coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/lm4/gpio.c

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2024-03-04 11:14:53 +01:00
/* Copyright 2012 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.
*/
/* GPIO module for Chrome EC */
#include "clock.h"
#include "common.h"
#include "gpio.h"
#include "hooks.h"
#include "registers.h"
#include "switch.h"
#include "task.h"
#include "timer.h"
#include "util.h"
/* 0-terminated list of GPIO base addresses */
static const uint32_t gpio_bases[] = {
LM4_GPIO_A, LM4_GPIO_B, LM4_GPIO_C, LM4_GPIO_D,
LM4_GPIO_E, LM4_GPIO_F, LM4_GPIO_G, LM4_GPIO_H,
LM4_GPIO_J, LM4_GPIO_K, LM4_GPIO_L, LM4_GPIO_M,
LM4_GPIO_N, LM4_GPIO_P, LM4_GPIO_Q, 0
};
/**
* Find the index of a GPIO port base address
*
* This is used by the clock gating registers.
*
* @param port_base Base address to find (LM4_GPIO_[A-Q])
*
* @return The index, or -1 if no match.
*/
static int find_gpio_port_index(uint32_t port_base)
{
int i;
for (i = 0; gpio_bases[i]; i++) {
if (gpio_bases[i] == port_base)
return i;
}
return -1;
}
void gpio_set_alternate_function(uint32_t port, uint32_t mask, int func)
{
int port_index = find_gpio_port_index(port);
int cgmask;
/* Ignore (do nothing for) invalid port values */
if (port_index < 0)
return;
/* Enable the GPIO port in run and sleep. */
cgmask = 1 << port_index;
clock_enable_peripheral(CGC_OFFSET_GPIO, cgmask,
CGC_MODE_RUN | CGC_MODE_SLEEP);
if (func >= 0) {
int pctlmask = 0;
int i;
/* Expand mask from bits to nibbles */
for (i = 0; i < 8; i++) {
if (mask & BIT(i))
pctlmask |= 1 << (4 * i);
}
LM4_GPIO_PCTL(port) =
(LM4_GPIO_PCTL(port) & ~(pctlmask * 0xf)) |
(pctlmask * func);
LM4_GPIO_AFSEL(port) |= mask;
} else {
LM4_GPIO_AFSEL(port) &= ~mask;
}
}
test_mockable int gpio_get_level(enum gpio_signal signal)
{
return LM4_GPIO_DATA(gpio_list[signal].port,
gpio_list[signal].mask) ? 1 : 0;
}
void gpio_set_level(enum gpio_signal signal, int value)
{
/*
* Ok to write 0xff because LM4_GPIO_DATA bit-masks only the bit
* we care about.
*/
LM4_GPIO_DATA(gpio_list[signal].port,
gpio_list[signal].mask) = (value ? 0xff : 0);
}
void gpio_set_flags_by_mask(uint32_t port, uint32_t mask, uint32_t flags)
{
/*
* Select open drain first, so that we don't glitch the signal
* when changing the line to an output.
*/
if (flags & GPIO_OPEN_DRAIN)
LM4_GPIO_ODR(port) |= mask;
else
LM4_GPIO_ODR(port) &= ~mask;
if (flags & GPIO_OUTPUT)
LM4_GPIO_DIR(port) |= mask;
else
LM4_GPIO_DIR(port) &= ~mask;
/* Handle pullup / pulldown */
if (flags & GPIO_PULL_UP) {
LM4_GPIO_PUR(port) |= mask;
} else if (flags & GPIO_PULL_DOWN) {
LM4_GPIO_PDR(port) |= mask;
} else {
/* No pull up/down */
LM4_GPIO_PUR(port) &= ~mask;
LM4_GPIO_PDR(port) &= ~mask;
}
/* Set up interrupt type */
if (flags & (GPIO_INT_F_LOW | GPIO_INT_F_HIGH))
LM4_GPIO_IS(port) |= mask;
else
LM4_GPIO_IS(port) &= ~mask;
if (flags & (GPIO_INT_F_RISING | GPIO_INT_F_HIGH))
LM4_GPIO_IEV(port) |= mask;
else
LM4_GPIO_IEV(port) &= ~mask;
/* Handle interrupting on both edges */
if ((flags & GPIO_INT_F_RISING) &&
(flags & GPIO_INT_F_FALLING))
LM4_GPIO_IBE(port) |= mask;
else
LM4_GPIO_IBE(port) &= ~mask;
if (flags & GPIO_ANALOG)
LM4_GPIO_DEN(port) &= ~mask;
else
LM4_GPIO_DEN(port) |= mask;
/* Set level */
if (flags & GPIO_HIGH)
LM4_GPIO_DATA(port, mask) = 0xff;
else if (flags & GPIO_LOW)
LM4_GPIO_DATA(port, mask) = 0;
}
int gpio_enable_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
/* Fail if no interrupt handler */
if (signal >= GPIO_IH_COUNT)
return EC_ERROR_UNKNOWN;
LM4_GPIO_IM(g->port) |= g->mask;
return EC_SUCCESS;
}
int gpio_disable_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
/* Fail if no interrupt handler */
if (signal >= GPIO_IH_COUNT)
return EC_ERROR_UNKNOWN;
LM4_GPIO_IM(g->port) &= ~g->mask;
return EC_SUCCESS;
}
int gpio_clear_pending_interrupt(enum gpio_signal signal)
{
const struct gpio_info *g = gpio_list + signal;
/* Fail if no interrupt handler */
if (signal >= GPIO_IH_COUNT)
return EC_ERROR_INVAL;
LM4_GPIO_ICR(g->port) |= g->mask;
return EC_SUCCESS;
}
#ifdef CONFIG_LOW_POWER_IDLE
/**
* Convert GPIO port to a mask that can be used to set the
* clock gate control register for GPIOs.
