coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/g/gpio.c

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2024-03-04 11:14:53 +01:00
/* Copyright 2014 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.
*/
#include "common.h"
#include "console.h"
#include "gpio.h"
#include "hooks.h"
#include "registers.h"
#include "task.h"
/*
* The Cr50's ARM core has two GPIO ports of 16 bits each. Each GPIO signal
* can be routed through a full NxM crossbar to any of a number of external
* pins. When setting up GPIOs, both the ARM core and the crossbar must be
* configured correctly. This file is only concerned with the ARM core.
*/
test_mockable int gpio_get_level(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
return !!(GR_GPIO_DATAIN(g->port) & g->mask);
}
static void set_one_gpio_bit(uint32_t port, uint16_t mask, int value)
{
if (!mask)
return;
/* Assumes mask has one and only one bit set */
if (mask & 0x00FF)
GR_GPIO_MASKLOWBYTE(port, mask) = value ? mask : 0;
else
GR_GPIO_MASKHIGHBYTE(port, mask >> 8) = value ? mask : 0;
}
void gpio_set_level(enum gpio_signal signal, int value)
{
const struct gpio_info *g = gpio_list + signal;
if (g->flags & GPIO_OPEN_DRAIN) {
if (value) {
GR_GPIO_CLRDOUTEN(g->port) = g->mask;
/* Don't ever set ODR output to HIGH. */
return;
}
GR_GPIO_SETDOUTEN(g->port) = g->mask;
}
set_one_gpio_bit(g->port, g->mask, value);
}
int gpio_get_flags_by_mask(uint32_t port, uint32_t mask)
{
uint32_t flags = 0;
uint32_t val = 0;
/* Only one bit must be set. */
if ((mask != (mask & -mask)) || (mask == 0))
return 0;
/* Check mode. */
/* ARM DDI 0479B: 3.5.2 */
val = GR_GPIO_SETDOUTEN(port) & mask;
if (val) {
flags |= GPIO_OUTPUT;
val = GR_GPIO_DOUT(port) & mask;
if (val)
flags |= GPIO_HIGH;
else
flags |= GPIO_LOW;
} else
flags |= GPIO_INPUT;
return flags;
}
void gpio_set_flags_by_mask(uint32_t port, uint32_t mask, uint32_t flags)
{
/* Output must be enabled when needed, input is always enabled */
if (flags & GPIO_OUTPUT) {
if (flags & GPIO_LOW)
set_one_gpio_bit(port, mask, 0);
else if ((flags & GPIO_HIGH) && !(flags & GPIO_OPEN_DRAIN))
/* Set to HIGH only if not open drain. */
set_one_gpio_bit(port, mask, 1);
if (!(flags & GPIO_OPEN_DRAIN) || (flags & GPIO_LOW))
/*
* Enable output for push-pull (high or low), or
* open-drain low.
*/
GR_GPIO_SETDOUTEN(port) = mask;
else if (flags & GPIO_OPEN_DRAIN)
/*
* Disable output for other open-drain cases to get a
* high-Z pin.
*/
GR_GPIO_CLRDOUTEN(port) = mask;
} else {
GR_GPIO_CLRDOUTEN(port) = mask;
}
/* Interrupt types */
if (flags & GPIO_INT_F_LOW) {
GR_GPIO_CLRINTTYPE(port) = mask;
GR_GPIO_CLRINTPOL(port) = mask;
}
if (flags & GPIO_INT_F_HIGH) {
GR_GPIO_CLRINTTYPE(port) = mask;
GR_GPIO_SETINTPOL(port) = mask;
}
if (flags & GPIO_INT_F_FALLING) {
GR_GPIO_SETINTTYPE(port) = mask;
GR_GPIO_CLRINTPOL(port) = mask;
}
if (flags & GPIO_INT_F_RISING) {
GR_GPIO_SETINTTYPE(port) = mask;
GR_GPIO_SETINTPOL(port) = mask;
}
/* No way to trigger on both rising and falling edges, darn it. */
}
void gpio_set_alternate_function(uint32_t port, uint32_t mask, int func)
{
/* This HW feature is not present in the Cr50 ARM core */
}
/*
* A pinmux_config contains the selector offset and selector value for a
* particular pinmux entry.
*/
struct pinmux_config {
uint16_t offset;
uint16_t value;
};
#define PINMUX_CONFIG(name) { \
.offset = CONCAT3(GC_PINMUX_, name, _SEL_OFFSET), \
.value = CONCAT3(GC_PINMUX_, name, _SEL), \
}
/*
* The pinmux struct contains a full description of the connection of a DIO to
* a GPIO, an internal peripheral, or as a direct input. The flag
* DIO_TO_PERIPHERAL is used to select between the two union entries. There
* is no union entry for direct input because it requires no parameters.
