coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/it83xx/i2c.c

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2024-03-04 11:14:53 +01:00
/* Copyright 2015 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/* I2C module for Chrome EC */
#include "clock.h"
#include "common.h"
#include "console.h"
#include "gpio.h"
#include "hooks.h"
#include "i2c.h"
#include "registers.h"
#include "task.h"
#include "timer.h"
#include "util.h"
#define CPRINTS(format, args...) cprints(CC_I2C, format, ## args)
/* Default maximum time we allow for an I2C transfer */
#define I2C_TIMEOUT_DEFAULT_US (100 * MSEC)
enum enhanced_i2c_transfer_direct {
TX_DIRECT,
RX_DIRECT,
};
enum i2c_host_status {
/* Host busy */
HOSTA_HOBY = 0x01,
/* Finish Interrupt */
HOSTA_FINTR = 0x02,
/* Device error */
HOSTA_DVER = 0x04,
/* Bus error */
HOSTA_BSER = 0x08,
/* Fail */
HOSTA_FAIL = 0x10,
/* Not response ACK */
HOSTA_NACK = 0x20,
/* Time-out error */
HOSTA_TMOE = 0x40,
/* Byte done status */
HOSTA_BDS = 0x80,
/* Error bit is set */
HOSTA_ANY_ERROR = (HOSTA_DVER | HOSTA_BSER |
HOSTA_FAIL | HOSTA_NACK | HOSTA_TMOE),
/* W/C for next byte */
HOSTA_NEXT_BYTE = HOSTA_BDS,
/* W/C host status register */
HOSTA_ALL_WC_BIT = (HOSTA_FINTR | HOSTA_ANY_ERROR | HOSTA_BDS),
};
enum enhanced_i2c_host_status {
/* ACK receive */
E_HOSTA_ACK = 0x01,
/* Interrupt pending */
E_HOSTA_INTP = 0x02,
/* Read/Write */
E_HOSTA_RW = 0x04,
/* Time out error */
E_HOSTA_TMOE = 0x08,
/* Arbitration lost */
E_HOSTA_ARB = 0x10,
/* Bus busy */
E_HOSTA_BB = 0x20,
/* Address match */
E_HOSTA_AM = 0x40,
/* Byte done status */
E_HOSTA_BDS = 0x80,
/* time out or lost arbitration */
E_HOSTA_ANY_ERROR = (E_HOSTA_TMOE | E_HOSTA_ARB),
/* Byte transfer done and ACK receive */
E_HOSTA_BDS_AND_ACK = (E_HOSTA_BDS | E_HOSTA_ACK),
};
enum enhanced_i2c_ctl {
/* Hardware reset */
E_HW_RST = 0x01,
/* Stop */
E_STOP = 0x02,
/* Start & Repeat start */
E_START = 0x04,
/* Acknowledge */
E_ACK = 0x08,
/* State reset */
E_STS_RST = 0x10,
/* Mode select */
E_MODE_SEL = 0x20,
/* I2C interrupt enable */
E_INT_EN = 0x40,
/* 0 : Standard mode , 1 : Receive mode */
E_RX_MODE = 0x80,
/* State reset and hardware reset */
E_STS_AND_HW_RST = (E_STS_RST | E_HW_RST),
/* Generate start condition and transmit slave address */
E_START_ID = (E_INT_EN | E_MODE_SEL | E_ACK | E_START | E_HW_RST),
/* Generate stop condition */
E_FINISH = (E_INT_EN | E_MODE_SEL | E_ACK | E_STOP | E_HW_RST),
};
enum i2c_reset_cause {
I2C_RC_NO_IDLE_FOR_START = 1,
I2C_RC_TIMEOUT,
};
struct i2c_ch_freq {
int kpbs;
uint8_t freq_set;
};
static const struct i2c_ch_freq i2c_freq_select[] = {
{ 50, 1},
{ 100, 2},
{ 400, 3},
{ 1000, 4},
};
struct i2c_pin {
volatile uint8_t *pin_clk;
