zephyr/drivers/entropy/entropy_stm32.c

650 lines
16 KiB
C

/*
* Copyright (c) 2017 Erwin Rol <erwin@erwinrol.com>
* Copyright (c) 2018 Nordic Semiconductor ASA
* Copyright (c) 2017 Exati Tecnologia Ltda.
* Copyright (c) 2020 STMicroelectronics.
*
* SPDX-License-Identifier: Apache-2.0
*/
#define DT_DRV_COMPAT st_stm32_rng
#include <zephyr/kernel.h>
#include <zephyr/device.h>
#include <zephyr/drivers/entropy.h>
#include <zephyr/random/rand32.h>
#include <zephyr/init.h>
#include <zephyr/sys/__assert.h>
#include <zephyr/sys/util.h>
#include <errno.h>
#include <soc.h>
#include <zephyr/pm/policy.h>
#include <stm32_ll_bus.h>
#include <stm32_ll_rcc.h>
#include <stm32_ll_rng.h>
#include <stm32_ll_system.h>
#include <zephyr/sys/printk.h>
#include <zephyr/drivers/clock_control.h>
#include <zephyr/drivers/clock_control/stm32_clock_control.h>
#include "stm32_hsem.h"
#define IRQN DT_INST_IRQN(0)
#define IRQ_PRIO DT_INST_IRQ(0, priority)
#if defined(RNG_CR_CONDRST)
#define STM32_CONDRST_SUPPORT
#endif
/*
* This driver need to take into account all STM32 family:
* - simple rng without hardware fifo and no DMA.
* - Variable delay between two consecutive random numbers
* (depending on family and clock settings)
*
*
* Due to the first byte in a stream of bytes being more costly on
* some platforms a "water system" inspired algorithm is used to
* amortize the cost of the first byte.
*
* The algorithm will delay generation of entropy until the amount of
* bytes goes below THRESHOLD, at which point it will generate entropy
* until the BUF_LEN limit is reached.
*
* The entropy level is checked at the end of every consumption of
* entropy.
*
*/
struct rng_pool {
uint8_t first_alloc;
uint8_t first_read;
uint8_t last;
uint8_t mask;
uint8_t threshold;
uint8_t buffer[0];
};
#define RNG_POOL_DEFINE(name, len) uint8_t name[sizeof(struct rng_pool) + (len)]
BUILD_ASSERT((CONFIG_ENTROPY_STM32_ISR_POOL_SIZE &
(CONFIG_ENTROPY_STM32_ISR_POOL_SIZE - 1)) == 0,
"The CONFIG_ENTROPY_STM32_ISR_POOL_SIZE must be a power of 2!");
BUILD_ASSERT((CONFIG_ENTROPY_STM32_THR_POOL_SIZE &
(CONFIG_ENTROPY_STM32_THR_POOL_SIZE - 1)) == 0,
"The CONFIG_ENTROPY_STM32_THR_POOL_SIZE must be a power of 2!");
struct entropy_stm32_rng_dev_cfg {
struct stm32_pclken pclken;
};
struct entropy_stm32_rng_dev_data {
RNG_TypeDef *rng;
const struct device *clock;
struct k_sem sem_lock;
struct k_sem sem_sync;
struct k_work filling_work;
bool filling_pools;
RNG_POOL_DEFINE(isr, CONFIG_ENTROPY_STM32_ISR_POOL_SIZE);
RNG_POOL_DEFINE(thr, CONFIG_ENTROPY_STM32_THR_POOL_SIZE);
};
static const struct entropy_stm32_rng_dev_cfg entropy_stm32_rng_config = {
.pclken = { .bus = DT_INST_CLOCKS_CELL(0, bus),
.enr = DT_INST_CLOCKS_CELL(0, bits) },
};
static struct entropy_stm32_rng_dev_data entropy_stm32_rng_data = {
.rng = (RNG_TypeDef *)DT_INST_REG_ADDR(0),
};
static void configure_rng(void)
{
RNG_TypeDef *rng = entropy_stm32_rng_data.rng;
#if DT_INST_NODE_HAS_PROP(0, health_test_config)
#if DT_INST_NODE_HAS_PROP(0, health_test_magic)
/* Write Magic number before writing configuration
* Not all stm32 series have a Magic number
*/
LL_RNG_SetHealthConfig(rng, DT_INST_PROP(0, health_test_magic));
#endif
/* Write RNG HTCR configuration */
LL_RNG_SetHealthConfig(rng, DT_INST_PROP(0, health_test_config));
#endif
LL_RNG_Enable(rng);