*/
static int gpio_port_to_clock_gate_mask(uint32_t gpio_port)
{
int index = find_gpio_port_index(gpio_port);
return index >= 0 ? BIT(index) : 0;
}
#endif
void gpio_pre_init(void)
{
const struct gpio_info *g = gpio_list;
int is_warm = 0;
int i;
if (LM4_SYSTEM_RCGCGPIO == 0x7fff) {
/* This is a warm reboot */
is_warm = 1;
} else {
/*
* Enable clocks to all the GPIO blocks since we use all of
* them as GPIOs in run and sleep modes.
*/
clock_enable_peripheral(CGC_OFFSET_GPIO, 0x7fff,
CGC_MODE_RUN | CGC_MODE_SLEEP);
}
/*
* Disable GPIO commit control for PD7 and PF0, since we don't use the
* NMI pin function.
*/
LM4_GPIO_LOCK(LM4_GPIO_D) = LM4_GPIO_LOCK_UNLOCK;
LM4_GPIO_CR(LM4_GPIO_D) |= 0x80;
LM4_GPIO_LOCK(LM4_GPIO_D) = 0;
LM4_GPIO_LOCK(LM4_GPIO_F) = LM4_GPIO_LOCK_UNLOCK;
LM4_GPIO_CR(LM4_GPIO_F) |= 0x01;
LM4_GPIO_LOCK(LM4_GPIO_F) = 0;
/* Clear SSI0 alternate function on PA2:5 */
LM4_GPIO_AFSEL(LM4_GPIO_A) &= ~0x3c;
/* Mask all GPIO interrupts */
for (i = 0; gpio_bases[i]; i++)
LM4_GPIO_IM(gpio_bases[i]) = 0;
/* Set all GPIOs to defaults */
for (i = 0; i < GPIO_COUNT; i++, g++) {
int flags = g->flags;
if (flags & GPIO_DEFAULT)
continue;
#ifdef CONFIG_LOW_POWER_IDLE
/*
* Enable board specific GPIO ports to interrupt deep sleep by
* providing a clock to that port in deep sleep mode.
*/
if (flags & GPIO_INT_DSLEEP) {
clock_enable_peripheral(CGC_OFFSET_GPIO,
gpio_port_to_clock_gate_mask(g->port),
CGC_MODE_ALL);
}
#endif
/*
* If this is a warm reboot, don't set the output levels or
* we'll shut off the main chipset.
*/
if (is_warm)
flags &= ~(GPIO_LOW | GPIO_HIGH);
/* Set up GPIO based on flags */
gpio_set_flags_by_mask(g->port, g->mask, flags);
/* Use as GPIO, not alternate function */
gpio_set_alternate_function(g->port, g->mask, -1);
}
#ifdef CONFIG_LOW_POWER_IDLE
/*
* Enable KB scan row to interrupt deep sleep by providing a clock
* signal to that port in deep sleep mode.
*/
clock_enable_peripheral(CGC_OFFSET_GPIO,
gpio_port_to_clock_gate_mask(KB_SCAN_ROW_GPIO),
CGC_MODE_ALL);
#endif
}
/* List of GPIO IRQs to enable. Don't automatically enable interrupts for
* the keyboard input GPIO bank - that's handled separately. Of course the
* bank is different for different systems. */
static const uint8_t gpio_irqs[] = {
LM4_IRQ_GPIOA, LM4_IRQ_GPIOB, LM4_IRQ_GPIOC, LM4_IRQ_GPIOD,
LM4_IRQ_GPIOE, LM4_IRQ_GPIOF, LM4_IRQ_GPIOG, LM4_IRQ_GPIOH,
LM4_IRQ_GPIOJ,
#if defined(KB_SCAN_ROW_IRQ) && (KB_SCAN_ROW_IRQ != LM4_IRQ_GPIOK)
LM4_IRQ_GPIOK,
#endif
LM4_IRQ_GPIOL, LM4_IRQ_GPIOM,
#if defined(KB_SCAN_ROW_IRQ) && (KB_SCAN_ROW_IRQ != LM4_IRQ_GPION)
LM4_IRQ_GPION,
#endif
LM4_IRQ_GPIOP, LM4_IRQ_GPIOQ
};
static void gpio_init(void)
{
int i;
/* Enable IRQs now that pins are set up */
for (i = 0; i < ARRAY_SIZE(gpio_irqs); i++)
task_enable_irq(gpio_irqs[i]);
}
DECLARE_HOOK(HOOK_INIT, gpio_init, HOOK_PRIO_DEFAULT);
/*****************************************************************************/
/* Interrupt handlers */
/**
* Handle a GPIO interrupt.
