esp-idf/components/esp32c3/memprot.c

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// Copyright 2020 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/* INTERNAL API
* implementation of PMS memory protection features
*/
#include <stdio.h>
#include "sdkconfig.h"
#include "soc/sensitive_reg.h"
#include "soc/dport_access.h"
#include "soc/periph_defs.h"
#include "esp_intr_alloc.h"
#include "esp_log.h"
static const char *TAG = "memprot";
#include "esp32c3/memprot.h"
#include "hal/memprot_ll.h"
#include "riscv/interrupt.h"
#include "esp_log.h"
extern int _iram_text_end;
const char *mem_type_to_str(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_NONE:
return "MEMPROT_NONE";
case MEMPROT_IRAM0_SRAM:
return "MEMPROT_IRAM0_SRAM";
case MEMPROT_DRAM0_SRAM:
return "MEMPROT_DRAM0_SRAM";
case MEMPROT_ALL:
return "MEMPROT_ALL";
default:
return "UNKNOWN";
}
}
const char *split_line_to_str(split_line_t line_type)
{
switch (line_type) {
case MEMPROT_IRAM0_DRAM0_SPLITLINE:
return "MEMPROT_IRAM0_DRAM0_SPLITLINE";
case MEMPROT_IRAM0_LINE_0_SPLITLINE:
return "MEMPROT_IRAM0_LINE_0_SPLITLINE";
case MEMPROT_IRAM0_LINE_1_SPLITLINE:
return "MEMPROT_IRAM0_LINE_1_SPLITLINE";
case MEMPROT_DRAM0_DMA_LINE_0_SPLITLINE:
return "MEMPROT_DRAM0_DMA_LINE_0_SPLITLINE";
case MEMPROT_DRAM0_DMA_LINE_1_SPLITLINE:
return "MEMPROT_DRAM0_DMA_LINE_1_SPLITLINE";
default:
return "UNKNOWN";
}
}
const char *pms_to_str(pms_area_t area_type)
{
switch (area_type) {
case MEMPROT_IRAM0_PMS_AREA_0:
return "MEMPROT_IRAM0_PMS_AREA_0";
case MEMPROT_IRAM0_PMS_AREA_1:
return "MEMPROT_IRAM0_PMS_AREA_1";
case MEMPROT_IRAM0_PMS_AREA_2:
return "MEMPROT_IRAM0_PMS_AREA_2";
case MEMPROT_IRAM0_PMS_AREA_3:
return "MEMPROT_IRAM0_PMS_AREA_3";
case MEMPROT_DRAM0_PMS_AREA_0:
return "MEMPROT_DRAM0_PMS_AREA_0";
case MEMPROT_DRAM0_PMS_AREA_1:
return "MEMPROT_DRAM0_PMS_AREA_1";
case MEMPROT_DRAM0_PMS_AREA_2:
return "MEMPROT_DRAM0_PMS_AREA_2";
case MEMPROT_DRAM0_PMS_AREA_3:
return "MEMPROT_DRAM0_PMS_AREA_3";
default:
return "UNKNOWN";
}
}
/* split lines */
void *esp_memprot_get_main_split_addr()
{
return &_iram_text_end;
}
void esp_memprot_set_split_line_lock(bool lock)
{
memprot_ll_set_iram0_dram0_split_line_lock(lock);
}
bool esp_memprot_get_split_line_lock()
{
return memprot_ll_get_iram0_dram0_split_line_lock();
}
void esp_memprot_set_split_line(split_line_t line_type, const void *line_addr)
{
uint32_t addr = (uint32_t)line_addr;
ESP_LOGD(TAG, "Setting split line %s, addr: 0x%08X", split_line_to_str(line_type), addr);
//split-line must be divisible by 512
assert( addr % 0x200 == 0 );
switch ( line_type ) {
case MEMPROT_IRAM0_DRAM0_SPLITLINE:
memprot_ll_set_iram0_split_line_main_I_D(line_addr);
break;
case MEMPROT_IRAM0_LINE_0_SPLITLINE:
memprot_ll_set_iram0_split_line_I_0(line_addr);
break;
case MEMPROT_IRAM0_LINE_1_SPLITLINE:
memprot_ll_set_iram0_split_line_I_1(line_addr);
break;
case MEMPROT_DRAM0_DMA_LINE_0_SPLITLINE:
memprot_ll_set_dram0_split_line_D_0(line_addr);
break;
case MEMPROT_DRAM0_DMA_LINE_1_SPLITLINE:
memprot_ll_set_dram0_split_line_D_1(line_addr);
break;
default:
ESP_LOGE(TAG, "Invalid split line type, aborting: 0x%08X", addr);
abort();
}
}
// TODO - get split lines
/* PMS */
