coreboot-libre-fam15h-rdimm/3rdparty/chromeec/board/zinger/hardware.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.
*/
/* Hardware initialization and common functions */
#include "adc.h"
#include "adc_chip.h"
#include "common.h"
#include "cpu.h"
#include "registers.h"
#include "task.h"
#include "timer.h"
#include "util.h"
#include "watchdog.h"
static void system_init(void)
{
/* Enable access to RCC CSR register and RTC backup registers */
STM32_PWR_CR |= BIT(8);
/* switch on LSI */
STM32_RCC_CSR |= BIT(0);
/* Wait for LSI to be ready */
while (!(STM32_RCC_CSR & BIT(1)))
;
/* re-configure RTC if needed */
if ((STM32_RCC_BDCR & 0x00018300) != 0x00008200) {
/* the RTC settings are bad, we need to reset it */
STM32_RCC_BDCR |= 0x00010000;
/* Enable RTC and use LSI as clock source */
STM32_RCC_BDCR = (STM32_RCC_BDCR & ~0x00018300) | 0x00008200;
}
}
static void power_init(void)
{
/* enable SYSCFG, COMP, ADC, SPI1, USART1 */
STM32_RCC_APB2ENR = 0x00005201;
/* enable TIM2, TIM3, TIM14, PWR */
STM32_RCC_APB1ENR = 0x10000103;
/* enable DMA, SRAM, CRC, GPA, GPB, GPF */
STM32_RCC_AHBENR = 0x460045;
}
/* GPIO setting helpers */
#define OUT(n) (1 << ((n) * 2))
#define AF(n) (2 << ((n) * 2))
#define ANALOG(n) (3 << ((n) * 2))
#define HIGH(n) (1 << (n))
#define ODR(n) (1 << (n))
#define HISPEED(n) (3 << ((n) * 2))
#define AFx(n, x) (x << (((n) % 8) * 4))
static void pins_init(void)
{
/* Pin usage:
* PA0 (OUT - GPIO) : Wakeup on Vnc / Threshold
* PA1 (ANALOG - ADC_IN1) : CC sense
* PA2 (ANALOG - ADC_IN2) : Current sense
* PA3 (ANALOG - ADC_IN3) : Voltage sense
* PA4 (OUT - OD GPIO) : PD TX enable
* PA5 (AF0 - SPI1_SCK) : TX clock in
* PA6 (AF0 - SPI1_MISO) : PD TX
* PA7 (AF5 - TIM3_CH2) : PD RX
* PA9 (AF1 - UART1_TX) : [DEBUG] UART TX
* PA10 (AF1 - UART1_RX) : [DEBUG] UART RX
* PA13 (OUT - GPIO) : voltage select[0]
* PA14 (OUT - GPIO) : voltage select[1]
* PB1 (AF0 - TIM14_CH1) : TX clock out
* PF0 (OUT - GPIO) : LM5050 FET driver off
* PF1 (OUT - GPIO) : discharge FET
*/
/*
* Clear power control/status register to disable wakeup
* pin A0, so that we can change it to an output.