volatile uint8_t *pin_data;
volatile uint8_t *pin_clk_ctrl;
volatile uint8_t *pin_data_ctrl;
volatile uint8_t *mirror_clk;
volatile uint8_t *mirror_data;
uint8_t clk_mask;
uint8_t data_mask;
};
static const struct i2c_pin i2c_pin_regs[] = {
{ &IT83XX_GPIO_GPCRB3, &IT83XX_GPIO_GPCRB4,
&IT83XX_GPIO_GPDRB, &IT83XX_GPIO_GPDRB,
&IT83XX_GPIO_GPDMRB, &IT83XX_GPIO_GPDMRB,
0x08, 0x10},
{ &IT83XX_GPIO_GPCRC1, &IT83XX_GPIO_GPCRC2,
&IT83XX_GPIO_GPDRC, &IT83XX_GPIO_GPDRC,
&IT83XX_GPIO_GPDMRC, &IT83XX_GPIO_GPDMRC,
0x02, 0x04},
#ifdef CONFIG_IT83XX_SMCLK2_ON_GPC7
{ &IT83XX_GPIO_GPCRC7, &IT83XX_GPIO_GPCRF7,
&IT83XX_GPIO_GPDRC, &IT83XX_GPIO_GPDRF,
&IT83XX_GPIO_GPDMRC, &IT83XX_GPIO_GPDMRF,
0x80, 0x80},
#else
{ &IT83XX_GPIO_GPCRF6, &IT83XX_GPIO_GPCRF7,
&IT83XX_GPIO_GPDRF, &IT83XX_GPIO_GPDRF,
&IT83XX_GPIO_GPDMRF, &IT83XX_GPIO_GPDMRF,
0x40, 0x80},
#endif
{ &IT83XX_GPIO_GPCRH1, &IT83XX_GPIO_GPCRH2,
&IT83XX_GPIO_GPDRH, &IT83XX_GPIO_GPDRH,
&IT83XX_GPIO_GPDMRH, &IT83XX_GPIO_GPDMRH,
0x02, 0x04},
{ &IT83XX_GPIO_GPCRE0, &IT83XX_GPIO_GPCRE7,
&IT83XX_GPIO_GPDRE, &IT83XX_GPIO_GPDRE,
&IT83XX_GPIO_GPDMRE, &IT83XX_GPIO_GPDMRE,
0x01, 0x80},
{ &IT83XX_GPIO_GPCRA4, &IT83XX_GPIO_GPCRA5,
&IT83XX_GPIO_GPDRA, &IT83XX_GPIO_GPDRA,
&IT83XX_GPIO_GPDMRA, &IT83XX_GPIO_GPDMRA,
0x10, 0x20},
};
struct i2c_ctrl_t {
uint8_t irq;
enum clock_gate_offsets clock_gate;
int reg_shift;
};
const struct i2c_ctrl_t i2c_ctrl_regs[] = {
{IT83XX_IRQ_SMB_A, CGC_OFFSET_SMBA, -1},
{IT83XX_IRQ_SMB_B, CGC_OFFSET_SMBB, -1},
{IT83XX_IRQ_SMB_C, CGC_OFFSET_SMBC, -1},
{IT83XX_IRQ_SMB_D, CGC_OFFSET_SMBD, 3},
{IT83XX_IRQ_SMB_E, CGC_OFFSET_SMBE, 0},
{IT83XX_IRQ_SMB_F, CGC_OFFSET_SMBF, 1},
};
enum i2c_ch_status {
I2C_CH_NORMAL = 0,
I2C_CH_REPEAT_START,
I2C_CH_WAIT_READ,
I2C_CH_WAIT_NEXT_XFER,
};
/* I2C port state data */
struct i2c_port_data {
const uint8_t *out; /* Output data pointer */
int out_size; /* Output data to transfer, in bytes */
uint8_t *in; /* Input data pointer */
int in_size; /* Input data to transfer, in bytes */
int flags; /* Flags (I2C_XFER_*) */
int widx; /* Index into output data */
int ridx; /* Index into input data */
int err; /* Error code, if any */
uint8_t addr_8bit; /* address of device */
uint32_t timeout_us; /* Transaction timeout, or 0 to use default */
uint8_t freq; /* Frequency setting */
enum i2c_ch_status i2ccs;
/* Task waiting on port, or TASK_ID_INVALID if none. */
volatile int task_waiting;
};
static struct i2c_port_data pdata[I2C_PORT_COUNT];
static int i2c_ch_reg_shift(int p)
{
/*
* only enhanced port needs to be changed the parameter of registers
*/
ASSERT(p >= I2C_STANDARD_PORT_COUNT && p < I2C_PORT_COUNT);
/*
* The registers of i2c enhanced ports are not sequential.
