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|
/*
* This file is part of the coreboot project.
*
* (C) Copyright 2002
* David Mueller, ELSOFT AG, d.mueller@elsoft.ch
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <device/mmio.h>
#include <assert.h>
#include <console/console.h>
#include <delay.h>
#include <device/i2c_simple.h>
#include <soc/clk.h>
#include <soc/i2c.h>
#include <soc/periph.h>
#include <soc/pinmux.h>
#include <stddef.h>
#include <timer.h>
struct __packed i2c_regs
{
uint8_t con;
uint8_t _1[3];
uint8_t stat;
uint8_t _2[3];
uint8_t add;
uint8_t _3[3];
uint8_t ds;
uint8_t _4[3];
uint8_t lc;
uint8_t _5[3];
};
struct __packed hsi2c_regs
{
uint32_t usi_ctl;
uint32_t usi_fifo_ctl;
uint32_t usi_trailing_ctl;
uint32_t usi_clk_ctl;
uint32_t usi_clk_slot;
uint32_t spi_ctl;
uint32_t uart_ctl;
uint32_t res1;
uint32_t usi_int_en;
uint32_t usi_int_stat;
uint32_t modem_stat;
uint32_t error_stat;
uint32_t usi_fifo_stat;
uint32_t usi_txdata;
uint32_t usi_rxdata;
uint32_t res2;
uint32_t i2c_conf;
uint32_t i2c_auto_conf;
uint32_t i2c_timeout;
uint32_t i2c_manual_cmd;
uint32_t i2c_trans_status;
uint32_t i2c_timing_hs1;
uint32_t i2c_timing_hs2;
uint32_t i2c_timing_hs3;
uint32_t i2c_timing_fs1;
uint32_t i2c_timing_fs2;
uint32_t i2c_timing_fs3;
uint32_t i2c_timing_sla;
uint32_t i2c_addr;
};
check_member(hsi2c_regs, i2c_addr, 0x70);
struct i2c_bus
{
int bus_num;
struct i2c_regs *regs;
enum periph_id periph_id;
struct hsi2c_regs *hsregs;
int is_highspeed; /* High speed type, rather than I2C */
int id;
unsigned int clk_cycle;
unsigned int clk_div;
};
static struct i2c_bus i2c_busses[] = {
{
.bus_num = 0,
.regs = (void *)0x12c60000,
.periph_id = PERIPH_ID_I2C0,
},
{
.bus_num = 1,
.regs = (void *)0x12c70000,
.periph_id = PERIPH_ID_I2C1,
},
{
.bus_num = 2,
.regs = (void *)0x12c80000,
.periph_id = PERIPH_ID_I2C2,
},
{
.bus_num = 3,
.regs = (void *)0x12c90000,
.periph_id = PERIPH_ID_I2C3,
},
/* I2C4-I2C10 are part of the USI block */
{
.bus_num = 4,
.hsregs = (void *)0x12ca0000,
.periph_id = PERIPH_ID_I2C4,
.is_highspeed = 1,
},
{
.bus_num = 5,
.hsregs = (void *)0x12cb0000,
.periph_id = PERIPH_ID_I2C5,
.is_highspeed = 1,
},
{
.bus_num = 6,
.hsregs = (void *)0x12cc0000,
.periph_id = PERIPH_ID_I2C6,
.is_highspeed = 1,
},
{
.bus_num = 7,
.hsregs = (void *)0x12cd0000,
.periph_id = PERIPH_ID_I2C7,
.is_highspeed = 1,
},
{
.bus_num = 8,
.hsregs = (void *)0x12e00000,