*/
STM32_PWR_CSR = 0;
STM32_PWR_CR |= 0xc;
STM32_GPIO_ODR(GPIO_A) = HIGH(0) | HIGH(4);
STM32_GPIO_AFRL(GPIO_A) = AFx(7, 1);
STM32_GPIO_AFRH(GPIO_A) = AFx(9, 1) | AFx(10, 1);
STM32_GPIO_OTYPER(GPIO_A) = ODR(4);
STM32_GPIO_OSPEEDR(GPIO_A) = HISPEED(5) | HISPEED(6) | HISPEED(7);
STM32_GPIO_MODER(GPIO_A) = OUT(0) | ANALOG(1) | ANALOG(2) | ANALOG(3)
| OUT(4) | AF(5) /*| AF(6)*/ | AF(7) | AF(9)
| AF(10) | OUT(13) | OUT(14);
/* set PF0 / PF1 as output */
STM32_GPIO_ODR(GPIO_F) = 0;
STM32_GPIO_MODER(GPIO_F) = OUT(0) | OUT(1);
STM32_GPIO_OTYPER(GPIO_F) = 0;
/* Set PB1 as AF0 (TIM14_CH1) */
STM32_GPIO_OSPEEDR(GPIO_B) = HISPEED(1);
STM32_GPIO_MODER(GPIO_B) = AF(1);
}
static void adc_init(void)
{
/* Only do the calibration if the ADC is off */
if (!(STM32_ADC_CR & 1)) {
/* ADC calibration */
STM32_ADC_CR = STM32_ADC_CR_ADCAL; /* set ADCAL = 1, ADC off */
/* wait for the end of calibration */
while (STM32_ADC_CR & STM32_ADC_CR_ADCAL)
;
}
/* Single conversion, right aligned, 12-bit */
STM32_ADC_CFGR1 = BIT(12); /* BIT(15) => AUTOOFF */;
/* clock is ADCCLK (ADEN must be off when writing this reg) */
STM32_ADC_CFGR2 = 0;
/* Sampling time : 71.5 ADC clock cycles, about 5us */
STM32_ADC_SMPR = 6;
/*
* ADC enable (note: takes 4 ADC clocks between end of calibration
* and setting ADEN).
*/
STM32_ADC_CR = STM32_ADC_CR_ADEN;
while (!(STM32_ADC_ISR & STM32_ADC_ISR_ADRDY))
STM32_ADC_CR = STM32_ADC_CR_ADEN;
/* Disable interrupts */
STM32_ADC_IER = 0;
/* Analog watchdog IRQ */
task_enable_irq(STM32_IRQ_ADC_COMP);
}
static void uart_init(void)
{
/* set baudrate */
STM32_USART_BRR(UARTN_BASE) =
DIV_ROUND_NEAREST(CPU_CLOCK, CONFIG_UART_BAUD_RATE);
/* UART enabled, 8 Data bits, oversampling x16, no parity */
STM32_USART_CR1(UARTN_BASE) =
STM32_USART_CR1_UE | STM32_USART_CR1_TE | STM32_USART_CR1_RE;
/* 1 stop bit, no fancy stuff */
STM32_USART_CR2(UARTN_BASE) = 0x0000;
/* DMA disabled, special modes disabled, error interrupt disabled */
STM32_USART_CR3(UARTN_BASE) = 0x0000;
}
static void timers_init(void)
{
/* TIM2 is a 32-bit free running counter with 1Mhz frequency */
STM32_TIM_CR2(2) = 0x0000;
STM32_TIM32_ARR(2) = 0xFFFFFFFF;
STM32_TIM_PSC(2) = CPU_CLOCK / 1000000 - 1;
STM32_TIM_EGR(2) = 0x0001; /* Reload the pre-scaler */
STM32_TIM_CR1(2) = 1;
STM32_TIM32_CNT(2) = 0x00000000;
STM32_TIM_SR(2) = 0; /* Clear pending interrupts */
STM32_TIM_DIER(2) = 1; /* Overflow interrupt */
task_enable_irq(STM32_IRQ_TIM2);
}
static void irq_init(void)
{
/* clear all pending interrupts */
CPU_NVIC_UNPEND(0) = 0xffffffff;
/* enable global interrupts */
asm("cpsie i");
}
extern void runtime_init(void);
void hardware_init(void)
{
uint32_t raw_cause = STM32_RCC_CSR;
uint32_t pwr_status = STM32_PWR_CSR;
power_init();
/* Clear the hardware reset cause by setting the RMVF bit */
STM32_RCC_CSR |= BIT(24);
/* Clear SBF in PWR_CSR */
STM32_PWR_CR |= BIT(3);
/*
* WORKAROUND: as we cannot de-activate the watchdog during
* long hibernation, we are woken-up once by the watchdog and
* go back to hibernate if we detect that condition, without
* watchdog initialized this time.
* The RTC deadline (if any) is already set.