void esp_memprot_set_pms_lock(mem_type_prot_t mem_type, bool lock)
{
ESP_LOGD(TAG, "esp_memprot_set_pms_lock(%s, %s)", mem_type_to_str(mem_type), lock ? "true" : "false");
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
memprot_ll_iram0_set_pms_lock(lock);
break;
case MEMPROT_DRAM0_SRAM:
memprot_ll_dram0_set_pms_lock(lock);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
bool esp_memprot_get_pms_lock(mem_type_prot_t mem_type)
{
ESP_LOGD(TAG, "esp_memprot_get_pms_lock(%s)", mem_type_to_str(mem_type));
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_pms_lock();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_pms_lock();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
void esp_memprot_iram_set_pms_area(pms_area_t area_type, bool r, bool w, bool x)
{
ESP_LOGD(TAG, "esp_memprot_iram_set_pms_area(area:%s r:%u w:%u, x:%u)", pms_to_str(area_type), r, w, x);
switch ( area_type ) {
case MEMPROT_IRAM0_PMS_AREA_0:
memprot_ll_iram0_set_pms_area_0(r, w, x);
break;
case MEMPROT_IRAM0_PMS_AREA_1:
memprot_ll_iram0_set_pms_area_1(r, w, x);
break;
case MEMPROT_IRAM0_PMS_AREA_2:
memprot_ll_iram0_set_pms_area_2(r, w, x);
break;
case MEMPROT_IRAM0_PMS_AREA_3:
memprot_ll_iram0_set_pms_area_3(r, w, x);
break;
default:
ESP_LOGE(TAG, "Invalid area_type %d", pms_to_str(area_type));
abort();
}
}
void esp_memprot_dram_set_pms_area(pms_area_t area_type, bool r, bool w)
{
ESP_LOGD(TAG, "esp_memprot_dram_set_pms_area(area:%s r:%u w:%u)", pms_to_str(area_type), r, w);
switch ( area_type ) {
case MEMPROT_DRAM0_PMS_AREA_0:
memprot_ll_dram0_set_pms_area_0(r, w);
break;
case MEMPROT_DRAM0_PMS_AREA_1:
memprot_ll_dram0_set_pms_area_1(r, w);
break;
case MEMPROT_DRAM0_PMS_AREA_2:
memprot_ll_dram0_set_pms_area_2(r, w);
break;
case MEMPROT_DRAM0_PMS_AREA_3:
memprot_ll_dram0_set_pms_area_3(r, w);
break;
default:
ESP_LOGE(TAG, "Invalid area_type %d", pms_to_str(area_type));
abort();
}
}
/* TODO - get single areas */
/* monitor */
void esp_memprot_set_monitor_lock(mem_type_prot_t mem_type, bool lock)
{
ESP_LOGD(TAG, "esp_memprot_set_monitor_lock(%s, %s)", mem_type_to_str(mem_type), lock ? "true" : "false");
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
memprot_ll_iram0_set_monitor_lock(lock);
break;
case MEMPROT_DRAM0_SRAM:
memprot_ll_dram0_set_monitor_lock(lock);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
bool esp_memprot_get_monitor_lock(mem_type_prot_t mem_type)
{
ESP_LOGD(TAG, "esp_memprot_get_monitor_lock(%s)", mem_type_to_str(mem_type));
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_lock();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_lock();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
void esp_memprot_set_monitor_en(mem_type_prot_t mem_type, bool enable)
{
ESP_LOGD(TAG, "esp_memprot_set_monitor_en(%s)", mem_type_to_str(mem_type));
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
memprot_ll_iram0_set_monitor_en(enable);
break;
case MEMPROT_DRAM0_SRAM:
memprot_ll_dram0_set_monitor_en(enable);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
bool esp_memprot_get_monitor_en(mem_type_prot_t mem_type)
{
ESP_LOGD(TAG, "esp_memprot_set_monitor_en(%s)", mem_type_to_str(mem_type));