LL_RNG_EnableIT(rng);
}
static void acquire_rng(void)
{
#if defined(CONFIG_SOC_SERIES_STM32WBX) || defined(CONFIG_STM32H7_DUAL_CORE)
/* Lock the RNG to prevent concurrent access */
z_stm32_hsem_lock(CFG_HW_RNG_SEMID, HSEM_LOCK_WAIT_FOREVER);
/* RNG configuration could have been changed by the other core */
configure_rng();
#endif /* CONFIG_SOC_SERIES_STM32WBX || CONFIG_STM32H7_DUAL_CORE */
}
static void release_rng(void)
{
#if defined(CONFIG_SOC_SERIES_STM32WBX) || defined(CONFIG_STM32H7_DUAL_CORE)
z_stm32_hsem_unlock(CFG_HW_RNG_SEMID);
#endif /* CONFIG_SOC_SERIES_STM32WBX || CONFIG_STM32H7_DUAL_CORE */
}
static int entropy_stm32_got_error(RNG_TypeDef *rng)
{
__ASSERT_NO_MSG(rng != NULL);
if (LL_RNG_IsActiveFlag_CECS(rng)) {
return 1;
}
if (LL_RNG_IsActiveFlag_SEIS(rng)) {
return 1;
}
return 0;
}
#if defined(STM32_CONDRST_SUPPORT)
/* SOCS w/ soft-reset support: execute the reset */
static int recover_seed_error(RNG_TypeDef *rng)
{
uint32_t count_timeout = 0;
LL_RNG_EnableCondReset(rng);
LL_RNG_DisableCondReset(rng);
/* When reset process is done cond reset bit is read 0
* This typically takes: 2 AHB clock cycles + 2 RNG clock cycles.
*/
while (LL_RNG_IsEnabledCondReset(rng) ||
LL_RNG_IsActiveFlag_SEIS(rng) ||
LL_RNG_IsActiveFlag_SECS(rng)) {
count_timeout++;
if (count_timeout == 10) {
return -ETIMEDOUT;
}
}
return 0;
}
#else /* !STM32_CONDRST_SUPPORT */
/* SOCS w/o soft-reset support: flush pipeline */
static int recover_seed_error(RNG_TypeDef *rng)
{
LL_RNG_ClearFlag_SEIS(rng);
for (int i = 0; i < 12; ++i) {
LL_RNG_ReadRandData32(rng);
}
if (LL_RNG_IsActiveFlag_SEIS(rng) != 0) {
return -EIO;
}
return 0;
}
#endif /* !STM32_CONDRST_SUPPORT */
static int random_byte_get(void)
{
int retval = -EAGAIN;
unsigned int key;
RNG_TypeDef *rng = entropy_stm32_rng_data.rng;
key = irq_lock();
if (LL_RNG_IsActiveFlag_SEIS(rng) && (recover_seed_error(rng) < 0)) {
retval = -EIO;
goto out;
}
if ((LL_RNG_IsActiveFlag_DRDY(rng) == 1)) {
if (entropy_stm32_got_error(rng)) {
retval = -EIO;
goto out;
}
retval = LL_RNG_ReadRandData32(rng);
if (retval == 0) {
/* A seed error could have occurred between RNG_SR
* polling and RND_DR output reading.
*/
retval = -EAGAIN;
goto out;
}
retval &= 0xFF;
}
out:
irq_unlock(key);
return retval;
}
static uint16_t generate_from_isr(uint8_t *buf, uint16_t len)
{
uint16_t remaining_len = len;
__ASSERT_NO_MSG(!irq_is_enabled(IRQN));
#if defined(CONFIG_SOC_SERIES_STM32WBX) || defined(CONFIG_STM32H7_DUAL_CORE)
__ASSERT_NO_MSG(z_stm32_hsem_is_owned(CFG_HW_RNG_SEMID));
#endif /* CONFIG_SOC_SERIES_STM32WBX || CONFIG_STM32H7_DUAL_CORE */
/* do not proceed if a Seed error occurred */
if (LL_RNG_IsActiveFlag_SECS(entropy_stm32_rng_data.rng) ||
LL_RNG_IsActiveFlag_SEIS(entropy_stm32_rng_data.rng)) {
(void)random_byte_get(); /* this will recover the error */
return 0; /* return cnt is null : no random data available */
}
/* Clear NVIC pending bit. This ensures that a subsequent
* RNG event will set the Cortex-M single-bit event register
* to 1 (the bit is set when NVIC pending IRQ status is
* changed from 0 to 1)
*/
NVIC_ClearPendingIRQ(IRQN);
do {
int byte;
while (LL_RNG_IsActiveFlag_DRDY(
entropy_stm32_rng_data.rng) != 1) {
/*
* To guarantee waking up from the event, the
* SEV-On-Pend feature must be enabled (enabled
* during ARCH initialization).
