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esp-idf/components/esp32s2/memprot.c
Martin Vychodil 497b730e8f * memprot support for RTC_SLOW 
* API upgrade
JIRA IDF-1636
2020-10-08 11:19:23 +08:00

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30 KiB
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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 generic interface to MMU 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 "esp32s2/memprot.h"
#include "hal/memprot_ll.h"
#include "hal/memprot_peri_ll.h"
#include "esp_fault.h"
#include "soc/cpu.h"
extern int _iram_text_end;
extern int _data_start;
extern int _rtc_text_end;
extern int _rtc_dummy_end;
uint32_t *esp_memprot_iram0_sram_get_min_split_addr(void)
{
return (uint32_t *)&_iram_text_end;
}
uint32_t *esp_memprot_iram0_rtcfast_get_min_split_addr(void)
{
return (uint32_t *)&_rtc_text_end;
}
uint32_t *esp_memprot_dram0_sram_get_min_split_addr(void)
{
return (uint32_t *)&_data_start;
}
uint32_t *esp_memprot_dram0_rtcfast_get_min_split_addr(void)
{
return (uint32_t *)&_rtc_dummy_end;
}
uint32_t *esp_memprot_peri1_rtcslow_get_min_split_addr(void)
{
return (uint32_t *)(PERI1_RTCSLOW_ADDRESS_BASE);
}
uint32_t *esp_memprot_peri2_rtcslow_0_get_min_split_addr(void)
{
return (uint32_t *)(PERI2_RTCSLOW_0_ADDRESS_BASE);
}
uint32_t *esp_memprot_peri2_rtcslow_1_get_min_split_addr(void)
{
return (uint32_t *)(PERI2_RTCSLOW_1_ADDRESS_BASE);
}
uint32_t *esp_memprot_get_split_addr(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_min_split_addr();
case MEMPROT_DRAM0_SRAM:
return esp_memprot_dram0_sram_get_min_split_addr();
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_rtcfast_get_min_split_addr();
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_rtcfast_get_min_split_addr();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_rtcslow_get_min_split_addr();
case MEMPROT_PERI2_RTCSLOW_0:
return esp_memprot_peri2_rtcslow_0_get_min_split_addr();
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_rtcslow_1_get_min_split_addr();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
const char *esp_memprot_type_to_str(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return "IRAM0_SRAM";
case MEMPROT_DRAM0_SRAM:
return "DRAM0_SRAM";
case MEMPROT_IRAM0_RTCFAST:
return "IRAM0_RTCFAST";
case MEMPROT_DRAM0_RTCFAST:
return "DRAM0_RTCFAST";
case MEMPROT_PERI1_RTCSLOW:
return "PERI1_RTCSLOW";
case MEMPROT_PERI2_RTCSLOW_0:
return "PERI2_RTCSLOW_0";
case MEMPROT_PERI2_RTCSLOW_1:
return "PERI2_RTCSLOW_1";
default:
return "UNKOWN";
}
}
void esp_memprot_intr_init(mem_type_prot_t mem_type)
{
ESP_INTR_DISABLE(ETS_MEMACCESS_ERR_INUM);
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
intr_matrix_set(PRO_CPU_NUM, esp_memprot_iram0_get_intr_source_num(), ETS_MEMACCESS_ERR_INUM);
break;
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
intr_matrix_set(PRO_CPU_NUM, esp_memprot_dram0_get_intr_source_num(), ETS_MEMACCESS_ERR_INUM);
break;
case MEMPROT_PERI1_RTCSLOW:
intr_matrix_set(PRO_CPU_NUM, esp_memprot_peri1_get_intr_source_num(), ETS_MEMACCESS_ERR_INUM);
break;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
intr_matrix_set(PRO_CPU_NUM, esp_memprot_peri2_get_intr_source_num(), ETS_MEMACCESS_ERR_INUM);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
ESP_INTR_ENABLE(ETS_MEMACCESS_ERR_INUM);
}
void esp_memprot_intr_ena(mem_type_prot_t mem_type, bool enable)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_intr_ena(enable);
break;
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_intr_ena(enable);
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_intr_ena(enable);
