esp-idf/components/spi_flash/flash_ops.c

781 lines
25 KiB
C

// Copyright 2015-2016 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.
#include <stdlib.h>
#include <assert.h>
#include <string.h>
#include <stdio.h>
#include <sys/param.h> // For MIN/MAX(a, b)
#include <freertos/FreeRTOS.h>
#include <freertos/task.h>
#include <freertos/semphr.h>
#include <esp32/rom/spi_flash.h>
#include <esp32/rom/cache.h>
#include <soc/soc.h>
#include <soc/dport_reg.h>
#include <soc/soc_memory_layout.h>
#include "sdkconfig.h"
#include "esp_ipc.h"
#include "esp_attr.h"
#include "esp_spi_flash.h"
#include "esp_log.h"
#if CONFIG_IDF_TARGET_ESP32
#include "esp32/clk.h"
#elif CONFIG_IDF_TARGET_ESP32S2BETA
#include "esp32s2beta/clk.h"
#include "soc/spi_mem_reg.h"
#include "soc/spi_mem_struct.h"
#endif
#include "esp_flash_partitions.h"
#include "cache_utils.h"
#include "esp_flash.h"
/* bytes erased by SPIEraseBlock() ROM function */
#define BLOCK_ERASE_SIZE 65536
/* Limit number of bytes written/read in a single SPI operation,
as these operations disable all higher priority tasks from running.
*/
#define MAX_WRITE_CHUNK 8192
#define MAX_READ_CHUNK 16384
static const char *TAG __attribute__((unused)) = "spi_flash";
#if CONFIG_SPI_FLASH_ENABLE_COUNTERS
static spi_flash_counters_t s_flash_stats;
#define COUNTER_START() uint32_t ts_begin = xthal_get_ccount()
#define COUNTER_STOP(counter) \
do{ \
s_flash_stats.counter.count++; \
s_flash_stats.counter.time += (xthal_get_ccount() - ts_begin) / (esp_clk_cpu_freq() / 1000000); \
} while(0)
#define COUNTER_ADD_BYTES(counter, size) \
do { \
s_flash_stats.counter.bytes += size; \
} while (0)
#else
#define COUNTER_START()
#define COUNTER_STOP(counter)
#define COUNTER_ADD_BYTES(counter, size)
#endif //CONFIG_SPI_FLASH_ENABLE_COUNTERS
static esp_err_t spi_flash_translate_rc(esp_rom_spiflash_result_t rc);
static bool is_safe_write_address(size_t addr, size_t size);
const DRAM_ATTR spi_flash_guard_funcs_t g_flash_guard_default_ops = {
.start = spi_flash_disable_interrupts_caches_and_other_cpu,
.end = spi_flash_enable_interrupts_caches_and_other_cpu,
.op_lock = spi_flash_op_lock,
.op_unlock = spi_flash_op_unlock,
#if !CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
.is_safe_write_address = is_safe_write_address
#endif
};
const DRAM_ATTR spi_flash_guard_funcs_t g_flash_guard_no_os_ops = {
.start = spi_flash_disable_interrupts_caches_and_other_cpu_no_os,
.end = spi_flash_enable_interrupts_caches_no_os,
.op_lock = 0,
.op_unlock = 0,
#if !CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
.is_safe_write_address = 0
#endif
};
static const spi_flash_guard_funcs_t *s_flash_guard_ops;
#ifdef CONFIG_SPI_FLASH_DANGEROUS_WRITE_ABORTS
#define UNSAFE_WRITE_ADDRESS abort()
#else
#define UNSAFE_WRITE_ADDRESS return false
#endif
/* CHECK_WRITE_ADDRESS macro to fail writes which land in the
bootloader, partition table, or running application region.