*
* DSB is recommended by spec before WFE (to
* guarantee completion of memory transactions)
*/
__DSB();
__WFE();
__SEV();
__WFE();
}
byte = random_byte_get();
NVIC_ClearPendingIRQ(IRQN);
if (byte < 0) {
continue;
}
buf[--remaining_len] = byte;
} while (remaining_len);
return len;
}
static int start_pool_filling(bool wait)
{
unsigned int key;
bool already_filling;
key = irq_lock();
#if defined(CONFIG_SOC_SERIES_STM32WBX) || defined(CONFIG_STM32H7_DUAL_CORE)
/* In non-blocking mode, return immediately if the RNG is not available */
if (!wait && z_stm32_hsem_try_lock(CFG_HW_RNG_SEMID) != 0) {
irq_unlock(key);
return -EAGAIN;
}
#else
ARG_UNUSED(wait);
#endif /* CONFIG_SOC_SERIES_STM32WBX || CONFIG_STM32H7_DUAL_CORE */
already_filling = entropy_stm32_rng_data.filling_pools;
entropy_stm32_rng_data.filling_pools = true;
irq_unlock(key);
if (unlikely(already_filling)) {
return 0;
}
/* Prevent the clocks to be stopped during the duration the rng pool is
* being populated. The ISR will release the constraint again when the
* rng pool is filled.
*/
pm_policy_state_lock_get(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES);
acquire_rng();
irq_enable(IRQN);
return 0;
}
static void pool_filling_work_handler(struct k_work *work)
{
if (start_pool_filling(false) != 0) {
/* RNG could not be acquired, try again */
k_work_submit(work);
}
}
#pragma GCC push_options
#if defined(CONFIG_BT_CTLR_FAST_ENC)
#pragma GCC optimize ("Ofast")
#endif
static uint16_t rng_pool_get(struct rng_pool *rngp, uint8_t *buf, uint16_t len)
{
uint32_t last = rngp->last;
uint32_t mask = rngp->mask;
uint8_t *dst = buf;
uint32_t first, available;
uint32_t other_read_in_progress;
unsigned int key;
key = irq_lock();
first = rngp->first_alloc;
/*
* The other_read_in_progress is non-zero if rngp->first_read != first,
* which means that lower-priority code (which was interrupted by this
* call) already allocated area for read.
*/
other_read_in_progress = (rngp->first_read ^ first);
available = (last - first) & mask;
if (available < len) {
len = available;
}
/*
* Move alloc index forward to signal, that part of the buffer is
* now reserved for this call.
*/
rngp->first_alloc = (first + len) & mask;
irq_unlock(key);
while (likely(len--)) {
*dst++ = rngp->buffer[first];
first = (first + 1) & mask;
}
/*
* If this call is the last one accessing the pool, move read index
* to signal that all allocated regions are now read and could be
* overwritten.
*/
if (likely(!other_read_in_progress)) {
key = irq_lock();
rngp->first_read = rngp->first_alloc;
irq_unlock(key);
}
len = dst - buf;
available = available - len;
if (available <= rngp->threshold) {
/*
* Avoid starting pool filling from ISR as it might require
* blocking if RNG is not available and a race condition could
* also occur if this ISR has interrupted the RNG ISR.