.periph_id = PERIPH_ID_I2C8,
.is_highspeed = 1,
},
{
.bus_num = 9,
.hsregs = (void *)0x12e10000,
.periph_id = PERIPH_ID_I2C9,
.is_highspeed = 1,
},
{
.bus_num = 10,
.hsregs = (void *)0x12e20000,
.periph_id = PERIPH_ID_I2C10,
.is_highspeed = 1,
},
};
// I2C_CTL
enum {
Hsi2cFuncModeI2c = 1 << 0,
Hsi2cMaster = 1 << 3,
Hsi2cRxchon = 1 << 6,
Hsi2cTxchon = 1 << 7,
Hsi2cSwRst = 1 << 31
};
// I2C_FIFO_STAT
enum {
Hsi2cTxFifoLevel = 0x7f << 0,
Hsi2cTxFifoFull = 1 << 7,
Hsi2cTxFifoEmpty = 1 << 8,
Hsi2cRxFifoLevel = 0x7f << 16,
Hsi2cRxFifoFull = 1 << 23,
Hsi2cRxFifoEmpty = 1 << 24
};
// I2C_FIFO_CTL
enum {
Hsi2cRxfifoEn = 1 << 0,
Hsi2cTxfifoEn = 1 << 1,
Hsi2cTxfifoTriggerLevel = 0x20 << 16,
Hsi2cRxfifoTriggerLevel = 0x20 << 4
};
// I2C_TRAILING_CTL
enum {
Hsi2cTrailingCount = 0xff
};
// I2C_INT_EN
enum {
Hsi2cIntTxAlmostemptyEn = 1 << 0,
Hsi2cIntRxAlmostfullEn = 1 << 1,
Hsi2cIntTrailingEn = 1 << 6,
Hsi2cIntI2cEn = 1 << 9
};
// I2C_CONF
enum {
Hsi2cAutoMode = 1 << 31,
Hsi2c10bitAddrMode = 1 << 30,
Hsi2cHsMode = 1 << 29
};
// I2C_AUTO_CONF
enum {
Hsi2cReadWrite = 1 << 16,
Hsi2cStopAfterTrans = 1 << 17,
Hsi2cMasterRun = 1 << 31
};
// I2C_TIMEOUT
enum {
Hsi2cTimeoutEn = 1 << 31
};
// I2C_TRANS_STATUS
enum {
Hsi2cMasterBusy = 1 << 17,
Hsi2cSlaveBusy = 1 << 16,
Hsi2cTimeoutAuto = 1 << 4,
Hsi2cNoDev = 1 << 3,
Hsi2cNoDevAck = 1 << 2,
Hsi2cTransAbort = 1 << 1,
Hsi2cTransDone = 1 << 0
};
#define HSI2C_SLV_ADDR_MAS(x) ((x & 0x3ff) << 10)
enum {
Hsi2cTimeout = 100
};
enum {
I2cConIntPending = 0x1 << 4,
I2cConIntEn = 0x1 << 5,
I2cConAckGen = 0x1 << 7
};
enum {
I2cStatAck = 0x1 << 0,
I2cStatAddrZero = 0x1 << 1,
I2cStatAddrSlave = 0x1 << 2,
I2cStatArb = 0x1 << 3,
I2cStatEnable = 0x1 << 4,
I2cStatStartStop = 0x1 << 5,
I2cStatBusy = 0x1 << 5,
I2cStatModeMask = 0x3 << 6,
I2cStatSlaveRecv = 0x0 << 6,
I2cStatSlaveXmit = 0x1 << 6,
I2cStatMasterRecv = 0x2 << 6,
I2cStatMasterXmit = 0x3 << 6
};
static int hsi2c_get_clk_details(struct i2c_bus *i2c, int *div, int *cycle,
unsigned int op_clk)
{
struct hsi2c_regs *regs = i2c->hsregs;
unsigned long clkin = clock_get_periph_rate(i2c->periph_id);
/*
* FPCLK / FI2C =
* (CLK_DIV + 1) * (TSCLK_L + TSCLK_H + 2) + 8 + 2 * FLT_CYCLE
* temp0 = (CLK_DIV + 1) * (TSCLK_L + TSCLK_H + 2)
* temp1 = (TSCLK_L + TSCLK_H + 2)
*/
uint32_t flt_cycle = (read32(®s->i2c_conf) >> 16) & 0x7;
int temp = (clkin / op_clk) - 8 - 2 * flt_cycle;
// CLK_DIV max is 256.