* This routine transfers the i2c port number to related
* parameter of registers.
*
* IT83xx chip : i2c enhanced ports - channel D,E,F
* channel D registers : 0x3680 ~ 0x36FF
* channel E registers : 0x3500 ~ 0x357F
* channel F registers : 0x3580 ~ 0x35FF
*/
return i2c_ctrl_regs[p].reg_shift;
}
static void i2c_reset(int p, int cause)
{
int p_ch;
if (p < I2C_STANDARD_PORT_COUNT) {
/* bit1, kill current transaction. */
IT83XX_SMB_HOCTL(p) = 0x2;
IT83XX_SMB_HOCTL(p) = 0;
/* W/C host status register */
IT83XX_SMB_HOSTA(p) = HOSTA_ALL_WC_BIT;
} else {
/* Shift register */
p_ch = i2c_ch_reg_shift(p);
/* State reset and hardware reset */
IT83XX_I2C_CTR(p_ch) = E_STS_AND_HW_RST;
}
CPRINTS("I2C ch%d reset cause %d", p, cause);
}
static void i2c_r_last_byte(int p)
{
struct i2c_port_data *pd = pdata + p;
/*
* bit5, The firmware shall write 1 to this bit
* when the next byte will be the last byte for i2c read.
*/
if ((pd->flags & I2C_XFER_STOP) && (pd->ridx == pd->in_size - 1))
IT83XX_SMB_HOCTL(p) |= 0x20;
}
static void i2c_w2r_change_direction(int p)
{
/* I2C switch direction */
if (IT83XX_SMB_HOCTL2(p) & 0x08) {
i2c_r_last_byte(p);
IT83XX_SMB_HOSTA(p) = HOSTA_NEXT_BYTE;
} else {
/*
* bit2, I2C switch direction wait.
* bit3, I2C switch direction enable.
*/
IT83XX_SMB_HOCTL2(p) |= 0x0C;
IT83XX_SMB_HOSTA(p) = HOSTA_NEXT_BYTE;
i2c_r_last_byte(p);
IT83XX_SMB_HOCTL2(p) &= ~0x04;
}
}
static void i2c_pio_trans_data(int p, enum enhanced_i2c_transfer_direct direct,
uint8_t data, int first_byte)
{
struct i2c_port_data *pd = pdata + p;
int p_ch;
int nack = 0;
/* Shift register */
p_ch = i2c_ch_reg_shift(p);
if (first_byte) {
/* First byte must be slave address. */
IT83XX_I2C_DTR(p_ch) =
data | (direct == RX_DIRECT ? BIT(0) : 0);
/* start or repeat start signal. */
IT83XX_I2C_CTR(p_ch) = E_START_ID;
} else {
if (direct == TX_DIRECT)
/* Transmit data */
IT83XX_I2C_DTR(p_ch) = data;
else {
/*
* Receive data.
* Last byte should be NACK in the end of read cycle
*/
if (((pd->ridx + 1) == pd->in_size) &&
(pd->flags & I2C_XFER_STOP))
nack = 1;
}
/* Set hardware reset to start next transmission */
IT83XX_I2C_CTR(p_ch) =
E_INT_EN | E_MODE_SEL | E_HW_RST | (nack ? 0 : E_ACK);
}
}
static int i2c_tran_write(int p)
{
struct i2c_port_data *pd = pdata + p;
if (pd->flags & I2C_XFER_START) {
/* i2c enable */
IT83XX_SMB_HOCTL2(p) = 0x13;
/*
* bit0, Direction of the host transfer.