*
* @param port GPIO port (LM4_GPIO_*)
* @param mis Masked interrupt status value for that port
*/
static void gpio_interrupt(int port, uint32_t mis)
{
int i = 0;
const struct gpio_info *g = gpio_list;
for (i = 0; i < GPIO_IH_COUNT && mis; i++, g++) {
if (port == g->port && (mis & g->mask)) {
gpio_irq_handlers[i](i);
mis &= ~g->mask;
}
}
}
/**
* Handlers for each GPIO port. These read and clear the interrupt bits for
* the port, then call the master handler above.
*/
#define GPIO_IRQ_FUNC(irqfunc, gpiobase) \
void irqfunc(void) \
{ \
uint32_t mis = LM4_GPIO_MIS(gpiobase); \
LM4_GPIO_ICR(gpiobase) = mis; \
gpio_interrupt(gpiobase, mis); \
}
GPIO_IRQ_FUNC(__gpio_a_interrupt, LM4_GPIO_A);
GPIO_IRQ_FUNC(__gpio_b_interrupt, LM4_GPIO_B);
GPIO_IRQ_FUNC(__gpio_c_interrupt, LM4_GPIO_C);
GPIO_IRQ_FUNC(__gpio_d_interrupt, LM4_GPIO_D);
GPIO_IRQ_FUNC(__gpio_e_interrupt, LM4_GPIO_E);
GPIO_IRQ_FUNC(__gpio_f_interrupt, LM4_GPIO_F);
GPIO_IRQ_FUNC(__gpio_g_interrupt, LM4_GPIO_G);
GPIO_IRQ_FUNC(__gpio_h_interrupt, LM4_GPIO_H);
GPIO_IRQ_FUNC(__gpio_j_interrupt, LM4_GPIO_J);
#if defined(KB_SCAN_ROW_GPIO) && (KB_SCAN_ROW_GPIO != LM4_GPIO_K)
GPIO_IRQ_FUNC(__gpio_k_interrupt, LM4_GPIO_K);
#endif
GPIO_IRQ_FUNC(__gpio_l_interrupt, LM4_GPIO_L);
GPIO_IRQ_FUNC(__gpio_m_interrupt, LM4_GPIO_M);
#if defined(KB_SCAN_ROW_GPIO) && (KB_SCAN_ROW_GPIO != LM4_GPIO_N)
GPIO_IRQ_FUNC(__gpio_n_interrupt, LM4_GPIO_N);
#endif
GPIO_IRQ_FUNC(__gpio_p_interrupt, LM4_GPIO_P);
GPIO_IRQ_FUNC(__gpio_q_interrupt, LM4_GPIO_Q);
#undef GPIO_IRQ_FUNC
/*
* Declare IRQs. Nesting this macro inside the GPIO_IRQ_FUNC macro works
* poorly because DECLARE_IRQ() stringizes its inputs.
*/
DECLARE_IRQ(LM4_IRQ_GPIOA, __gpio_a_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOB, __gpio_b_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOC, __gpio_c_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOD, __gpio_d_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOE, __gpio_e_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOF, __gpio_f_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOG, __gpio_g_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOH, __gpio_h_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOJ, __gpio_j_interrupt, 1);
#if defined(KB_SCAN_ROW_GPIO) && (KB_SCAN_ROW_GPIO != LM4_GPIO_K)
DECLARE_IRQ(LM4_IRQ_GPIOK, __gpio_k_interrupt, 1);
#endif
DECLARE_IRQ(LM4_IRQ_GPIOL, __gpio_l_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOM, __gpio_m_interrupt, 1);
#if defined(KB_SCAN_ROW_GPIO) && (KB_SCAN_ROW_GPIO != LM4_GPIO_N)
DECLARE_IRQ(LM4_IRQ_GPION, __gpio_n_interrupt, 1);
#endif
DECLARE_IRQ(LM4_IRQ_GPIOP, __gpio_p_interrupt, 1);
DECLARE_IRQ(LM4_IRQ_GPIOQ, __gpio_q_interrupt, 1);