*/
#if CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
#define CHECK_WRITE_ADDRESS(ADDR, SIZE)
#else /* FAILS or ABORTS */
#define CHECK_WRITE_ADDRESS(ADDR, SIZE) do { \
if (s_flash_guard_ops && s_flash_guard_ops->is_safe_write_address && !s_flash_guard_ops->is_safe_write_address(ADDR, SIZE)) { \
return ESP_ERR_INVALID_ARG; \
} \
} while(0)
#endif // CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
static __attribute__((unused)) bool is_safe_write_address(size_t addr, size_t size)
{
if (!esp_partition_main_flash_region_safe(addr, size)) {
UNSAFE_WRITE_ADDRESS;
}
return true;
}
void spi_flash_init(void)
{
spi_flash_init_lock();
#if CONFIG_SPI_FLASH_ENABLE_COUNTERS
spi_flash_reset_counters();
#endif
}
void IRAM_ATTR spi_flash_guard_set(const spi_flash_guard_funcs_t *funcs)
{
s_flash_guard_ops = funcs;
}
const spi_flash_guard_funcs_t *IRAM_ATTR spi_flash_guard_get(void)
{
return s_flash_guard_ops;
}
size_t IRAM_ATTR spi_flash_get_chip_size(void)
{
return g_rom_flashchip.chip_size;
}
static inline void IRAM_ATTR spi_flash_guard_start(void)
{
if (s_flash_guard_ops && s_flash_guard_ops->start) {
s_flash_guard_ops->start();
}
}
static inline void IRAM_ATTR spi_flash_guard_end(void)
{
if (s_flash_guard_ops && s_flash_guard_ops->end) {
s_flash_guard_ops->end();
}
}
static inline void IRAM_ATTR spi_flash_guard_op_lock(void)
{
if (s_flash_guard_ops && s_flash_guard_ops->op_lock) {
s_flash_guard_ops->op_lock();
}
}
static inline void IRAM_ATTR spi_flash_guard_op_unlock(void)
{
if (s_flash_guard_ops && s_flash_guard_ops->op_unlock) {
s_flash_guard_ops->op_unlock();
}
}
#ifdef CONFIG_SPI_FLASH_USE_LEGACY_IMPL
static esp_rom_spiflash_result_t IRAM_ATTR spi_flash_unlock(void)
{
static bool unlocked = false;
if (!unlocked) {
spi_flash_guard_start();
esp_rom_spiflash_result_t rc = esp_rom_spiflash_unlock();
spi_flash_guard_end();
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
return rc;
}
unlocked = true;
}
return ESP_ROM_SPIFLASH_RESULT_OK;
}
#else
static esp_rom_spiflash_result_t IRAM_ATTR spi_flash_unlock(void)
{
esp_err_t err = esp_flash_set_chip_write_protect(NULL, false);
if (err != ESP_OK) {
return ESP_ROM_SPIFLASH_RESULT_ERR;
}
return ESP_ROM_SPIFLASH_RESULT_OK;
}
#endif // CONFIG_SPI_FLASH_USE_LEGACY_IMPL
esp_err_t IRAM_ATTR spi_flash_erase_sector(size_t sec)
{
CHECK_WRITE_ADDRESS(sec * SPI_FLASH_SEC_SIZE, SPI_FLASH_SEC_SIZE);
return spi_flash_erase_range(sec * SPI_FLASH_SEC_SIZE, SPI_FLASH_SEC_SIZE);
}
#ifdef CONFIG_SPI_FLASH_USE_LEGACY_IMPL
//deprecated, only used in compatible mode
esp_err_t IRAM_ATTR spi_flash_erase_range(size_t start_addr, size_t size)
{
CHECK_WRITE_ADDRESS(start_addr, size);
if (start_addr % SPI_FLASH_SEC_SIZE != 0) {
return ESP_ERR_INVALID_ARG;
}
if (size % SPI_FLASH_SEC_SIZE != 0) {
return ESP_ERR_INVALID_SIZE;
}
if (size + start_addr > spi_flash_get_chip_size()) {
return ESP_ERR_INVALID_SIZE;
}
size_t start = start_addr / SPI_FLASH_SEC_SIZE;
size_t end = start + size / SPI_FLASH_SEC_SIZE;
const size_t sectors_per_block = BLOCK_ERASE_SIZE / SPI_FLASH_SEC_SIZE;
COUNTER_START();
esp_rom_spiflash_result_t rc;
rc = spi_flash_unlock();
if (rc == ESP_ROM_SPIFLASH_RESULT_OK) {
for (size_t sector = start; sector != end && rc == ESP_ROM_SPIFLASH_RESULT_OK; ) {
spi_flash_guard_start();
if (sector % sectors_per_block == 0 && end - sector >= sectors_per_block) {
rc = esp_rom_spiflash_erase_block(sector / sectors_per_block);
sector += sectors_per_block;
COUNTER_ADD_BYTES(erase, sectors_per_block * SPI_FLASH_SEC_SIZE);
} else {
rc = esp_rom_spiflash_erase_sector(sector);
++sector;
COUNTER_ADD_BYTES(erase, SPI_FLASH_SEC_SIZE);
}
spi_flash_guard_end();
}
}
COUNTER_STOP(erase);
spi_flash_guard_start();
spi_flash_check_and_flush_cache(start_addr, size);
spi_flash_guard_end();
return spi_flash_translate_rc(rc);
}
/* Wrapper around esp_rom_spiflash_write() that verifies data as written if CONFIG_SPI_FLASH_VERIFY_WRITE is set.