* bit[1:7}, Address of the targeted slave.
*/
IT83XX_SMB_TRASLA(p) = pd->addr_8bit;
/* Send first byte */
IT83XX_SMB_HOBDB(p) = *(pd->out++);
pd->widx++;
/* clear start flag */
pd->flags &= ~I2C_XFER_START;
/*
* bit0, Host interrupt enable.
* bit[2:4}, Extend command.
* bit6, start.
*/
IT83XX_SMB_HOCTL(p) = 0x5D;
} else {
/* Host has completed the transmission of a byte */
if (IT83XX_SMB_HOSTA(p) & HOSTA_BDS) {
if (pd->widx < pd->out_size) {
/* Send next byte */
IT83XX_SMB_HOBDB(p) = *(pd->out++);
pd->widx++;
/* W/C byte done for next byte */
IT83XX_SMB_HOSTA(p) = HOSTA_NEXT_BYTE;
if (pd->i2ccs == I2C_CH_REPEAT_START) {
pd->i2ccs = I2C_CH_NORMAL;
task_enable_irq(i2c_ctrl_regs[p].irq);
}
} else {
/* done */
pd->out_size = 0;
if (pd->in_size > 0) {
/* write to read */
i2c_w2r_change_direction(p);
} else {
if (pd->flags & I2C_XFER_STOP) {
/* set I2C_EN = 0 */
IT83XX_SMB_HOCTL2(p) = 0x11;
/* W/C byte done for finish */
IT83XX_SMB_HOSTA(p) =
HOSTA_NEXT_BYTE;
} else {
pd->i2ccs = I2C_CH_REPEAT_START;
return 0;
}
}
}
}
}
return 1;
}
static int i2c_tran_read(int p)
{
struct i2c_port_data *pd = pdata + p;
if (pd->flags & I2C_XFER_START) {
/* i2c enable */
IT83XX_SMB_HOCTL2(p) = 0x13;
/*
* bit0, Direction of the host transfer.
* bit[1:7}, Address of the targeted slave.
*/
IT83XX_SMB_TRASLA(p) = pd->addr_8bit | 0x01;
/* clear start flag */
pd->flags &= ~I2C_XFER_START;
/*
* bit0, Host interrupt enable.
* bit[2:4}, Extend command.
* bit5, The firmware shall write 1 to this bit
* when the next byte will be the last byte.
* bit6, start.
*/
if ((1 == pd->in_size) && (pd->flags & I2C_XFER_STOP))
IT83XX_SMB_HOCTL(p) = 0x7D;
else
IT83XX_SMB_HOCTL(p) = 0x5D;
} else {
if ((pd->i2ccs == I2C_CH_REPEAT_START) ||
(pd->i2ccs == I2C_CH_WAIT_READ)) {
if (pd->i2ccs == I2C_CH_REPEAT_START) {
/* write to read */
i2c_w2r_change_direction(p);
} else {
/* For last byte */
i2c_r_last_byte(p);
/* W/C for next byte */
IT83XX_SMB_HOSTA(p) = HOSTA_NEXT_BYTE;
}
pd->i2ccs = I2C_CH_NORMAL;
task_enable_irq(i2c_ctrl_regs[p].irq);
} else if (IT83XX_SMB_HOSTA(p) & HOSTA_BDS) {
if (pd->ridx < pd->in_size) {
/* To get received data. */
*(pd->in++) = IT83XX_SMB_HOBDB(p);
pd->ridx++;
/* For last byte */
i2c_r_last_byte(p);
/* done */
if (pd->ridx == pd->in_size) {
pd->in_size = 0;
if (pd->flags & I2C_XFER_STOP) {
/* W/C for finish */
IT83XX_SMB_HOSTA(p) =
HOSTA_NEXT_BYTE;
} else {
pd->i2ccs = I2C_CH_WAIT_READ;
return 0;
}
} else {
/* W/C for next byte */
IT83XX_SMB_HOSTA(p) = HOSTA_NEXT_BYTE;
}
}
}
}
return 1;
}
static void enhanced_i2c_start(int p)
{
/* Shift register */
int p_ch = i2c_ch_reg_shift(p);
/* State reset and hardware reset */
IT83XX_I2C_CTR(p_ch) = E_STS_AND_HW_RST;
/* Set i2c frequency */
IT83XX_I2C_PSR(p_ch) = pdata[p].freq;
IT83XX_I2C_HSPR(p_ch) = pdata[p].freq;
/*
* Set time out register.