break;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_intr_ena(enable);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
mem_type_prot_t esp_memprot_get_active_intr_memtype()
{
if (esp_memprot_iram0_sram_is_intr_mine()) {
return MEMPROT_IRAM0_SRAM;
} else if (esp_memprot_iram0_rtcfast_is_intr_mine()) {
return MEMPROT_IRAM0_RTCFAST;
} else if (esp_memprot_dram0_sram_is_intr_mine()) {
return MEMPROT_DRAM0_SRAM;
} else if (esp_memprot_dram0_rtcfast_is_intr_mine()) {
return MEMPROT_DRAM0_RTCFAST;
} else if (esp_memprot_peri1_rtcslow_is_intr_mine()) {
return MEMPROT_PERI1_RTCSLOW;
} else if (esp_memprot_peri2_rtcslow_0_is_intr_mine()) {
return MEMPROT_PERI2_RTCSLOW_0;
} else if (esp_memprot_peri2_rtcslow_1_is_intr_mine()) {
return MEMPROT_PERI2_RTCSLOW_1;
}
return MEMPROT_NONE;
}
void esp_memprot_clear_intr(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_clear_intr();
break;
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_clear_intr();
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_clear_intr();
break;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_clear_intr();
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_lock(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_set_lock();
break;
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_set_lock();
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_set_lock();
break;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_set_lock();
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
bool esp_memprot_get_lock(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_lock_bit() > 0;
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_lock_bit() > 0;
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_lock_bit() > 0;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_lock_bit() > 0;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
bool esp_memprot_is_locked_any()
{
return
esp_memprot_iram0_get_lock_bit() > 0 ||
esp_memprot_dram0_get_lock_bit() > 0 ||
esp_memprot_peri1_get_lock_bit() > 0 ||
esp_memprot_peri2_get_lock_bit() > 0;
}
uint32_t esp_memprot_get_lock_bit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_lock_bit();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_lock_bit();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_lock_bit();
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_lock_bit();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_conf_reg(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_conf_reg();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_conf_reg();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_rtcslow_get_conf_reg();
case MEMPROT_PERI2_RTCSLOW_0:
return esp_memprot_peri2_rtcslow_0_get_conf_reg();
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_rtcslow_1_get_conf_reg();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_fault_reg(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_fault_reg();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_fault_reg();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_fault_reg();
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_fault_reg();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_fault_status(mem_type_prot_t mem_type, uint32_t **faulting_address, uint32_t *op_type, uint32_t *op_subtype)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
*faulting_address = esp_memprot_iram0_sram_get_fault_address();
break;
case MEMPROT_IRAM0_RTCFAST:
*faulting_address = esp_memprot_iram0_rtcfast_get_fault_address();
break;
case MEMPROT_DRAM0_SRAM:
*faulting_address = esp_memprot_dram0_sram_get_fault_address();
break;
case MEMPROT_DRAM0_RTCFAST:
*faulting_address = esp_memprot_dram0_rtcfast_get_fault_address();
break;