int i;
for (i = 0; i < 256; i++) {
int period = temp / (i + 1) - 2;
if (period < 512 && period >= 2) {
*cycle = period;
*div = i;
return 0;
}
}
printk(BIOS_ERR, "%s: Failed to find timing parameters.\n", __func__);
return -1;
}
static void hsi2c_ch_init(struct i2c_bus *i2c, unsigned int frequency)
{
struct hsi2c_regs *regs = i2c->hsregs;
int div, cycle;
if (hsi2c_get_clk_details(i2c, &div, &cycle, frequency))
return;
uint32_t sr_release;
sr_release = cycle;
uint32_t scl_l, scl_h, start_su, start_hd, stop_su;
scl_l = scl_h = start_su = start_hd = stop_su = cycle / 2;
uint32_t data_su, data_hd;
data_su = data_hd = cycle / 4;
uint32_t timing_fs1 = start_su << 24 | start_hd << 16 | stop_su << 8;
uint32_t timing_fs2 = data_su << 24 | scl_l << 8 | scl_h << 0;
uint32_t timing_fs3 = div << 16 | sr_release << 0;
uint32_t timing_sla = data_hd << 0;
// Currently operating in fast speed mode.
write32(®s->i2c_timing_fs1, timing_fs1);
write32(®s->i2c_timing_fs2, timing_fs2);
write32(®s->i2c_timing_fs3, timing_fs3);
write32(®s->i2c_timing_sla, timing_sla);
// Clear to enable timeout.
write32(®s->i2c_timeout,
read32(®s->i2c_timeout) & ~Hsi2cTimeoutEn);
write32(®s->usi_trailing_ctl, Hsi2cTrailingCount);
write32(®s->usi_fifo_ctl, Hsi2cRxfifoEn | Hsi2cTxfifoEn);
write32(®s->i2c_conf, read32(®s->i2c_conf) | Hsi2cAutoMode);
}
static void hsi2c_reset(struct i2c_bus *i2c)
{
struct hsi2c_regs *regs = i2c->hsregs;
// Set and clear the bit for reset.
write32(®s->usi_ctl, read32(®s->usi_ctl) | Hsi2cSwRst);
write32(®s->usi_ctl, read32(®s->usi_ctl) & ~Hsi2cSwRst);
/* FIXME: This just assumes 100KHz as a default bus freq */
hsi2c_ch_init(i2c, 100000);
}
static void i2c_ch_init(struct i2c_bus *i2c, int speed)
{
struct i2c_regs *regs = i2c->regs;
unsigned long freq, pres = 16, div;
unsigned long val;
freq = clock_get_periph_rate(i2c->periph_id);
// Calculate prescaler and divisor values.
if ((freq / pres / (16 + 1)) > speed)
/* set prescaler to 512 */
pres = 512;
div = 0;
while ((freq / pres / (div + 1)) > speed)
div++;
// Set prescaler, divisor according to freq, also set ACKGEN, IRQ.
val = (div & 0x0f) | 0xa0 | ((pres == 512) ? 0x40 : 0);
write32(®s->con, val);
// Init to SLAVE RECEIVE mode and clear I2CADDn.
write32(®s->stat, 0);
write32(®s->add, 0);
// program Master Transmit (and implicit STOP).
write32(®s->stat, I2cStatMasterXmit | I2cStatEnable);
}
void i2c_init(unsigned int bus, int speed, int slaveadd)
{
struct i2c_bus *i2c = &i2c_busses[bus];
if (i2c->is_highspeed) {
hsi2c_reset(i2c);
hsi2c_ch_init(i2c, speed);
} else {
i2c_ch_init(i2c, speed);
}
}
/*
* Check whether the transfer is complete.