If CONFIG_SPI_FLASH_VERIFY_WRITE is not set, this is esp_rom_spiflash_write().
*/
static IRAM_ATTR esp_rom_spiflash_result_t spi_flash_write_inner(uint32_t target, const uint32_t *src_addr, int32_t len)
{
#ifndef CONFIG_SPI_FLASH_VERIFY_WRITE
return esp_rom_spiflash_write(target, src_addr, len);
#else // CONFIG_SPI_FLASH_VERIFY_WRITE
esp_rom_spiflash_result_t res = ESP_ROM_SPIFLASH_RESULT_OK;
assert(len % sizeof(uint32_t) == 0);
uint32_t before_buf[ESP_ROM_SPIFLASH_BUFF_BYTE_READ_NUM / sizeof(uint32_t)];
uint32_t after_buf[ESP_ROM_SPIFLASH_BUFF_BYTE_READ_NUM / sizeof(uint32_t)];
int32_t remaining = len;
for(int i = 0; i < len; i += sizeof(before_buf)) {
int i_w = i / sizeof(uint32_t); // index in words (i is an index in bytes)
int32_t read_len = MIN(sizeof(before_buf), remaining);
// Read "before" contents from flash
res = esp_rom_spiflash_read(target + i, before_buf, read_len);
if (res != ESP_ROM_SPIFLASH_RESULT_OK) {
break;
}
#ifdef CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
for (int r = 0; r < read_len; r += sizeof(uint32_t)) {
int r_w = r / sizeof(uint32_t); // index in words (r is index in bytes)
uint32_t write = src_addr[i_w + r_w];
uint32_t before = before_buf[r_w];
if ((before & write) != write) {
spi_flash_guard_end();
ESP_LOGW(TAG, "Write at offset 0x%x requests 0x%08x but will write 0x%08x -> 0x%08x",
target + i + r, write, before, before & write);
spi_flash_guard_start();
}
}
#endif
res = esp_rom_spiflash_write(target + i, &src_addr[i_w], read_len);
if (res != ESP_ROM_SPIFLASH_RESULT_OK) {
break;
}
res = esp_rom_spiflash_read(target + i, after_buf, read_len);
if (res != ESP_ROM_SPIFLASH_RESULT_OK) {
break;
}
for (int r = 0; r < read_len; r += sizeof(uint32_t)) {
int r_w = r / sizeof(uint32_t); // index in words (r is index in bytes)
uint32_t expected = src_addr[i_w + r_w] & before_buf[r_w];
uint32_t actual = after_buf[r_w];
if (expected != actual) {
#ifdef CONFIG_SPI_FLASH_LOG_FAILED_WRITE
spi_flash_guard_end();
ESP_LOGE(TAG, "Bad write at offset 0x%x expected 0x%08x readback 0x%08x", target + i + r, expected, actual);
spi_flash_guard_start();
#endif
res = ESP_ROM_SPIFLASH_RESULT_ERR;
}
}
if (res != ESP_ROM_SPIFLASH_RESULT_OK) {
break;
}
remaining -= read_len;
}
return res;
#endif // CONFIG_SPI_FLASH_VERIFY_WRITE
}
esp_err_t IRAM_ATTR spi_flash_write(size_t dst, const void *srcv, size_t size)
{
CHECK_WRITE_ADDRESS(dst, size);
// Out of bound writes are checked in ROM code, but we can give better
// error code here
if (dst + size > g_rom_flashchip.chip_size) {
return ESP_ERR_INVALID_SIZE;
}
if (size == 0) {
return ESP_OK;
}
esp_rom_spiflash_result_t rc = ESP_ROM_SPIFLASH_RESULT_OK;
COUNTER_START();
const uint8_t *srcc = (const uint8_t *) srcv;
/*
* Large operations are split into (up to) 3 parts:
* - Left padding: 4 bytes up to the first 4-byte aligned destination offset.