*/
if (k_is_in_isr()) {
k_work_submit(&entropy_stm32_rng_data.filling_work);
} else {
start_pool_filling(true);
}
}
return len;
}
#pragma GCC pop_options
static int rng_pool_put(struct rng_pool *rngp, uint8_t byte)
{
uint8_t first = rngp->first_read;
uint8_t last = rngp->last;
uint8_t mask = rngp->mask;
/* Signal error if the pool is full. */
if (((last - first) & mask) == mask) {
return -ENOBUFS;
}
rngp->buffer[last] = byte;
rngp->last = (last + 1) & mask;
return 0;
}
static void rng_pool_init(struct rng_pool *rngp, uint16_t size,
uint8_t threshold)
{
rngp->first_alloc = 0U;
rngp->first_read = 0U;
rngp->last = 0U;
rngp->mask = size - 1;
rngp->threshold = threshold;
}
static void stm32_rng_isr(const void *arg)
{
int byte, ret;
ARG_UNUSED(arg);
byte = random_byte_get();
if (byte < 0) {
return;
}
ret = rng_pool_put((struct rng_pool *)(entropy_stm32_rng_data.isr),
byte);
if (ret < 0) {
ret = rng_pool_put(
(struct rng_pool *)(entropy_stm32_rng_data.thr),
byte);
if (ret < 0) {
irq_disable(IRQN);
release_rng();
pm_policy_state_lock_put(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES);
entropy_stm32_rng_data.filling_pools = false;
}
k_sem_give(&entropy_stm32_rng_data.sem_sync);
}
}
static int entropy_stm32_rng_get_entropy(const struct device *dev,
uint8_t *buf,
uint16_t len)
{
/* Check if this API is called on correct driver instance. */
__ASSERT_NO_MSG(&entropy_stm32_rng_data == dev->data);
while (len) {
uint16_t bytes;
k_sem_take(&entropy_stm32_rng_data.sem_lock, K_FOREVER);
bytes = rng_pool_get(
(struct rng_pool *)(entropy_stm32_rng_data.thr),
buf, len);
if (bytes == 0U) {
/* Pool is empty: Sleep until next interrupt. */
k_sem_take(&entropy_stm32_rng_data.sem_sync, K_FOREVER);
}
k_sem_give(&entropy_stm32_rng_data.sem_lock);
len -= bytes;
buf += bytes;
}
return 0;
}
static int entropy_stm32_rng_get_entropy_isr(const struct device *dev,
uint8_t *buf,
uint16_t len,
uint32_t flags)
{
uint16_t cnt = len;
/* Check if this API is called on correct driver instance. */
__ASSERT_NO_MSG(&entropy_stm32_rng_data == dev->data);
if (likely((flags & ENTROPY_BUSYWAIT) == 0U)) {
return rng_pool_get(
(struct rng_pool *)(entropy_stm32_rng_data.isr),
buf, len);
}
if (len) {
unsigned int key;
int irq_enabled;
bool rng_already_acquired;
key = irq_lock();
irq_enabled = irq_is_enabled(IRQN);
irq_disable(IRQN);
irq_unlock(key);
rng_already_acquired = z_stm32_hsem_is_owned(CFG_HW_RNG_SEMID);
acquire_rng();
cnt = generate_from_isr(buf, len);
/* Restore the state of the RNG lock and IRQ */
if (!rng_already_acquired) {
release_rng();
}
if (irq_enabled) {
irq_enable(IRQN);
}
}
return cnt;
}
static int entropy_stm32_rng_init(const struct device *dev)
{
struct entropy_stm32_rng_dev_data *dev_data;
const struct entropy_stm32_rng_dev_cfg *dev_cfg;
int res;
__ASSERT_NO_MSG(dev != NULL);
dev_data = dev->data;
dev_cfg = dev->config;
__ASSERT_NO_MSG(dev_data != NULL);
__ASSERT_NO_MSG(dev_cfg != NULL);
#if CONFIG_SOC_SERIES_STM32L4X
/* Configure PLLSA11 to enable 48M domain */
LL_RCC_PLLSAI1_ConfigDomain_48M(LL_RCC_PLLSOURCE_MSI,
LL_RCC_PLLM_DIV_1,