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_en();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_en();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
bool esp_memprot_is_intr_ena_any()
{
return esp_memprot_get_monitor_en(MEMPROT_IRAM0_SRAM) || esp_memprot_get_monitor_en(MEMPROT_DRAM0_SRAM);
}
void esp_memprot_monitor_clear_intr(mem_type_prot_t mem_type)
{
ESP_LOGD(TAG, "esp_memprot_monitor_clear_intr(%s)", mem_type_to_str(mem_type));
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
memprot_ll_iram0_clear_monitor_intr();
break;
case MEMPROT_DRAM0_SRAM:
memprot_ll_dram0_clear_monitor_intr();
break;
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
mem_type_prot_t esp_memprot_get_active_intr_memtype()
{
if ( memprot_ll_iram0_get_monitor_status_intr() > 0 ) {
return MEMPROT_IRAM0_SRAM;
} else if ( memprot_ll_dram0_get_monitor_status_intr() ) {
return MEMPROT_DRAM0_SRAM;
}
return MEMPROT_NONE;
}
bool esp_memprot_is_locked_any()
{
return
esp_memprot_get_split_line_lock() ||
esp_memprot_get_pms_lock(MEMPROT_IRAM0_SRAM) ||
esp_memprot_get_pms_lock(MEMPROT_DRAM0_SRAM) ||
esp_memprot_get_monitor_lock(MEMPROT_IRAM0_SRAM) ||
esp_memprot_get_monitor_lock(MEMPROT_DRAM0_SRAM);
}
uint32_t esp_memprot_get_violate_intr_on(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_status_intr();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_status_intr();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
uint32_t esp_memprot_get_violate_addr(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_status_fault_addr();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_status_fault_addr();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
uint32_t esp_memprot_get_violate_world(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_status_fault_world();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_status_fault_world();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
uint32_t esp_memprot_get_violate_wr(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_status_fault_wr();
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_status_fault_wr();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
uint32_t esp_memprot_get_violate_loadstore(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_IRAM0_SRAM:
return memprot_ll_iram0_get_monitor_status_fault_loadstore();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
uint32_t esp_memprot_get_violate_byte_en(mem_type_prot_t mem_type)
{
switch ( mem_type ) {
case MEMPROT_DRAM0_SRAM:
return memprot_ll_dram0_get_monitor_status_fault_byte_en();
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
}
int esp_memprot_intr_get_cpuid()
{
return PRO_CPU_NUM;
}
void esp_memprot_set_intr_matrix(mem_type_prot_t mem_type)
{
ESP_LOGD(TAG, "esp_memprot_set_intr_matrix(%s)", mem_type_to_str(mem_type));
ESP_INTR_DISABLE(ETS_MEMPROT_ERR_INUM);
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
intr_matrix_set(esp_memprot_intr_get_cpuid(), memprot_ll_iram0_get_intr_source_num(), ETS_MEMPROT_ERR_INUM);
break;
case MEMPROT_DRAM0_SRAM:
intr_matrix_set(esp_memprot_intr_get_cpuid(), memprot_ll_dram0_get_intr_source_num(), ETS_MEMPROT_ERR_INUM);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type (%s), aborting", mem_type_to_str(mem_type));
abort();
}