* - Middle part
* - Right padding: 4 bytes from the last 4-byte aligned offset covered.
*/
size_t left_off = dst & ~3U;
size_t left_size = MIN(((dst + 3) & ~3U) - dst, size);
size_t mid_off = left_size;
size_t mid_size = (size - left_size) & ~3U;
size_t right_off = left_size + mid_size;
size_t right_size = size - mid_size - left_size;
rc = spi_flash_unlock();
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
if (left_size > 0) {
uint32_t t = 0xffffffff;
memcpy(((uint8_t *) &t) + (dst - left_off), srcc, left_size);
spi_flash_guard_start();
rc = spi_flash_write_inner(left_off, &t, 4);
spi_flash_guard_end();
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
COUNTER_ADD_BYTES(write, 4);
}
if (mid_size > 0) {
/* If src buffer is 4-byte aligned as well and is not in a region that requires cache access to be enabled, we
* can write directly without buffering in RAM. */
#ifdef ESP_PLATFORM
bool direct_write = esp_ptr_internal(srcc)
&& esp_ptr_byte_accessible(srcc)
&& ((uintptr_t) srcc + mid_off) % 4 == 0;
#else
bool direct_write = true;
#endif
while(mid_size > 0 && rc == ESP_ROM_SPIFLASH_RESULT_OK) {
uint32_t write_buf[8];
uint32_t write_size = MIN(mid_size, MAX_WRITE_CHUNK);
const uint8_t *write_src = srcc + mid_off;
if (!direct_write) {
write_size = MIN(write_size, sizeof(write_buf));
memcpy(write_buf, write_src, write_size);
write_src = (const uint8_t *)write_buf;
}
spi_flash_guard_start();
rc = spi_flash_write_inner(dst + mid_off, (const uint32_t *) write_src, write_size);
spi_flash_guard_end();
COUNTER_ADD_BYTES(write, write_size);
mid_size -= write_size;
mid_off += write_size;
}
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
}
if (right_size > 0) {
uint32_t t = 0xffffffff;
memcpy(&t, srcc + right_off, right_size);
spi_flash_guard_start();
rc = spi_flash_write_inner(dst + right_off, &t, 4);
spi_flash_guard_end();
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
COUNTER_ADD_BYTES(write, 4);
}
out:
COUNTER_STOP(write);
spi_flash_guard_start();
spi_flash_check_and_flush_cache(dst, size);
spi_flash_guard_end();
return spi_flash_translate_rc(rc);
}
#endif // CONFIG_SPI_FLASH_USE_LEGACY_IMPL
esp_err_t IRAM_ATTR spi_flash_write_encrypted(size_t dest_addr, const void *src, size_t size)
{
CHECK_WRITE_ADDRESS(dest_addr, size);
const uint8_t *ssrc = (const uint8_t *)src;
if ((dest_addr % 16) != 0) {
return ESP_ERR_INVALID_ARG;
}
if ((size % 16) != 0) {
return ESP_ERR_INVALID_SIZE;
}
COUNTER_START();
esp_rom_spiflash_result_t rc;
rc = spi_flash_unlock();
if (rc == ESP_ROM_SPIFLASH_RESULT_OK) {
/* esp_rom_spiflash_write_encrypted encrypts data in RAM as it writes,
so copy to a temporary buffer - 32 bytes at a time.