case MEMPROT_PERI1_RTCSLOW:
*faulting_address = esp_memprot_peri1_rtcslow_get_fault_address();
break;
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
*faulting_address = esp_memprot_peri2_rtcslow_get_fault_address();
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
if (mem_type == MEMPROT_IRAM0_SRAM || mem_type == MEMPROT_IRAM0_RTCFAST) {
esp_memprot_iram0_get_fault_op_type(op_type, op_subtype);
} else if (mem_type == MEMPROT_DRAM0_SRAM || mem_type == MEMPROT_DRAM0_RTCFAST) {
esp_memprot_dram0_get_fault_op_type(op_type, op_subtype);
} else if (mem_type == MEMPROT_PERI1_RTCSLOW) {
esp_memprot_peri1_get_fault_op_type(op_type, op_subtype);
} else if (mem_type == MEMPROT_PERI2_RTCSLOW_0 || mem_type == MEMPROT_PERI2_RTCSLOW_1) {
esp_memprot_peri2_get_fault_op_type(op_type, op_subtype);
}
}
bool esp_memprot_is_intr_ena_any()
{
return
esp_memprot_iram0_get_intr_ena_bit() > 0 ||
esp_memprot_dram0_get_intr_ena_bit() > 0 ||
esp_memprot_peri1_get_intr_ena_bit() > 0 ||
esp_memprot_peri2_get_intr_ena_bit() > 0;
}
uint32_t esp_memprot_get_intr_ena_bit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_intr_ena_bit();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_intr_ena_bit();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_intr_ena_bit();
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_intr_ena_bit();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_intr_on_bit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_intr_on_bit();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_intr_on_bit();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_intr_on_bit();
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_intr_on_bit();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_intr_clr_bit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_get_intr_clr_bit();
case MEMPROT_DRAM0_SRAM:
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_get_intr_clr_bit();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_get_intr_clr_bit();
case MEMPROT_PERI2_RTCSLOW_0:
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_get_intr_clr_bit();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_uni_block_read_bit(mem_type_prot_t mem_type, uint32_t block)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_uni_block_read_bit(block);
case MEMPROT_DRAM0_SRAM:
return esp_memprot_dram0_sram_get_uni_block_read_bit(block);
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
uint32_t esp_memprot_get_uni_block_write_bit(mem_type_prot_t mem_type, uint32_t block)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_uni_block_write_bit(block);
case MEMPROT_DRAM0_SRAM:
return esp_memprot_dram0_sram_get_uni_block_write_bit(block);
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
uint32_t esp_memprot_get_uni_block_exec_bit(mem_type_prot_t mem_type, uint32_t block)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_uni_block_exec_bit(block);
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
void esp_memprot_set_uni_block_perm_dram(mem_type_prot_t mem_type, uint32_t block, bool write_perm, bool read_perm)
{
switch (mem_type) {
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_set_uni_block_perm(block, write_perm, read_perm);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
uint32_t esp_memprot_get_perm_uni_reg(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_perm_uni_reg();
case MEMPROT_DRAM0_SRAM:
return esp_memprot_dram0_sram_get_perm_reg();
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
uint32_t esp_memprot_get_perm_split_reg(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return esp_memprot_iram0_sram_get_perm_split_reg();
case MEMPROT_IRAM0_RTCFAST:
return esp_memprot_iram0_rtcfast_get_perm_split_reg();
case MEMPROT_DRAM0_SRAM:
return esp_memprot_dram0_sram_get_perm_reg();
case MEMPROT_DRAM0_RTCFAST:
return esp_memprot_dram0_rtcfast_get_perm_split_reg();
case MEMPROT_PERI1_RTCSLOW:
return esp_memprot_peri1_rtcslow_get_conf_reg();
case MEMPROT_PERI2_RTCSLOW_0:
return esp_memprot_peri2_rtcslow_0_get_conf_reg();
case MEMPROT_PERI2_RTCSLOW_1:
return esp_memprot_peri2_rtcslow_1_get_conf_reg();
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_prot_dram(mem_type_prot_t mem_type, uint32_t *split_addr, bool lw, bool lr, bool hw, bool hr)
{
switch (mem_type) {
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_set_prot(split_addr != NULL ? split_addr : esp_memprot_dram0_sram_get_min_split_addr(), lw, lr, hw, hr);
break;
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_rtcfast_set_prot(split_addr != NULL ? split_addr : esp_memprot_dram0_rtcfast_get_min_split_addr(), lw, lr, hw, hr);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_uni_block_perm_iram(mem_type_prot_t mem_type, uint32_t block, bool write_perm, bool read_perm, bool exec_perm)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_set_uni_block_perm(block, write_perm, read_perm, exec_perm);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d (unified block management not supported)", mem_type);
abort();
}
}
void esp_memprot_set_prot_iram(mem_type_prot_t mem_type, uint32_t *split_addr, bool lw, bool lr, bool lx, bool hw, bool hr, bool hx)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_set_prot(split_addr != NULL ? split_addr : esp_memprot_iram0_sram_get_min_split_addr(), lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_set_prot(split_addr != NULL ? split_addr : esp_memprot_iram0_rtcfast_get_min_split_addr(), lw, lr, lx, hw, hr, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_perm_split_bits_iram(mem_type_prot_t mem_type, bool *lw, bool *lr, bool *lx, bool *hw, bool *hr, bool *hx)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_perm_split_bits_dram(mem_type_prot_t mem_type, bool *lw, bool *lr, bool *hw, bool *hr)
{
switch (mem_type) {
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_get_split_sgnf_bits(lw, lr, hw, hr);
break;
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_rtcfast_get_split_sgnf_bits(lw, lr, hw, hr);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_perm_split_bits_peri1(mem_type_prot_t mem_type, bool *lw, bool *lr, bool *hw, bool *hr)
{
switch (mem_type) {
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_rtcslow_get_split_sgnf_bits(lw, lr, hw, hr);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_prot_peri1(mem_type_prot_t mem_type, uint32_t *split_addr, bool lw, bool lr, bool hw, bool hr)
{
switch (mem_type) {
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_rtcslow_set_prot(split_addr != NULL ? split_addr : esp_memprot_peri1_rtcslow_get_min_split_addr(), lw, lr, hw, hr);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_perm_split_bits_peri2(mem_type_prot_t mem_type, bool *lw, bool *lr, bool *lx, bool *hw, bool *hr, bool *hx)
{
switch (mem_type) {
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_prot_peri2(mem_type_prot_t mem_type, uint32_t *split_addr, bool lw, bool lr, bool lx, bool hw, bool hr, bool hx)
{
switch (mem_type) {
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_set_prot(split_addr != NULL ? split_addr : esp_memprot_peri2_rtcslow_0_get_min_split_addr(), lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_set_prot(split_addr != NULL ? split_addr : esp_memprot_peri2_rtcslow_1_get_min_split_addr(), lw, lr, lx, hw, hr, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_prot(bool invoke_panic_handler, bool lock_feature, uint32_t *mem_type_mask)