*/
struct pinmux {
union {
enum gpio_signal signal;
struct pinmux_config peripheral;
};
struct pinmux_config dio;
uint16_t flags;
};
/*
* These macros are used to add flags indicating the type of mapping requested.
* DIO_TO_PERIPHERAL for FUNC mappings.
* DIO_ENABLE_DIRECT_INPUT for DIRECT mappings.
*/
#define FLAGS_FUNC(name) DIO_TO_PERIPHERAL
#define FLAGS_GPIO(name) 0
#define FLAGS_DIRECT DIO_ENABLE_DIRECT_INPUT
/*
* These macros are used to selectively initialize the anonymous union based
* on the type of pinmux mapping requested (FUNC, GPIO, or DIRECT).
*/
#define PINMUX_FUNC(name) .peripheral = PINMUX_CONFIG(name),
#define PINMUX_GPIO(name) .signal = CONCAT2(GPIO_, name),
#define PINMUX_DIRECT
/*
* Initialize an entry for the pinmux list. The first parameter can be either
* FUNC(name) or GPIO(name) depending on the type of mapping required. The
* second argument is the DIO name to map to. And the final argument is the
* flags set for this mapping, this macro adds the DIO_TO_PERIPHERAL flag for
* a FUNC mapping.
*/
#define PINMUX(name, dio_name, dio_flags) { \
PINMUX_##name \
.dio = PINMUX_CONFIG(DIO##dio_name), \
.flags = dio_flags | FLAGS_##name \
},
static const struct pinmux pinmux_list[] = {
#include "gpio.wrap"
};
/* Return true if DIO should be a digital input */
static int connect_dio_to_peripheral(struct pinmux const *p)
{
if (p->flags & DIO_OUTPUT)
DIO_SEL_REG(p->dio.offset) = p->peripheral.value;
if (p->flags & DIO_INPUT)
DIO_SEL_REG(p->peripheral.offset) = p->dio.value;
return p->flags & DIO_INPUT;
}
/* Return true if DIO should be a digital input */
static int connect_dio_to_gpio(struct pinmux const *p)
{
const struct gpio_info *g = gpio_list + p->signal;
int bitnum = GPIO_MASK_TO_NUM(g->mask);
if ((g->flags & GPIO_OUTPUT) || (p->flags & DIO_OUTPUT))
DIO_SEL_REG(p->dio.offset) = GET_GPIO_FUNC(g->port, bitnum);
if ((g->flags & GPIO_INPUT) || (p->flags & DIO_INPUT))
GET_GPIO_SEL_REG(g->port, bitnum) = p->dio.value;
if (g->flags & GPIO_PULL_UP)
REG_WRITE_MLV(DIO_CTL_REG(p->dio.offset),
DIO_CTL_PU_MASK,
DIO_CTL_PU_LSB, 1);
if (g->flags & GPIO_PULL_DOWN)
REG_WRITE_MLV(DIO_CTL_REG(p->dio.offset),
DIO_CTL_PD_MASK,
DIO_CTL_PD_LSB, 1);
return (g->flags & GPIO_INPUT) || (p->flags & DIO_INPUT);
}
static void connect_pinmux(struct pinmux const *p)
{
uint32_t bitmask;
int is_input;
if (p->flags & DIO_ENABLE_DIRECT_INPUT) {
/* We don't have to setup any muxes for directly connected
* pads. The only ones that we are likely to ever care about
* are tied to the SPS and SPI peripherals, and they're all
* inouts, so we can just enable the digital input for them
* regardless. */
is_input = 1;
} else {
/* Pads that must be muxed to specific GPIOs or peripherals may
* or may not be inputs. We'll check those individually. */
if (p->flags & DIO_TO_PERIPHERAL)
is_input = connect_dio_to_peripheral(p);
else
is_input = connect_dio_to_gpio(p);
}
/* Configure the DIO pad controls */
if (is_input)
REG_WRITE_MLV(DIO_CTL_REG(p->dio.offset),