* Return values:
* 0 - transfer not done
* 1 - transfer finished successfully
* -1 - transfer failed
*/
static int hsi2c_check_transfer(struct hsi2c_regs *regs)
{
uint32_t status = read32(®s->i2c_trans_status);
if (status & (Hsi2cTransAbort | Hsi2cNoDevAck |
Hsi2cNoDev | Hsi2cTimeoutAuto)) {
if (status & Hsi2cTransAbort)
printk(BIOS_ERR,
"%s: Transaction aborted.\n", __func__);
if (status & Hsi2cNoDevAck)
printk(BIOS_ERR,
"%s: No ack from device.\n", __func__);
if (status & Hsi2cNoDev)
printk(BIOS_ERR,
"%s: No response from device.\n", __func__);
if (status & Hsi2cTimeoutAuto)
printk(BIOS_ERR,
"%s: Transaction time out.\n", __func__);
return -1;
}
return !(status & Hsi2cMasterBusy);
}
/*
* Wait for the transfer to finish.
* Return values:
* 0 - transfer not done
* 1 - transfer finished successfully
* -1 - transfer failed
*/
static int hsi2c_wait_for_transfer(struct hsi2c_regs *i2c)
{
struct stopwatch sw;
stopwatch_init_msecs_expire(&sw, Hsi2cTimeout);
while (!stopwatch_expired(&sw)) {
int ret = hsi2c_check_transfer(i2c);
if (ret)
return ret;
}
return 0;
}
static int hsi2c_senddata(struct hsi2c_regs *regs, const uint8_t *data, int len)
{
while (!hsi2c_check_transfer(regs) && len) {
if (!(read32(®s->usi_fifo_stat) & Hsi2cTxFifoFull)) {
write32(®s->usi_txdata, *data++);
len--;
}
}
return len ? -1 : 0;
}
static int hsi2c_recvdata(struct hsi2c_regs *regs, uint8_t *data, int len)
{
while (!hsi2c_check_transfer(regs) && len) {
if (!(read32(®s->usi_fifo_stat) & Hsi2cRxFifoEmpty)) {
*data++ = read32(®s->usi_rxdata);
len--;
}
}
return len ? -1 : 0;
}
static int hsi2c_segment(struct i2c_msg *seg, struct hsi2c_regs *regs,
int stop)
{
const uint32_t usi_ctl = Hsi2cFuncModeI2c | Hsi2cMaster;
write32(®s->i2c_addr, HSI2C_SLV_ADDR_MAS(seg->slave));
/*
* We really only want to stop after this transaction (I think) if the
* "stop" parameter is true. I'm assuming that's supposed to make the
* controller issue a repeated start, but the documentation isn't very
* clear. We may need to switch to manual mode to really get the
* behavior we want.
*/
uint32_t autoconf =
seg->len | Hsi2cMasterRun | Hsi2cStopAfterTrans;
if (seg->flags & I2C_M_RD) {
write32(®s->usi_ctl, usi_ctl | Hsi2cRxchon);
write32(®s->i2c_auto_conf, autoconf | Hsi2cReadWrite);
if (hsi2c_recvdata(regs, seg->buf, seg->len))
return -1;
} else {
write32(®s->usi_ctl, usi_ctl | Hsi2cTxchon);
write32(®s->i2c_auto_conf, autoconf);
if (hsi2c_senddata(regs, seg->buf, seg->len))
return -1;
}
if (hsi2c_wait_for_transfer(regs) != 1)
return -1;
write32(®s->usi_ctl, Hsi2cFuncModeI2c);
return 0;
}
static int hsi2c_transfer(struct i2c_bus *i2c, struct i2c_msg *segments,
int count)
{
struct hsi2c_regs *regs = i2c->hsregs;
if (hsi2c_wait_for_transfer(regs) != 1) {
hsi2c_reset(i2c);
return -1;
}
int i;
for (i = 0; i < count; i++) {
if (hsi2c_segment(&segments[i], regs, i == count - 1)) {
hsi2c_reset(i2c);
return -1;
}
}
return 0;
}
static int i2c_int_pending(struct i2c_regs *regs)
{
return read8(®s->con) & I2cConIntPending;
}
static void i2c_clear_int(struct i2c_regs *regs)
{
write8(®s->con, read8(®s->con) & ~I2cConIntPending);
}
static void i2c_ack_enable(struct i2c_regs *regs)
{
write8(®s->con, read8(®s->con) | I2cConAckGen);
}
static void i2c_ack_disable(struct i2c_regs *regs)
{
write8(®s->con, read8(®s->con) & ~I2cConAckGen);
}
static int i2c_got_ack(struct i2c_regs *regs)
{
return !(read8(®s->stat) & I2cStatAck);
}
static int i2c_wait_for_idle(struct i2c_regs *regs)
{
int timeout = 1000 * 100; // 1s.