Each call to esp_rom_spiflash_write_encrypted takes a 32 byte "row" of
data to encrypt, and each row is two 16 byte AES blocks
that share a key (as derived from flash address).
*/
uint8_t encrypt_buf[32] __attribute__((aligned(4)));
uint32_t row_size;
for (size_t i = 0; i < size; i += row_size) {
uint32_t row_addr = dest_addr + i;
if (i == 0 && (row_addr % 32) != 0) {
/* writing to second block of a 32 byte row */
row_size = 16;
row_addr -= 16;
/* copy to second block in buffer */
memcpy(encrypt_buf + 16, ssrc + i, 16);
/* decrypt the first block from flash, will reencrypt to same bytes */
spi_flash_read_encrypted(row_addr, encrypt_buf, 16);
} else if (size - i == 16) {
/* 16 bytes left, is first block of a 32 byte row */
row_size = 16;
/* copy to first block in buffer */
memcpy(encrypt_buf, ssrc + i, 16);
/* decrypt the second block from flash, will reencrypt to same bytes */
spi_flash_read_encrypted(row_addr + 16, encrypt_buf + 16, 16);
} else {
/* Writing a full 32 byte row (2 blocks) */
row_size = 32;
memcpy(encrypt_buf, ssrc + i, 32);
}
spi_flash_guard_start();
rc = esp_rom_spiflash_write_encrypted(row_addr, (uint32_t *)encrypt_buf, 32);
spi_flash_guard_end();
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
break;
}
}
bzero(encrypt_buf, sizeof(encrypt_buf));
}
COUNTER_ADD_BYTES(write, size);
COUNTER_STOP(write);
spi_flash_guard_start();
spi_flash_check_and_flush_cache(dest_addr, size);
spi_flash_guard_end();
return spi_flash_translate_rc(rc);
}
#ifdef CONFIG_SPI_FLASH_USE_LEGACY_IMPL
esp_err_t IRAM_ATTR spi_flash_read(size_t src, void *dstv, size_t size)
{
// Out of bound reads are checked in ROM code, but we can give better
// error code here
if (src + size > g_rom_flashchip.chip_size) {
return ESP_ERR_INVALID_SIZE;
}
if (size == 0) {
return ESP_OK;
}
esp_rom_spiflash_result_t rc = ESP_ROM_SPIFLASH_RESULT_OK;
COUNTER_START();
spi_flash_guard_start();
/* To simplify boundary checks below, we handle small reads separately. */
if (size < 16) {
uint32_t t[6]; /* Enough for 16 bytes + 4 on either side for padding. */
uint32_t read_src = src & ~3U;
uint32_t left_off = src & 3U;
uint32_t read_size = (left_off + size + 3) & ~3U;
rc = esp_rom_spiflash_read(read_src, t, read_size);
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
COUNTER_ADD_BYTES(read, read_size);
memcpy(dstv, ((uint8_t *) t) + left_off, size);
goto out;
}
uint8_t *dstc = (uint8_t *) dstv;
intptr_t dsti = (intptr_t) dstc;
/*
* Large operations are split into (up to) 3 parts:
* - The middle part: from the first 4-aligned position in src to the first
* 4-aligned position in dst.
*/
size_t src_mid_off = (src % 4 == 0 ? 0 : 4 - (src % 4));
size_t dst_mid_off = (dsti % 4 == 0 ? 0 : 4 - (dsti % 4));
size_t mid_size = (size - MAX(src_mid_off, dst_mid_off)) & ~3U;
/*
* - Once the middle part is in place, src_mid_off bytes from the preceding
* 4-aligned source location are added on the left.
*/
size_t pad_left_src = src & ~3U;
size_t pad_left_size = src_mid_off;
/*
* - Finally, the right part is added: from the end of the middle part to
* the end. Depending on the alignment of source and destination, this may
* be a 4 or 8 byte read from pad_right_src.
