125,
	21	5250,
	22	5375,
	23	5500,
	24	5625,
	25	5750,
	26	5875,
	27	6000,
	28	6125,
	29	6250,
	30	6375,
	31	6500,
	32	6625,
	33	6750,
	34	6875,
	35	7000,
	36	7125,
	37	7250,
	38	7375,
	39	7500,
	40	7625,
	41	7750,
	42	7875,
	43	8000,
	44	8125,
	45	8250,
	46	8375,
	47	8500,
	48	8625,
	49	8750,
	50	8875,
	51	9000,
	52	9125,
	53	9250,
	54	9375,
	55	9500, /* 0.95mV */
	56	9625,
	57	9750,
	58	9875,
	59	10000, /* 1.0V */
	60	10125,
	61	10250,
	62	10375,
	63	10500,
	64	10625,
	65	10750,
	66	10875,
	67	11000,
	68	11125,
	69	11250,
	70	11375,
	71	11500,
	72	11625,
73	11750,
74	11875,
75	12000,
76	12125,
77	12250,
78	12375,
79	0, /* reserved */
80	};
81
82
83	/* Read Data d from Register r of POL p */
84	u8 dpm_rrp(uchar r)
85	{
86	u8 ret[5];
87
88	ret[0] = RRP_OPCODE;
89	/* POL is 0 */
90	ret[1] = 0;
91	ret[2] = r;
92	i2c_read(I2C_DPM_ADDR, 0, -3, ret, 2);
93	if (ret[1] == DPM_SUCCESS) { /* the DPM returned success as status */
94	debug("RRP_OPCODE returned success data is %x\n", ret[0]);
95	return ret[0];
96	} else {
97	return -1;
98	}
99	}
100
101	/* Write Data d into DPM register r (RAM) */
102	int dpm_wrm(u8 r, u8 d)
103	{
104	u8 ret[5];
105
106	ret[0] = WRM_OPCODE;
107	ret[1] = r;
108	ret[2] = d;
109	i2c_read(I2C_DPM_ADDR, 0, -3, ret, 1);
110	if (ret[0] == DPM_SUCCESS) { /* the DPM returned success as status */
111	debug("WRM_OPCODE returned success data is %x\n", ret[0]);
112	return ret[0];
113	} else {
114	return -1;
115	}
116	}
117
118	/* Write Data d into Register r of POL(s) a */
119	int dpm_wrp(u8 r, u8 d)
120	{
121	u8 ret[7];
122
123	ret[0] = WRP_OPCODE;
124	/* only POL0 is present */
125	ret[1] = 0x01;
126	ret[2] = 0x00;
127	ret[3] = 0x00;
128	ret[4] = 0x00;
129	ret[5] = r;
130	ret[6] = d;
131	i2c_read(I2C_DPM_ADDR, 0, -7, ret, 1);
132	if (ret[0] == DPM_SUCCESS) { /* the DPM returned success as status */
133	debug("WRP_OPCODE returned success data is %x\n", ret[0]);
134	return 0;
135	} else {
136	return -1;
137	}
138	}
139
140	/* Uses the DPM command RRP */
141	u8 zm_read(uchar reg)
142	{
63a7578e	143	return dpm_rrp(reg);
4150f242 SL	144	}
	145
	146	/* ZM_write --
	147	Steps:
	148	a. Write data to the register
	149	b. Read data from register and compare to written value
	150	c. Return return_code & voltage_read
	151	*/
	152	u8 zm_write(u8 reg, u8 data)
	153	{
	154	u8 d;
	155
	156	/* write data to register */
	157	dpm_wrp(reg, data);
	158
	159	/* read register and compare to written value */
	160	d = dpm_rrp(reg);
	161	if (d != data) {
	162	printf("zm_write : Comparison register data failed\n");
	163	return -1;
	164	}
	165
	166	return d;
	167	}
	168
	169	/* zm_write_out_voltage
	170	* voltage in 1/10 mV
	171	*/
	172	int zm_write_voltage(int voltage)
	173	{
	174	u8 reg = 0x7, vid;
	175	uint16_t voltage_read;
	176	u8 ret;
	177
	178	vid = (voltage - 5000) / ZM_STEP;
	179
	180	ret = zm_write(reg, vid);
	181	if (ret != -1) {
	182	voltage_read = hex_to_1_10mv[ret];
	183	debug("voltage set to %dmV\n", voltage_read/10);
	184	return voltage_read;
	185	}
	186	return -1;
	187	}
	188
	189	/* zm_read_out_voltage
	190	* voltage in 1/10 mV
	191	*/
	192	int zm_read_voltage(void)
	193	{
	194	u8 reg = 0x7;
	195	u8 ret;
	196	int voltage;
	197
	198	ret = zm_read(reg);
	199	if (ret != -1) {
	200	voltage = hex_to_1_10mv[ret];
	201	debug("Voltage read is %dmV\n", voltage/10);
	202	return voltage;
	203	} else {
	204	return -1;
	205	}
	206	}
	207
208	int zm_disable_wp()
209	{
210	u8 new_wp_value;
211
212	/* Disable using Write-Protect register 0x96 */
213	new_wp_value = 0x8;
214	if ((dpm_wrm(DPM_WP, new_wp_value)) < 0) {
215	printf("Disable Write-Protect register failed\n");
216	return -1;
217	}
218	return 0;
219	}
220
221	int zm_enable_wp()
222	{
223	u8 orig_wp_value;
224	orig_wp_value = 0x0;
225
226	/* Enable using Write-Protect register 0x96 */
227	if ((dpm_wrm(DPM_WP, orig_wp_value)) < 0) {
228	printf("Enable Write-Protect register failed\n");
229	return -1;
230	}
231	return 0;
232	}
233