DIO_CTL_IE_MASK,
DIO_CTL_IE_LSB, 1);
if (p->flags & DIO_PULL_UP)
REG_WRITE_MLV(DIO_CTL_REG(p->dio.offset),
DIO_CTL_PU_MASK,
DIO_CTL_PU_LSB, 1);
if (p->flags & DIO_PULL_DOWN)
REG_WRITE_MLV(DIO_CTL_REG(p->dio.offset),
DIO_CTL_PD_MASK,
DIO_CTL_PD_LSB, 1);
/* Enable any wake pins needed to exit low-power modes */
if ((p->flags & DIO_WAKE_EN0) &&
(p->dio.offset <= GC_PINMUX_DIOB7_SEL_OFFSET)) { /* not VIOn ! */
bitmask = (1 << (p->dio.offset / 8));
/* enable pad as wake source */
GREG32(PINMUX, EXITEN0) |= bitmask;
/* level (0) or edge sensitive (1) */
if (p->flags & DIO_WAKE_EDGE0)
GREG32(PINMUX, EXITEDGE0) |= bitmask;
else
GREG32(PINMUX, EXITEDGE0) &= ~bitmask;
/* high/rising (0) or low/falling (1) */
if (p->flags & DIO_WAKE_INV0)
GREG32(PINMUX, EXITINV0) |= bitmask;
else
GREG32(PINMUX, EXITINV0) &= ~bitmask;
}
}
int gpio_enable_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
GR_GPIO_SETINTEN(g->port) = g->mask;
return EC_SUCCESS;
}
int gpio_disable_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
GR_GPIO_CLRINTEN(g->port) = g->mask;
return EC_SUCCESS;
}
int gpio_clear_pending_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
GR_GPIO_CLRINTSTAT(g->port) = g->mask;
return EC_SUCCESS;
}
void gpio_pre_init(void)
{
const struct gpio_info *g = gpio_list;
int i;
/* Enable clocks */
REG_WRITE_MLV(GR_PMU_PERICLKSET0,
GC_PMU_PERICLKSET0_DGPIO0_CLK_MASK,
GC_PMU_PERICLKSET0_DGPIO0_CLK_LSB, 1);
REG_WRITE_MLV(GR_PMU_PERICLKSET0,
GC_PMU_PERICLKSET0_DGPIO1_CLK_MASK,
GC_PMU_PERICLKSET0_DGPIO1_CLK_LSB, 1);
/* Set up the pinmux */
for (i = 0; i < ARRAY_SIZE(pinmux_list); i++)
connect_pinmux(pinmux_list + i);
/* Set up ARM core GPIOs */
for (i = 0; i < GPIO_COUNT; i++, g++)
if (g->mask && !(g->flags & GPIO_DEFAULT))
gpio_set_flags_by_mask(g->port, g->mask, g->flags);
}
static void gpio_init(void)
{
task_enable_irq(GC_IRQNUM_GPIO0_GPIOCOMBINT);
task_enable_irq(GC_IRQNUM_GPIO1_GPIOCOMBINT);
}
DECLARE_HOOK(HOOK_INIT, gpio_init, HOOK_PRIO_DEFAULT);
/*****************************************************************************/
/* Interrupt handler stuff */
static void gpio_invoke_handler(uint32_t port, uint32_t mask)
{
const struct gpio_info *g = gpio_list;
int i;
for (i = 0; i < GPIO_IH_COUNT; i++, g++)
if (port == g->port && (mask & g->mask))
gpio_irq_handlers[i](i);
}
static void gpio_interrupt(int port)
{
int bitnum;
uint32_t mask;
uint32_t pending = GR_GPIO_CLRINTSTAT(port);
while (pending) {
bitnum = GPIO_MASK_TO_NUM(pending);
mask = 1 << bitnum;
pending &= ~mask;
gpio_invoke_handler(port, mask);
GR_GPIO_CLRINTSTAT(port) = mask;
}
}
void _gpio0_interrupt(void)
{
gpio_interrupt(0);
}
void _gpio1_interrupt(void)
{
gpio_interrupt(1);
}
DECLARE_IRQ(GC_IRQNUM_GPIO0_GPIOCOMBINT, _gpio0_interrupt, 1);
DECLARE_IRQ(GC_IRQNUM_GPIO1_GPIOCOMBINT, _gpio1_interrupt, 1);
/*
* The uart, i2c, and spi suffix arrays must match the order of the pinmux
* select registers in chip/g/hw_regdefs.h. If the order is incorrect, the
* pinmux command output will be wrong.