while (timeout--) {
if (!(read8(®s->stat) & I2cStatBusy))
return 0;
udelay(10);
}
printk(BIOS_ERR, "I2C timeout waiting for idle.\n");
return 1;
}
static int i2c_wait_for_int(struct i2c_regs *regs)
{
int timeout = 1000 * 100; // 1s.
while (timeout--) {
if (i2c_int_pending(regs))
return 0;
udelay(10);
}
printk(BIOS_ERR, "I2C timeout waiting for I2C interrupt.\n");
return 1;
}
static int i2c_send_stop(struct i2c_regs *regs)
{
uint8_t mode = read8(®s->stat) & (I2cStatModeMask);
write8(®s->stat, mode | I2cStatEnable);
i2c_clear_int(regs);
return i2c_wait_for_idle(regs);
}
static int i2c_send_start(struct i2c_regs *regs, int read, int chip)
{
write8(®s->ds, chip << 1);
uint8_t mode = read ? I2cStatMasterRecv : I2cStatMasterXmit;
write8(®s->stat, mode | I2cStatStartStop | I2cStatEnable);
i2c_clear_int(regs);
if (i2c_wait_for_int(regs))
return 1;
if (!i2c_got_ack(regs)) {
// Nobody home, but they may just be asleep.
return 1;
}
return 0;
}
static int i2c_xmit_buf(struct i2c_regs *regs, uint8_t *data, int len)
{
ASSERT(len);
i2c_ack_enable(regs);
int i;
for (i = 0; i < len; i++) {
write8(®s->ds, data[i]);
i2c_clear_int(regs);
if (i2c_wait_for_int(regs))
return 1;
if (!i2c_got_ack(regs)) {
printk(BIOS_INFO, "I2c nacked.\n");
return 1;
}
}
return 0;
}
static int i2c_recv_buf(struct i2c_regs *regs, uint8_t *data, int len)
{
ASSERT(len);
i2c_ack_enable(regs);
int i;
for (i = 0; i < len; i++) {
if (i == len - 1)
i2c_ack_disable(regs);
i2c_clear_int(regs);
if (i2c_wait_for_int(regs))
return 1;
data[i] = read8(®s->ds);
}
return 0;
}
int platform_i2c_transfer(unsigned int bus, struct i2c_msg *segments, int count)
{
struct i2c_bus *i2c = &i2c_busses[bus];
if (i2c->is_highspeed)
return hsi2c_transfer(i2c, segments, count);
struct i2c_regs *regs = i2c->regs;
int res = 0;
if (!regs || i2c_wait_for_idle(regs))
return 1;
write8(®s->stat, I2cStatMasterXmit | I2cStatEnable);
int i;
for (i = 0; i < count; i++) {
struct i2c_msg *seg = &segments[i];
res = i2c_send_start(regs, seg->flags & I2C_M_RD, seg->slave);
if (res)
break;
if (seg->flags & I2C_M_RD)
res = i2c_recv_buf(regs, seg->buf, seg->len);
else
res = i2c_xmit_buf(regs, seg->buf, seg->len);
if (res)
break;
}
return i2c_send_stop(regs) || res;
}
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