/* Set the type and priority to cache error interrupts. */
esprv_intc_int_set_type(BIT(ETS_MEMPROT_ERR_INUM), INTR_TYPE_LEVEL);
esprv_intc_int_set_priority(ETS_MEMPROT_ERR_INUM, SOC_INTERRUPT_LEVEL_MEDIUM);
ESP_INTR_ENABLE(ETS_MEMPROT_ERR_INUM);
}
void esp_memprot_set_prot(bool invoke_panic_handler, bool lock_feature, uint32_t *mem_type_mask)
{
esp_memprot_set_prot_int(invoke_panic_handler, lock_feature, NULL, mem_type_mask);
}
void esp_memprot_set_prot_int(bool invoke_panic_handler, bool lock_feature, void *split_addr, uint32_t *mem_type_mask)
{
ESP_LOGD(TAG, "esp_memprot_set_prot(panic_handler: %u, lock: %u, split.addr: 0x%08X, mem.types: 0x%08X", invoke_panic_handler, lock_feature, (uint32_t)split_addr, (uint32_t)mem_type_mask);
uint32_t required_mem_prot = mem_type_mask == NULL ? (uint32_t)MEMPROT_ALL : *mem_type_mask;
bool use_iram0 = required_mem_prot & MEMPROT_IRAM0_SRAM;
bool use_dram0 = required_mem_prot & MEMPROT_DRAM0_SRAM;
if (required_mem_prot == MEMPROT_NONE) {
return;
}
//disable protection
if (use_iram0) {
esp_memprot_set_monitor_en(MEMPROT_IRAM0_SRAM, false);
}
if (use_dram0) {
esp_memprot_set_monitor_en(MEMPROT_DRAM0_SRAM, false);
}
//panic handling
if (invoke_panic_handler) {
if (use_iram0) {
esp_memprot_set_intr_matrix(MEMPROT_IRAM0_SRAM);
}
if (use_dram0) {
esp_memprot_set_intr_matrix(MEMPROT_DRAM0_SRAM);
}
}
//set split lines (must-have for all mem_types)
const void *line_addr = split_addr == NULL ? esp_memprot_get_main_split_addr() : split_addr;
esp_memprot_set_split_line(MEMPROT_IRAM0_LINE_1_SPLITLINE, line_addr);
esp_memprot_set_split_line(MEMPROT_IRAM0_LINE_0_SPLITLINE, line_addr);
esp_memprot_set_split_line(MEMPROT_IRAM0_DRAM0_SPLITLINE, line_addr);
esp_memprot_set_split_line(MEMPROT_DRAM0_DMA_LINE_0_SPLITLINE, (void *)(MAP_IRAM_TO_DRAM((uint32_t)line_addr)));
esp_memprot_set_split_line(MEMPROT_DRAM0_DMA_LINE_1_SPLITLINE, (void *)(MAP_IRAM_TO_DRAM((uint32_t)line_addr)));
//set permissions
if (required_mem_prot & MEMPROT_IRAM0_SRAM) {
esp_memprot_iram_set_pms_area(MEMPROT_IRAM0_PMS_AREA_0, true, false, true);
esp_memprot_iram_set_pms_area(MEMPROT_IRAM0_PMS_AREA_1, true, false, true);
esp_memprot_iram_set_pms_area(MEMPROT_IRAM0_PMS_AREA_2, true, false, true);
esp_memprot_iram_set_pms_area(MEMPROT_IRAM0_PMS_AREA_3, true, true, false);
}
if (required_mem_prot & MEMPROT_DRAM0_SRAM) {
esp_memprot_dram_set_pms_area( MEMPROT_DRAM0_PMS_AREA_0, true, false );
esp_memprot_dram_set_pms_area(MEMPROT_DRAM0_PMS_AREA_1, true, true);
esp_memprot_dram_set_pms_area(MEMPROT_DRAM0_PMS_AREA_2, true, true);
esp_memprot_dram_set_pms_area(MEMPROT_DRAM0_PMS_AREA_3, true, true);
}
//reenable protection
if (use_iram0) {
esp_memprot_monitor_clear_intr(MEMPROT_IRAM0_SRAM);
esp_memprot_set_monitor_en(MEMPROT_IRAM0_SRAM, true);
}
if (use_dram0) {
esp_memprot_monitor_clear_intr(MEMPROT_DRAM0_SRAM);
esp_memprot_set_monitor_en(MEMPROT_DRAM0_SRAM, true);
}
//lock if required
if (lock_feature) {
esp_memprot_set_split_line_lock(true);
if (use_iram0) {
esp_memprot_set_pms_lock(MEMPROT_IRAM0_SRAM, true);
esp_memprot_set_monitor_lock(MEMPROT_IRAM0_SRAM, true);
}
if (use_dram0) {
esp_memprot_set_pms_lock(MEMPROT_DRAM0_SRAM, true);
esp_memprot_set_monitor_lock(MEMPROT_DRAM0_SRAM, true);
}
}
}