*/
static const char * const uart_str[] = {
"0_CTS", "0_RTS", "0_RX", "0_TX",
"1_CTS", "1_RTS", "1_RX", "1_TX",
"2_CTS", "2_RTS", "2_RX", "2_TX",
};
static const char * const i2c_str[] = {
"0_SCL", "0_SDA",
"1_SCL", "1_SDA",
"S0_SCL", "S0_SDA",
};
static const char * const spi_str[] = {
"SPICLK", "SPICSB", "SPIMISO", "SPIMOSI",
};
static void print_periph(int sel)
{
if (sel >= 1 && sel <= 16)
ccprintf("GPIO0_GPIO%d", sel - 1);
else if (sel >= 17 && sel <= 32)
ccprintf("GPIO1_GPIO%d", sel - 17);
else if (sel >= 33 && sel <= 38)
ccprintf("I2C%s", i2c_str[sel - 33]);
else if (sel >= 49 && sel <= 52)
ccprintf("SPI1_%s", spi_str[sel - 49]);
else if (sel >= 67 && sel <= 78)
ccprintf("UART%s", uart_str[sel - 67]);
else if (sel)
ccprintf("UNDEF");
}
static void show_pinmux(const char name, int i, int ofs)
{
uint32_t sel = DIO_SEL_REG(i * 8 + ofs);
uint32_t ctl = DIO_CTL_REG(i * 8 + ofs);
uint32_t bitmask = 1 << (i + ofs / 8);
uint32_t edge = GREG32(PINMUX, EXITEDGE0) & bitmask;
/* skip empty ones (ignoring drive strength bits) */
if (!sel && !(ctl & (0xf << 2)) && !(GREG32(PINMUX, EXITEN0) & bitmask))
return;
ccprintf("%08x: DIO%c%-2d %2d %3s%3s%3s%4s ",
GC_PINMUX_BASE_ADDR + i * 8 + ofs,
name, i, sel,
(ctl & BIT(2)) ? " IN" : "",
(ctl & BIT(3)) ? " PD" : "",
(ctl & BIT(4)) ? " PU" : "",
(ctl & BIT(5)) ? " INV" : "");
print_periph(sel);
if (GREG32(PINMUX, EXITEN0) & bitmask) {
ccprintf(" WAKE_");
if (GREG32(PINMUX, EXITINV0) & bitmask)
ccprintf("%s", edge ? "FALLING" : "LOW");
else
ccprintf("%s", edge ? "RISING" : "HIGH");
}
ccprintf("\n");
cflush();
}
static void print_dio_str(uint32_t sel)
{
if (sel >= 1 && sel <= 2)
ccprintf(" VIO%d\n", 2 - sel);
else if (sel >= 3 && sel <= 10)
ccprintf(" DIOB%d\n", 10 - sel);
else if (sel >= 11 && sel <= 25)
ccprintf(" DIOA%d\n", 25 - sel);
else if (sel >= 26 && sel <= 30)
ccprintf(" DIOM%d\n", 30 - sel);
else
ccprintf("\n");
cflush();
}
static void show_pinmux_periph(int i)
{
uint32_t ofs = GC_PINMUX_GPIO0_GPIO0_SEL_OFFSET + i * 4;
uint32_t sel = DIO_SEL_REG(ofs);
if (sel == 0)
return;
ccprintf("%08x: ", GC_PINMUX_BASE_ADDR + ofs);
print_periph(i + 1);
ccprintf("\t%2d", sel);
print_dio_str(sel);
}
static int command_pinmux(int argc, char **argv)
{
size_t i;
const struct {
char name;
uint8_t count;
uint8_t base_offset;
} pads[] = {
{'M', 5, 0},
{'A', 15, 0x28},
{'B', 8, 0xa0},
{'V', 2, 0xe8},
};
for (i = 0; i < ARRAY_SIZE(pads); i++) {
uint8_t j;
for (j = 0; j < pads[i].count; j++)
show_pinmux(pads[i].name, j, pads[i].base_offset);
}
ccprintf("\n");
/* GPIO & Peripheral sources */
for (i = 0; i <= 98; i++)
show_pinmux_periph(i);
ccprintf("\n");
return EC_SUCCESS;
}
DECLARE_SAFE_CONSOLE_COMMAND(pinmux, command_pinmux,
"",
"Display pinmux info");
static const char * const int_str[] = {
"LOW", "FALLING", "HIGH", "RISING",
};
static void show_gpiocfg(int n)
{
uint32_t din = GR_GPIO_DATAIN(n);
uint32_t dout = GR_GPIO_DOUT(n);
uint32_t outen = GR_GPIO_SETDOUTEN(n);
uint32_t inten = GR_GPIO_SETINTEN(n);
uint32_t intpol = GR_GPIO_SETINTPOL(n);
uint32_t inttype = GR_GPIO_SETINTTYPE(n);
uint32_t mask;
int i, j;
for (i = 0, mask = 0x1; i < 16; i++, mask <<= 1) {
/* Skip it unless it's an output or an interrupt */
if (!((outen & mask) || (inten & mask)))
continue;
ccprintf("GPIO%d_GPIO%d:\tread %d", n, i, !!(din & mask));
if (outen & mask)
ccprintf(" drive %d", !!(dout & mask));
if (inten & mask) {
j = ((intpol & mask) ? 2 : 0) +
((inttype & mask) ? 1 : 0);
ccprintf(" INT_%s", int_str[j]);
}
ccprintf("\n");
}
}
static int command_gpiocfg(int argc, char **argv)
{
show_gpiocfg(0);
show_gpiocfg(1);
return EC_SUCCESS;
}
DECLARE_SAFE_CONSOLE_COMMAND(gpiocfg, command_gpiocfg,
"",
"Display GPIO configs");