* I2C D/E/F clock/data low timeout.
*/
IT83XX_I2C_TOR(p_ch) = I2C_CLK_LOW_TIMEOUT;
/* bit1: Enable enhanced i2c module */
IT83XX_I2C_CTR1(p_ch) = BIT(1);
}
static int enhanced_i2c_tran_write(int p)
{
struct i2c_port_data *pd = pdata + p;
uint8_t out_data;
int p_ch;
/* Shift register */
p_ch = i2c_ch_reg_shift(p);
if (pd->flags & I2C_XFER_START) {
/* Clear start bit */
pd->flags &= ~I2C_XFER_START;
enhanced_i2c_start(p);
/* Send ID */
i2c_pio_trans_data(p, TX_DIRECT, pd->addr_8bit, 1);
} else {
/* Host has completed the transmission of a byte */
if (pd->widx < pd->out_size) {
out_data = *(pd->out++);
pd->widx++;
/* Send Byte */
i2c_pio_trans_data(p, TX_DIRECT, out_data, 0);
if (pd->i2ccs == I2C_CH_WAIT_NEXT_XFER) {
pd->i2ccs = I2C_CH_NORMAL;
task_enable_irq(i2c_ctrl_regs[p].irq);
}
} else {
/* done */
pd->out_size = 0;
if (pd->in_size > 0) {
/* Write to read protocol */
pd->i2ccs = I2C_CH_REPEAT_START;
/* Repeat Start */
i2c_pio_trans_data(p, RX_DIRECT,
pd->addr_8bit, 1);
} else {
if (pd->flags & I2C_XFER_STOP) {
IT83XX_I2C_CTR(p_ch) = E_FINISH;
/* wait for stop bit interrupt*/
return 1;
}
/* Direct write with direct read */
pd->i2ccs = I2C_CH_WAIT_NEXT_XFER;
return 0;
}
}
}
return 1;
}
static int enhanced_i2c_tran_read(int p)
{
struct i2c_port_data *pd = pdata + p;
uint8_t in_data = 0;
int p_ch;
/* Shift register */
p_ch = i2c_ch_reg_shift(p);
if (pd->flags & I2C_XFER_START) {
/* clear start flag */
pd->flags &= ~I2C_XFER_START;
enhanced_i2c_start(p);
/* Direct read */
pd->i2ccs = I2C_CH_WAIT_READ;
/* Send ID */
i2c_pio_trans_data(p, RX_DIRECT, pd->addr_8bit, 1);
} else {
if (pd->i2ccs) {
if (pd->i2ccs == I2C_CH_REPEAT_START) {
pd->i2ccs = I2C_CH_NORMAL;
/* Receive data */
i2c_pio_trans_data(p, RX_DIRECT, in_data, 0);
} else if (pd->i2ccs == I2C_CH_WAIT_READ) {
pd->i2ccs = I2C_CH_NORMAL;
/* Receive data */
i2c_pio_trans_data(p, RX_DIRECT, in_data, 0);
/* Turn on irq before next direct read */
task_enable_irq(i2c_ctrl_regs[p].irq);
} else {
/* Write to read */
pd->i2ccs = I2C_CH_WAIT_READ;
/* Send ID */
i2c_pio_trans_data(p, RX_DIRECT,
pd->addr_8bit, 1);
task_enable_irq(i2c_ctrl_regs[p].irq);
}
} else {
if (pd->ridx < pd->in_size) {
/* read data */
*(pd->in++) = IT83XX_I2C_DRR(p_ch);
pd->ridx++;
/* done */
if (pd->ridx == pd->in_size) {
pd->in_size = 0;
if (pd->flags & I2C_XFER_STOP) {
pd->i2ccs = I2C_CH_NORMAL;
IT83XX_I2C_CTR(p_ch) = E_FINISH;
/* wait for stop bit interrupt*/
return 1;
}
/* End the transaction */
pd->i2ccs = I2C_CH_WAIT_READ;
return 0;
}
/* read next byte */
i2c_pio_trans_data(p, RX_DIRECT, in_data, 0);