{
//any IRAM0/DRAM0 enable/disable call applies to all memory modules connected
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 || required_mem_prot & MEMPROT_IRAM0_RTCFAST;
bool use_dram0 = required_mem_prot & MEMPROT_DRAM0_SRAM || required_mem_prot & MEMPROT_DRAM0_RTCFAST;
bool use_peri1 = required_mem_prot & MEMPROT_PERI1_RTCSLOW;
bool use_peri2 = required_mem_prot & MEMPROT_PERI2_RTCSLOW_0 || required_mem_prot & MEMPROT_PERI2_RTCSLOW_1;
//disable protection
if (use_iram0) {
esp_memprot_intr_ena(MEMPROT_IRAM0_SRAM, false);
}
if (use_dram0) {
esp_memprot_intr_ena(MEMPROT_DRAM0_SRAM, false);
}
if (use_peri1) {
esp_memprot_intr_ena(MEMPROT_PERI1_RTCSLOW, false);
}
if (use_peri2) {
esp_memprot_intr_ena(MEMPROT_PERI2_RTCSLOW_0, false);
}
//connect to intr. matrix if not being debugged
if (!esp_cpu_in_ocd_debug_mode()) {
ESP_FAULT_ASSERT(!esp_cpu_in_ocd_debug_mode());
//initialize for specific buses (any memory type does the job)
if (invoke_panic_handler) {
if (use_iram0) {
esp_memprot_intr_init(MEMPROT_IRAM0_SRAM);
}
if (use_dram0) {
esp_memprot_intr_init(MEMPROT_DRAM0_SRAM);
}
if (use_peri1) {
esp_memprot_intr_init(MEMPROT_PERI1_RTCSLOW);
}
if (use_peri2) {
esp_memprot_intr_init(MEMPROT_PERI2_RTCSLOW_0);
}
}
//set permissions
if (required_mem_prot & MEMPROT_IRAM0_SRAM) {
esp_memprot_set_prot_iram(MEMPROT_IRAM0_SRAM, NULL, false, true, true, true, true, true);
}
if (required_mem_prot & MEMPROT_IRAM0_RTCFAST) {
esp_memprot_set_prot_iram(MEMPROT_IRAM0_RTCFAST, NULL, false, true, true, true, true, true);
}
if (required_mem_prot & MEMPROT_DRAM0_SRAM) {
esp_memprot_set_prot_dram(MEMPROT_DRAM0_SRAM, NULL, false, true, true, true);
}
if (required_mem_prot & MEMPROT_DRAM0_RTCFAST) {
esp_memprot_set_prot_dram(MEMPROT_DRAM0_RTCFAST, NULL, false, true, true, true);
}
if (required_mem_prot & MEMPROT_PERI1_RTCSLOW) {
esp_memprot_set_prot_peri1(MEMPROT_PERI1_RTCSLOW, NULL, true, true, true, true);
}
if (required_mem_prot & MEMPROT_PERI2_RTCSLOW_0) {
esp_memprot_set_prot_peri2(MEMPROT_PERI2_RTCSLOW_0, NULL, true, true, false, true, true, false);
}
if (required_mem_prot & MEMPROT_PERI2_RTCSLOW_1) {
esp_memprot_set_prot_peri2(MEMPROT_PERI2_RTCSLOW_1, NULL, true, true, false, true, true, false);
}
//reenable protection (bus based)
if (use_iram0) {
esp_memprot_intr_ena(MEMPROT_IRAM0_SRAM, true);
}
if (use_dram0) {
esp_memprot_intr_ena(MEMPROT_DRAM0_SRAM, true);
}
if (use_peri1) {
esp_memprot_intr_ena(MEMPROT_PERI1_RTCSLOW, true);
}
if (use_peri2) {
esp_memprot_intr_ena(MEMPROT_PERI2_RTCSLOW_0, true);
}
//lock if required (bus based)
if (lock_feature) {
if (use_iram0) {
esp_memprot_set_lock(MEMPROT_IRAM0_SRAM);
}
if (use_dram0) {
esp_memprot_set_lock(MEMPROT_DRAM0_SRAM);
}
if (use_peri1) {
esp_memprot_set_lock(MEMPROT_PERI1_RTCSLOW);
}
if (use_peri2) {
esp_memprot_set_lock(MEMPROT_PERI2_RTCSLOW_0);
}
}
}
}
void esp_memprot_get_permissions(mem_type_prot_t mem_type, bool *lw, bool *lr, bool *lx, bool *hw, bool *hr, bool *hx)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_get_split_sgnf_bits(lw, lr, hw, hr);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_rtcfast_get_split_sgnf_bits(lw, lr, hw, hr);
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_rtcslow_get_split_sgnf_bits(lw, lr, hw, hr);
break;
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_get_split_sgnf_bits(lw, lr, lx, hw, hr, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_get_perm_read(mem_type_prot_t mem_type, bool *lr, bool *hr)
{
bool _lw, _lr, _lx, _hw, _hr, _hx;
esp_memprot_get_permissions(mem_type, &_lw, &_lr, &_lx, &_hw, &_hr, &_hx);
