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/*
* (C) Copyright 2007
* Stefan Roese, DENX Software Engineering, sr@denx.de.
*
* See file CREDITS for list of people who contributed to this
* project.
*
* 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; either version 2 of
* the License, or (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <common.h>
#include <asm/processor.h>
#include <asm/io.h>
#include <asm/gpio.h>
#if defined(CFG_440_GPIO_TABLE)
gpio_param_s gpio_tab[GPIO_GROUP_MAX][GPIO_MAX] = CFG_440_GPIO_TABLE;
#endif
#if defined(GPIO0_OSRL)
/* Only some 4xx variants support alternate funtions on the GPIO's */
void gpio_config(int pin, int in_out, int gpio_alt, int out_val)
{
u32 mask;
u32 mask2;
u32 val;
u32 offs = 0;
u32 offs2 = 0;
int pin2 = pin << 1;
if (pin >= GPIO_MAX) {
offs = 0x100;
pin -= GPIO_MAX;
}
if (pin >= GPIO_MAX/2) {
offs2 = 0x100;
pin2 = (pin - GPIO_MAX/2) << 1;
}
mask = 0x80000000 >> pin;
mask2 = 0xc0000000 >> (pin2 << 1);
/* first set TCR to 0 */
out32(GPIO0_TCR + offs, in32(GPIO0_TCR + offs) & ~mask);
if (in_out == GPIO_OUT) {
val = in32(GPIO0_OSRL + offs + offs2) & ~mask2;
switch (gpio_alt) {
case GPIO_ALT1:
val |= GPIO_ALT1_SEL >> pin2;
break;
case GPIO_ALT2:
val |= GPIO_ALT2_SEL >> pin2;
break;
case GPIO_ALT3:
val |= GPIO_ALT3_SEL >> pin2;
break;
}
out32(GPIO0_OSRL + offs + offs2, val);
/* setup requested output value */
if (out_val == GPIO_OUT_0)
out32(GPIO0_OR + offs, in32(GPIO0_OR + offs) & ~mask);
else if (out_val == GPIO_OUT_1)
out32(GPIO0_OR + offs, in32(GPIO0_OR + offs) | mask);
/* now configure TCR to drive output if selected */
out32(GPIO0_TCR + offs, in32(GPIO0_TCR + offs) | mask);
} else {
val = in32(GPIO0_ISR1L + offs + offs2) & ~mask2;
val |= GPIO_IN_SEL >> pin2;
out32(GPIO0_ISR1L + offs + offs2, val);
}
}
#endif /* GPIO_OSRL */
void gpio_write_bit(int pin, int val)
{
u32 offs = 0;
if (pin >= GPIO_MAX) {
offs = 0x100;
pin -= GPIO_MAX;
}
if (val)
out32(GPIO0_OR + offs, in32(GPIO0_OR + offs) | GPIO_VAL(pin));
else
out32(GPIO0_OR + offs, in32(GPIO0_OR + offs) & ~GPIO_VAL(pin));
}
int gpio_read_out_bit(int pin)
{
u32 offs = 0;
if (pin >= GPIO_MAX) {
offs = 0x100;
pin -= GPIO_MAX;
}
return (in32(GPIO0_OR + offs) & GPIO_VAL(pin) ? 1 : 0);
}
#if defined(CFG_440_GPIO_TABLE)
void gpio_set_chip_configuration(void)
{
unsigned char i=0, j=0, offs=0, gpio_core;
unsigned long reg, core_add;
for (gpio_core=0; gpio_core<GPIO_GROUP_MAX; gpio_core++) {
j = 0;
offs = 0;
/* GPIO config of the GPIOs 0 to 31 */
for (i=0; i<GPIO_MAX; i++, j++) {
if (i == GPIO_MAX/2) {
offs = 4;
j = i-16;
}
core_add = gpio_tab[gpio_core][i].add;
if ((gpio_tab[gpio_core][i].in_out == GPIO_IN) ||
(gpio_tab[gpio_core][i].in_out == GPIO_BI)) {
switch (gpio_tab[gpio_core][i].alt_nb) {
case GPIO_SEL:
break;
case GPIO_ALT1:
reg = in32(GPIO_IS1(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_IN_SEL >> (j*2));
out32(GPIO_IS1(core_add+offs), reg);
break;
case GPIO_ALT2:
reg = in32(GPIO_IS2(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_IN_SEL >> (j*2));
out32(GPIO_IS2(core_add+offs), reg);
break;
case GPIO_ALT3:
reg = in32(GPIO_IS3(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_IN_SEL >> (j*2));
out32(GPIO_IS3(core_add+offs), reg);
break;
}
}
if ((gpio_tab[gpio_core][i].in_out == GPIO_OUT) ||
(gpio_tab[gpio_core][i].in_out == GPIO_BI)) {
switch (gpio_tab[gpio_core][i].alt_nb) {
case GPIO_SEL:
if (gpio_core == GPIO0) {
/*
* Setup output value
* 1 -> high level
* 0 -> low level
* else -> don't touch
*/
reg = in32(GPIO0_OR);
if (gpio_tab[gpio_core][i].out_val == GPIO_OUT_1)
reg |= (0x80000000 >> (i));
else if (gpio_tab[gpio_core][i].out_val == GPIO_OUT_0)
reg &= ~(0x80000000 >> (i));
out32(GPIO0_OR, reg);
reg = in32(GPIO0_TCR) | (0x80000000 >> (i));
out32(GPIO0_TCR, reg);
}
if (gpio_core == GPIO1) {
/*
* Setup output value
* 1 -> high level
* 0 -> low level
* else -> don't touch
*/
reg = in32(GPIO1_OR);
if (gpio_tab[gpio_core][i].out_val == GPIO_OUT_1)
reg |= (0x80000000 >> (i));
else if (gpio_tab[gpio_core][i].out_val == GPIO_OUT_0)
reg &= ~(0x80000000 >> (i));
out32(GPIO1_OR, reg);
reg = in32(GPIO1_TCR) | (0x80000000 >> (i));
out32(GPIO1_TCR, reg);
}
reg = in32(GPIO_OS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
out32(GPIO_OS(core_add+offs), reg);
reg = in32(GPIO_TS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
out32(GPIO_TS(core_add+offs), reg);
break;
case GPIO_ALT1:
reg = in32(GPIO_OS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT1_SEL >> (j*2));
out32(GPIO_OS(core_add+offs), reg);
reg = in32(GPIO_TS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT1_SEL >> (j*2));
out32(GPIO_TS(core_add+offs), reg);
break;
case GPIO_ALT2:
reg = in32(GPIO_OS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT2_SEL >> (j*2));
out32(GPIO_OS(core_add+offs), reg);
reg = in32(GPIO_TS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT2_SEL >> (j*2));
out32(GPIO_TS(core_add+offs), reg);
break;
case GPIO_ALT3:
reg = in32(GPIO_OS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT3_SEL >> (j*2));
out32(GPIO_OS(core_add+offs), reg);
reg = in32(GPIO_TS(core_add+offs))
& ~(GPIO_MASK >> (j*2));
reg = reg | (GPIO_ALT3_SEL >> (j*2));
out32(GPIO_TS(core_add+offs), reg);
break;
}
}
}
}
}
#endif /* CFG_440_GPIO_TABLE */