}
}
}
return 1;
}
static int enhanced_i2c_error(int p)
{
struct i2c_port_data *pd = pdata + p;
/* Shift register */
int p_ch = i2c_ch_reg_shift(p);
int i2c_str = IT83XX_I2C_STR(p_ch);
if (i2c_str & E_HOSTA_ANY_ERROR) {
pd->err = i2c_str & E_HOSTA_ANY_ERROR;
/* device does not respond ACK */
} else if ((i2c_str & E_HOSTA_BDS_AND_ACK) == E_HOSTA_BDS) {
if (IT83XX_I2C_CTR(p_ch) & E_ACK)
pd->err = E_HOSTA_ACK;
}
return pd->err;
}
static int i2c_transaction(int p)
{
struct i2c_port_data *pd = pdata + p;
int p_ch;
if (p < I2C_STANDARD_PORT_COUNT) {
/* any error */
if (IT83XX_SMB_HOSTA(p) & HOSTA_ANY_ERROR) {
pd->err = (IT83XX_SMB_HOSTA(p) & HOSTA_ANY_ERROR);
} else {
/* i2c write */
if (pd->out_size)
return i2c_tran_write(p);
/* i2c read */
else if (pd->in_size)
return i2c_tran_read(p);
/* wait finish */
if (!(IT83XX_SMB_HOSTA(p) & HOSTA_FINTR))
return 1;
}
/* W/C */
IT83XX_SMB_HOSTA(p) = HOSTA_ALL_WC_BIT;
/* disable the SMBus host interface */
IT83XX_SMB_HOCTL2(p) = 0x00;
} else {
/* no error */
if (!(enhanced_i2c_error(p))) {
/* i2c write */
if (pd->out_size)
return enhanced_i2c_tran_write(p);
/* i2c read */
else if (pd->in_size)
return enhanced_i2c_tran_read(p);
}
p_ch = i2c_ch_reg_shift(p);
IT83XX_I2C_CTR(p_ch) = E_STS_AND_HW_RST;
IT83XX_I2C_CTR1(p_ch) = 0;
}
/* done doing work */
return 0;
}
int i2c_is_busy(int port)
{
int p_ch;
if (port < I2C_STANDARD_PORT_COUNT)
return (IT83XX_SMB_HOSTA(port) &
(HOSTA_HOBY | HOSTA_ALL_WC_BIT));
p_ch = i2c_ch_reg_shift(port);
return (IT83XX_I2C_STR(p_ch) & E_HOSTA_BB);
}
int chip_i2c_xfer(int port, uint16_t slave_addr_flags,
const uint8_t *out, int out_size,
uint8_t *in, int in_size, int flags)
{
struct i2c_port_data *pd = pdata + port;
uint32_t events = 0;
if (out_size == 0 && in_size == 0)
return EC_SUCCESS;
if (pd->i2ccs) {
if ((flags & I2C_XFER_SINGLE) == I2C_XFER_SINGLE)
flags &= ~I2C_XFER_START;
}
/* Copy data to port struct */
pd->out = out;
pd->out_size = out_size;
pd->in = in;
pd->in_size = in_size;
pd->flags = flags;
pd->widx = 0;
pd->ridx = 0;
pd->err = 0;
pd->addr_8bit = I2C_GET_ADDR(slave_addr_flags) << 1;
/* Make sure we're in a good state to start */
if ((flags & I2C_XFER_START) && (i2c_is_busy(port)
|| (i2c_get_line_levels(port) != I2C_LINE_IDLE))) {
/* Attempt to unwedge the port. */
i2c_unwedge(port);
/* reset i2c port */
i2c_reset(port, I2C_RC_NO_IDLE_FOR_START);
}
pd->task_waiting = task_get_current();
if (pd->flags & I2C_XFER_START) {
pd->i2ccs = I2C_CH_NORMAL;
/* enable i2c interrupt */
task_clear_pending_irq(i2c_ctrl_regs[port].irq);