*lr = _lr;
*hr = _hr;
}
void esp_memprot_get_perm_write(mem_type_prot_t mem_type, bool *lw, bool *hw)
{
bool _lw, _lr, _lx, _hw, _hr, _hx;
esp_memprot_get_permissions(mem_type, &_lw, &_lr, &_lx, &_hw, &_hr, &_hx);
*lw = _lw;
*hw = _hw;
}
void esp_memprot_get_perm_exec(mem_type_prot_t mem_type, bool *lx, bool *hx)
{
if ( mem_type == MEMPROT_DRAM0_SRAM ||
mem_type == MEMPROT_DRAM0_RTCFAST ||
mem_type == MEMPROT_PERI1_RTCSLOW ) {
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
bool _lw, _lr, _lx, _hw, _hr, _hx;
esp_memprot_get_permissions(mem_type, &_lw, &_lr, &_lx, &_hw, &_hr, &_hx);
*lx = _lx;
*hx = _hx;
}
uint32_t esp_memprot_get_low_limit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return IRAM0_SRAM_ADDRESS_LOW;
case MEMPROT_DRAM0_SRAM:
return DRAM0_SRAM_ADDRESS_LOW;
case MEMPROT_IRAM0_RTCFAST:
return IRAM0_RTCFAST_ADDRESS_LOW;
case MEMPROT_DRAM0_RTCFAST:
return DRAM0_RTCFAST_ADDRESS_LOW;
case MEMPROT_PERI1_RTCSLOW:
return PERI1_RTCSLOW_ADDRESS_LOW;
case MEMPROT_PERI2_RTCSLOW_0:
return PERI2_RTCSLOW_0_ADDRESS_LOW;
case MEMPROT_PERI2_RTCSLOW_1:
return PERI2_RTCSLOW_1_ADDRESS_LOW;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
uint32_t esp_memprot_get_high_limit(mem_type_prot_t mem_type)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
return IRAM0_SRAM_ADDRESS_HIGH;
case MEMPROT_DRAM0_SRAM:
return DRAM0_SRAM_ADDRESS_HIGH;
case MEMPROT_IRAM0_RTCFAST:
return IRAM0_RTCFAST_ADDRESS_HIGH;
case MEMPROT_DRAM0_RTCFAST:
return DRAM0_RTCFAST_ADDRESS_HIGH;
case MEMPROT_PERI1_RTCSLOW:
return PERI1_RTCSLOW_ADDRESS_HIGH;
case MEMPROT_PERI2_RTCSLOW_0:
return PERI2_RTCSLOW_0_ADDRESS_HIGH;
case MEMPROT_PERI2_RTCSLOW_1:
return PERI2_RTCSLOW_1_ADDRESS_HIGH;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_read_perm(mem_type_prot_t mem_type, bool lr, bool hr)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_set_read_perm(lr, hr);
break;
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_set_read_perm(lr, hr);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_set_read_perm(lr, hr);
break;
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_rtcfast_set_read_perm(lr, hr);
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_rtcslow_set_read_perm(lr, hr);
break;
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_set_read_perm(lr, hr);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_set_read_perm(lr, hr);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_write_perm(mem_type_prot_t mem_type, bool lw, bool hw)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_set_write_perm(lw, hw);
break;
case MEMPROT_DRAM0_SRAM:
esp_memprot_dram0_sram_set_write_perm(lw, hw);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_set_write_perm(lw, hw);
break;
case MEMPROT_DRAM0_RTCFAST:
esp_memprot_dram0_rtcfast_set_write_perm(lw, hw);
break;
case MEMPROT_PERI1_RTCSLOW:
esp_memprot_peri1_rtcslow_set_write_perm(lw, hw);
break;
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_set_write_perm(lw, hw);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_set_write_perm(lw, hw);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
void esp_memprot_set_exec_perm(mem_type_prot_t mem_type, bool lx, bool hx)
{
switch (mem_type) {
case MEMPROT_IRAM0_SRAM:
esp_memprot_iram0_sram_set_exec_perm(lx, hx);
break;
case MEMPROT_IRAM0_RTCFAST:
esp_memprot_iram0_rtcfast_set_exec_perm(lx, hx);
break;
case MEMPROT_PERI2_RTCSLOW_0:
esp_memprot_peri2_rtcslow_0_set_exec_perm(lx, hx);
break;
case MEMPROT_PERI2_RTCSLOW_1:
esp_memprot_peri2_rtcslow_1_set_exec_perm(lx, hx);
break;
default:
ESP_LOGE(TAG, "Invalid mem_type %d", mem_type);
abort();
}
}
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