*/
if ((pwr_status & 0x2) && (raw_cause & 0x60000000))
__enter_hibernate(0, 0);
system_init();
runtime_init(); /* sets clock */
pins_init();
uart_init();
timers_init();
watchdog_init();
adc_init();
irq_init();
}
static int watchdog_ain_id, watchdog_ain_high, watchdog_ain_low;
static int adc_enable_last_watchdog(void)
{
return adc_enable_watchdog(watchdog_ain_id, watchdog_ain_high,
watchdog_ain_low);
}
static inline int adc_watchdog_enabled(void)
{
return STM32_ADC_CFGR1 & BIT(23);
}
int adc_read_channel(enum adc_channel ch)
{
int value;
int watchdog_enabled = adc_watchdog_enabled();
if (watchdog_enabled)
adc_disable_watchdog();
/* Select channel to convert */
STM32_ADC_CHSELR = 1 << ch;
/* Clear flags */
STM32_ADC_ISR = 0x8e;
/* Start conversion */
STM32_ADC_CR |= BIT(2); /* ADSTART */
/* Wait for end of conversion */
while (!(STM32_ADC_ISR & BIT(2)))
;
/* read converted value */
value = STM32_ADC_DR;
if (watchdog_enabled)
adc_enable_last_watchdog();
return value;
}
int adc_enable_watchdog(int ch, int high, int low)
{
/* store last watchdog setup */
watchdog_ain_id = ch;
watchdog_ain_high = high;
watchdog_ain_low = low;
/* Set thresholds */
STM32_ADC_TR = ((high & 0xfff) << 16) | (low & 0xfff);
/* Select channel to convert */
STM32_ADC_CHSELR = 1 << ch;
/* Clear flags */
STM32_ADC_ISR = 0x8e;
/* Set Watchdog enable bit on a single channel / continuous mode */
STM32_ADC_CFGR1 = (ch << 26) | BIT(23) | BIT(22)
| BIT(13) | BIT(12);
/* Enable watchdog interrupt */
STM32_ADC_IER = BIT(7);
/* Start continuous conversion */
STM32_ADC_CR |= BIT(2); /* ADSTART */
return EC_SUCCESS;
}
int adc_disable_watchdog(void)
{
/* Stop on-going conversion */
STM32_ADC_CR |= BIT(4); /* ADSTP */
/* Wait for conversion to stop */
while (STM32_ADC_CR & BIT(4))
;
/* CONT=0 -> continuous mode off / Clear Watchdog enable */
STM32_ADC_CFGR1 = BIT(12);
/* Disable interrupt */
STM32_ADC_IER = 0;
/* Clear flags */
STM32_ADC_ISR = 0x8e;
return EC_SUCCESS;
}
/* ---- flash handling ---- */
/*
* Approximate number of CPU cycles per iteration of the loop when polling
* the flash status
*/
#define CYCLE_PER_FLASH_LOOP 10
/* Flash page programming timeout. This is 2x the datasheet max. */
#define FLASH_TIMEOUT_US 16000
#define FLASH_TIMEOUT_LOOP \
(FLASH_TIMEOUT_US * (CPU_CLOCK / SECOND) / CYCLE_PER_FLASH_LOOP)
/* Flash unlocking keys */
#define KEY1 0x45670123
#define KEY2 0xCDEF89AB
/* Lock bits for FLASH_CR register */
#define PG BIT(0)
#define PER BIT(1)
#define OPTPG BIT(4)
#define OPTER BIT(5)
#define STRT BIT(6)
#define CR_LOCK BIT(7)
#define OPTWRE BIT(9)
int flash_physical_write(int offset, int size, const char *data)
{
uint16_t *address = (uint16_t *)(CONFIG_PROGRAM_MEMORY_BASE + offset);
int res = EC_SUCCESS;
int i;
if ((uint32_t)address > CONFIG_PROGRAM_MEMORY_BASE + CONFIG_FLASH_SIZE)
return EC_ERROR_INVAL;
/* unlock CR if needed */
if (STM32_FLASH_CR & CR_LOCK) {
STM32_FLASH_KEYR = KEY1;
STM32_FLASH_KEYR = KEY2;
}
/* Clear previous error status */
STM32_FLASH_SR = 0x34;
/* set the ProGram bit */
STM32_FLASH_CR |= PG;
for (; size > 0; size -= sizeof(uint16_t)) {
/* wait to be ready */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP);