task_enable_irq(i2c_ctrl_regs[port].irq);
}
/* Start transaction */
i2c_transaction(port);
/* Wait for transfer complete or timeout */
events = task_wait_event_mask(TASK_EVENT_I2C_IDLE, pd->timeout_us);
/* disable i2c interrupt */
task_disable_irq(i2c_ctrl_regs[port].irq);
pd->task_waiting = TASK_ID_INVALID;
/* Handle timeout */
if (!(events & TASK_EVENT_I2C_IDLE)) {
pd->err = EC_ERROR_TIMEOUT;
/* reset i2c port */
i2c_reset(port, I2C_RC_TIMEOUT);
}
/* reset i2c channel status */
if (pd->err)
pd->i2ccs = I2C_CH_NORMAL;
return pd->err;
}
int i2c_raw_get_scl(int port)
{
enum gpio_signal g;
if (get_scl_from_i2c_port(port, &g) == EC_SUCCESS)
return !!(*i2c_pin_regs[port].mirror_clk &
i2c_pin_regs[port].clk_mask);
/* If no SCL pin defined for this port, then return 1 to appear idle */
return 1;
}
int i2c_raw_get_sda(int port)
{
enum gpio_signal g;
if (get_sda_from_i2c_port(port, &g) == EC_SUCCESS)
return !!(*i2c_pin_regs[port].mirror_data &
i2c_pin_regs[port].data_mask);
/* If no SDA pin defined for this port, then return 1 to appear idle */
return 1;
}
int i2c_get_line_levels(int port)
{
int pin_sts = 0;
if (port < I2C_STANDARD_PORT_COUNT)
return IT83XX_SMB_SMBPCTL(port) & 0x03;
if (*i2c_pin_regs[port].mirror_clk & i2c_pin_regs[port].clk_mask)
pin_sts |= I2C_LINE_SCL_HIGH;
if (*i2c_pin_regs[port].mirror_data & i2c_pin_regs[port].data_mask)
pin_sts |= I2C_LINE_SDA_HIGH;
return pin_sts;
}
void i2c_set_timeout(int port, uint32_t timeout)
{
pdata[port].timeout_us = timeout ? timeout : I2C_TIMEOUT_DEFAULT_US;
}
void i2c_interrupt(int port)
{
int id = pdata[port].task_waiting;
/* Clear the interrupt status */
task_clear_pending_irq(i2c_ctrl_regs[port].irq);
/* If no task is waiting, just return */
if (id == TASK_ID_INVALID)
return;
/* If done doing work, wake up the task waiting for the transfer */
if (!i2c_transaction(port)) {
task_disable_irq(i2c_ctrl_regs[port].irq);
task_set_event(id, TASK_EVENT_I2C_IDLE, 0);
}
}
static void i2c_freq_changed(void)
{
int i, f, clk_div, psr, freq;
int p_ch;
/*
* Standard I2C Channels
*/
for (i = 0; i < i2c_ports_used; i++) {
freq = i2c_ports[i].kbps;
if (i2c_ports[i].port < I2C_STANDARD_PORT_COUNT) {
for (f = ARRAY_SIZE(i2c_freq_select) - 1; f >= 0; f--) {
if (freq >= i2c_freq_select[f].kpbs) {
IT83XX_SMB_SCLKTS(i2c_ports[i].port) =
i2c_freq_select[f].freq_set;
break;
}
}
} else {
p_ch = i2c_ch_reg_shift(i2c_ports[i].port);
/*
* Let psr(Prescale) = IT83XX_I2C_PSR(p_ch)
* Then, 1 SCL cycle = 2 x (psr + 2) x SMBus clock cycle
* SMBus clock = PLL_CLOCK / clk_div