24, LL_RCC_PLLSAI1Q_DIV_2);
/* Enable PLLSA1 */
LL_RCC_PLLSAI1_Enable();
/* Enable PLLSAI1 output mapped on 48MHz domain clock */
LL_RCC_PLLSAI1_EnableDomain_48M();
/* Wait for PLLSA1 ready flag */
while (LL_RCC_PLLSAI1_IsReady() != 1) {
}
/* Write the peripherals independent clock configuration register :
* choose PLLSAI1 source as the 48 MHz clock is needed for the RNG
* Linear Feedback Shift Register
*/
LL_RCC_SetRNGClockSource(LL_RCC_RNG_CLKSOURCE_PLLSAI1);
#elif CONFIG_SOC_SERIES_STM32WLX || CONFIG_SOC_SERIES_STM32G0X
LL_RCC_PLL_EnableDomain_RNG();
LL_RCC_SetRNGClockSource(LL_RCC_RNG_CLKSOURCE_PLL);
#elif defined(RCC_CR2_HSI48ON) || defined(RCC_CR_HSI48ON) \
|| defined(RCC_CRRCR_HSI48ON)
#if CONFIG_SOC_SERIES_STM32L0X
/* We need SYSCFG to control VREFINT, so make sure it is clocked */
if (!LL_APB2_GRP1_IsEnabledClock(LL_APB2_GRP1_PERIPH_SYSCFG)) {
return -EINVAL;
}
/* HSI48 requires VREFINT (see RM0376 section 7.2.4). */
LL_SYSCFG_VREFINT_EnableHSI48();
#endif /* CONFIG_SOC_SERIES_STM32L0X */
z_stm32_hsem_lock(CFG_HW_CLK48_CONFIG_SEMID, HSEM_LOCK_DEFAULT_RETRY);
/* Use the HSI48 for the RNG */
LL_RCC_HSI48_Enable();
while (!LL_RCC_HSI48_IsReady()) {
/* Wait for HSI48 to become ready */
}
#if defined(CONFIG_SOC_SERIES_STM32WBX)
LL_RCC_SetRNGClockSource(LL_RCC_RNG_CLKSOURCE_CLK48);
LL_RCC_SetCLK48ClockSource(LL_RCC_CLK48_CLKSOURCE_HSI48);
/* Don't unlock the HSEM to prevent M0 core
* to disable HSI48 clock used for RNG.
*/
#else
LL_RCC_SetRNGClockSource(LL_RCC_RNG_CLKSOURCE_HSI48);
/* Unlock the HSEM if it is not STM32WB */
z_stm32_hsem_unlock(CFG_HW_CLK48_CONFIG_SEMID);
#endif /* CONFIG_SOC_SERIES_STM32WBX */
#endif /* CONFIG_SOC_SERIES_STM32L4X */
dev_data->clock = DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE);
res = clock_control_on(dev_data->clock,
(clock_control_subsys_t *)&dev_cfg->pclken);
__ASSERT_NO_MSG(res == 0);
/* Locking semaphore initialized to 1 (unlocked) */
k_sem_init(&dev_data->sem_lock, 1, 1);
/* Synching semaphore */
k_sem_init(&dev_data->sem_sync, 0, 1);
k_work_init(&dev_data->filling_work, pool_filling_work_handler);
rng_pool_init((struct rng_pool *)(dev_data->thr),
CONFIG_ENTROPY_STM32_THR_POOL_SIZE,
CONFIG_ENTROPY_STM32_THR_THRESHOLD);
rng_pool_init((struct rng_pool *)(dev_data->isr),
CONFIG_ENTROPY_STM32_ISR_POOL_SIZE,
CONFIG_ENTROPY_STM32_ISR_THRESHOLD);
IRQ_CONNECT(IRQN, IRQ_PRIO, stm32_rng_isr, &entropy_stm32_rng_data, 0);
#if !defined(CONFIG_SOC_SERIES_STM32WBX) && !defined(CONFIG_STM32H7_DUAL_CORE)
/* For multi-core MCUs, RNG configuration is automatically performed
* after acquiring the RNG in start_pool_filling()
*/
configure_rng();
#endif /* !CONFIG_SOC_SERIES_STM32WBX && !CONFIG_STM32H7_DUAL_CORE */
start_pool_filling(true);
return 0;
}
static const struct entropy_driver_api entropy_stm32_rng_api = {
.get_entropy = entropy_stm32_rng_get_entropy,
.get_entropy_isr = entropy_stm32_rng_get_entropy_isr
};
DEVICE_DT_INST_DEFINE(0,
entropy_stm32_rng_init, NULL,
&entropy_stm32_rng_data, &entropy_stm32_rng_config,
PRE_KERNEL_1, CONFIG_ENTROPY_INIT_PRIORITY,
&entropy_stm32_rng_api);