i++)
;
/* write the half word */
*address++ = data[0] + (data[1] << 8);
data += 2;
/* Wait for writes to complete */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP);
i++)
;
if (i == FLASH_TIMEOUT_LOOP) {
res = EC_ERROR_TIMEOUT;
goto exit_wr;
}
/* Check for error conditions - erase failed, voltage error,
* protection error */
if (STM32_FLASH_SR & 0x14) {
res = EC_ERROR_UNKNOWN;
goto exit_wr;
}
}
exit_wr:
STM32_FLASH_CR &= ~PG;
STM32_FLASH_CR = CR_LOCK;
return res;
}
int flash_physical_erase(int offset, int size)
{
int res = EC_SUCCESS;
/* unlock CR if needed */
if (STM32_FLASH_CR & CR_LOCK) {
STM32_FLASH_KEYR = KEY1;
STM32_FLASH_KEYR = KEY2;
}
/* Clear previous error status */
STM32_FLASH_SR = 0x34;
/* set PER bit */
STM32_FLASH_CR |= PER;
for (; size > 0; size -= CONFIG_FLASH_ERASE_SIZE,
offset += CONFIG_FLASH_ERASE_SIZE) {
int i;
/* select page to erase */
STM32_FLASH_AR = CONFIG_PROGRAM_MEMORY_BASE + offset;
/* set STRT bit : start erase */
STM32_FLASH_CR |= STRT;
/* Wait for erase to complete */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP);
i++)
;
if (i == FLASH_TIMEOUT_LOOP) {
res = EC_ERROR_TIMEOUT;
goto exit_er;
}
/*
* Check for error conditions - erase failed, voltage error,
* protection error
*/
if (STM32_FLASH_SR & 0x14) {
res = EC_ERROR_UNKNOWN;
goto exit_er;
}
}
exit_er:
STM32_FLASH_CR &= ~PER;
STM32_FLASH_CR = CR_LOCK;
return res;
}
static void unlock_erase_optb(void)
{
int i;
/* Clear previous error status */
STM32_FLASH_SR = 0x34;
/* wait to be ready */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP); i++)
;
/* Unlock the option bytes access */
if (STM32_FLASH_CR & CR_LOCK) {
STM32_FLASH_KEYR = KEY1;
STM32_FLASH_KEYR = KEY2;
}
if (!(STM32_FLASH_CR & OPTWRE)) {
STM32_FLASH_OPTKEYR = KEY1;
STM32_FLASH_OPTKEYR = KEY2;
}
/* Must be set in 2 separate lines. */
STM32_FLASH_CR |= OPTER;
STM32_FLASH_CR |= STRT;
/* wait to be ready */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP); i++)
;
/* reset erasing bits */
STM32_FLASH_CR = OPTWRE;
}
static void write_optb(int byte, uint8_t value)
{
volatile int16_t *hword = (uint16_t *)(STM32_OPTB_BASE + byte);
int i;
/* Clear previous error status */
STM32_FLASH_SR = 0x34;
/* set OPTPG bit */
STM32_FLASH_CR |= OPTPG;
*hword = ((~value) << STM32_OPTB_COMPL_SHIFT) | value;
/* reset OPTPG bit */
STM32_FLASH_CR = OPTWRE;
/* wait to be ready */
for (i = 0; (STM32_FLASH_SR & 1) && (i < FLASH_TIMEOUT_LOOP); i++)
;
}
void flash_physical_permanent_protect(void)
{
unlock_erase_optb();
/* protect the 16KB RO partition against write/erase in WRP0 */
write_optb(8, 0xF0);
/* Set RDP to level 1 to prevent disabling the protection */
write_optb(0, 0x11);
/* Reset by using OBL_LAUNCH to take changes into account */
asm volatile("cpsid i");
STM32_FLASH_CR |= FLASH_CR_OBL_LAUNCH;
/* Spin and wait for reboot; should never return */
while (1)
;
}
int flash_physical_is_permanently_protected(void)
{
/* if RDP is still at level 0, the flash protection is not in place */
return (STM32_FLASH_OBR & STM32_FLASH_OBR_RDP_MASK) &&
/* the low 16KB (RO partition) are write-protected */
!(STM32_FLASH_WRPR & 0xF);
}