* SMBus clock cycle = 1 / SMBus clock
* 1 SCL cycle = 1 / (1000 x freq)
* 1 / (1000 x freq) =
* 2 x (psr + 2) x (1 / (PLL_CLOCK / clk_div))
* psr = ((PLL_CLOCK / clk_div) x
* (1 / (1000 x freq)) x (1 / 2)) - 2
*/
if (freq) {
/* Get SMBus clock divide value */
clk_div = (IT83XX_ECPM_SCDCR2 & 0x0F) + 1;
/* Calculate PSR value */
psr = (PLL_CLOCK /
(clk_div * (2 * 1000 * freq))) - 2;
/* Set psr value under 0xFD */
if (psr > 0xFD)
psr = 0xFD;
/* Set I2C Speed */
IT83XX_I2C_PSR(p_ch) = (psr & 0xFF);
IT83XX_I2C_HSPR(p_ch) = (psr & 0xFF);
/* Backup */
pdata[i2c_ports[i].port].freq = (psr & 0xFF);
}
}
}
/* This field defines the SMCLK0/1/2 clock/data low timeout. */
IT83XX_SMB_25MS = I2C_CLK_LOW_TIMEOUT;
}
DECLARE_HOOK(HOOK_FREQ_CHANGE, i2c_freq_changed, HOOK_PRIO_DEFAULT);
static void i2c_init(void)
{
int i, p, p_ch;
/* Configure GPIOs */
gpio_config_module(MODULE_I2C, 1);
#ifdef CONFIG_IT83XX_SMCLK2_ON_GPC7
/* bit7, 0: SMCLK2 is located on GPF6, 1: SMCLK2 is located on GPC7 */
IT83XX_GPIO_GRC7 |= 0x80;
#endif
/* Enable I2C function. */
for (i = 0; i < i2c_ports_used; i++) {
/* I2c port mapping. */
p = i2c_ports[i].port;
clock_enable_peripheral(i2c_ctrl_regs[p].clock_gate, 0, 0);
if (p < I2C_STANDARD_PORT_COUNT) {
/*
* bit0, The SMBus host interface is enabled.
* bit1, Enable to communicate with I2C device
* and support I2C-compatible cycles.
* bit4, This bit controls the reset mechanism
* of SMBus master to handle the SMDAT
* line low if 25ms reg timeout.
*/
IT83XX_SMB_HOCTL2(p) = 0x11;
/*
* bit1, Kill SMBus host transaction.
* bit0, Enable the interrupt for the master interface.
*/
IT83XX_SMB_HOCTL(p) = 0x03;
IT83XX_SMB_HOCTL(p) = 0x01;
/* W/C host status register */
IT83XX_SMB_HOSTA(p) = HOSTA_ALL_WC_BIT;
IT83XX_SMB_HOCTL2(p) = 0x00;
} else {
/* Shift register */
p_ch = i2c_ch_reg_shift(p);
switch (p) {
case IT83XX_I2C_CH_D:
#ifndef CONFIG_UART_HOST
/* Enable SMBus D channel */
IT83XX_GPIO_GRC2 |= 0x20;
#endif
break;
case IT83XX_I2C_CH_E:
/* Enable SMBus E channel */
IT83XX_GCTRL_PMER1 |= 0x01;
break;
case IT83XX_I2C_CH_F:
/* Enable SMBus F channel */
IT83XX_GCTRL_PMER1 |= 0x02;
break;
}
/* Software reset */
IT83XX_I2C_DHTR(p_ch) |= 0x80;
IT83XX_I2C_DHTR(p_ch) &= 0x7F;
/* State reset and hardware reset */
IT83XX_I2C_CTR(p_ch) = E_STS_AND_HW_RST;
/* bit1, Module enable */
IT83XX_I2C_CTR1(p_ch) = 0;
}
pdata[i].task_waiting = TASK_ID_INVALID;
}
i2c_freq_changed();
for (i = 0; i < I2C_PORT_COUNT; i++) {
/* Use default timeout */
i2c_set_timeout(i, 0);
}
}
DECLARE_HOOK(HOOK_INIT, i2c_init, HOOK_PRIO_INIT_I2C);