*/
size_t pad_right_src = (src + pad_left_size + mid_size) & ~3U;
size_t pad_right_off = (pad_right_src - src);
size_t pad_right_size = (size - pad_right_off);
#ifdef ESP_PLATFORM
bool direct_read = esp_ptr_internal(dstc)
&& esp_ptr_byte_accessible(dstc)
&& ((uintptr_t) dstc + dst_mid_off) % 4 == 0;
#else
bool direct_read = true;
#endif
if (mid_size > 0) {
uint32_t mid_remaining = mid_size;
uint32_t mid_read = 0;
while (mid_remaining > 0) {
uint32_t read_size = MIN(mid_remaining, MAX_READ_CHUNK);
uint32_t read_buf[8];
uint8_t *read_dst_final = dstc + dst_mid_off + mid_read;
uint8_t *read_dst = read_dst_final;
if (!direct_read) {
read_size = MIN(read_size, sizeof(read_buf));
read_dst = (uint8_t *) read_buf;
}
rc = esp_rom_spiflash_read(src + src_mid_off + mid_read,
(uint32_t *) read_dst, read_size);
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
mid_remaining -= read_size;
mid_read += read_size;
if (!direct_read) {
spi_flash_guard_end();
memcpy(read_dst_final, read_buf, read_size);
spi_flash_guard_start();
} else if (mid_remaining > 0) {
/* Drop guard momentarily, allows other tasks to preempt */
spi_flash_guard_end();
spi_flash_guard_start();
}
}
COUNTER_ADD_BYTES(read, mid_size);
/*
* If offsets in src and dst are different, perform an in-place shift
* to put destination data into its final position.
* Note that the shift can be left (src_mid_off < dst_mid_off) or right.
*/
if (src_mid_off != dst_mid_off) {
if (!direct_read) {
spi_flash_guard_end();
}
memmove(dstc + src_mid_off, dstc + dst_mid_off, mid_size);
if (!direct_read) {
spi_flash_guard_start();
}
}
}
if (pad_left_size > 0) {
uint32_t t;
rc = esp_rom_spiflash_read(pad_left_src, &t, 4);
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
COUNTER_ADD_BYTES(read, 4);
if (!direct_read) {
spi_flash_guard_end();
}
memcpy(dstc, ((uint8_t *) &t) + (4 - pad_left_size), pad_left_size);
if (!direct_read) {
spi_flash_guard_start();
}
}
if (pad_right_size > 0) {
uint32_t t[2];
int32_t read_size = (pad_right_size <= 4 ? 4 : 8);
rc = esp_rom_spiflash_read(pad_right_src, t, read_size);
if (rc != ESP_ROM_SPIFLASH_RESULT_OK) {
goto out;
}
COUNTER_ADD_BYTES(read, read_size);
if (!direct_read) {
spi_flash_guard_end();
}
memcpy(dstc + pad_right_off, t, pad_right_size);
if (!direct_read) {
spi_flash_guard_start();
}
}
out:
spi_flash_guard_end();
COUNTER_STOP(read);
return spi_flash_translate_rc(rc);
}
#endif
esp_err_t IRAM_ATTR spi_flash_read_encrypted(size_t src, void *dstv, size_t size)
{
if (src + size > g_rom_flashchip.chip_size) {
return ESP_ERR_INVALID_SIZE;
}
if (size == 0) {
return ESP_OK;
}
esp_err_t err;
const uint8_t *map;
spi_flash_mmap_handle_t map_handle;
size_t map_src = src & ~(SPI_FLASH_MMU_PAGE_SIZE - 1);
size_t map_size = size + (src - map_src);
err = spi_flash_mmap(map_src, map_size, SPI_FLASH_MMAP_DATA, (const void **)&map, &map_handle);
if (err != ESP_OK) {
return err;
}
memcpy(dstv, map + (src - map_src), size);
spi_flash_munmap(map_handle);
return err;
}
static esp_err_t IRAM_ATTR spi_flash_translate_rc(esp_rom_spiflash_result_t rc)
{
switch (rc) {
case ESP_ROM_SPIFLASH_RESULT_OK:
return ESP_OK;
case ESP_ROM_SPIFLASH_RESULT_TIMEOUT:
return ESP_ERR_FLASH_OP_TIMEOUT;
case ESP_ROM_SPIFLASH_RESULT_ERR:
default:
return ESP_ERR_FLASH_OP_FAIL;
}
}
#if CONFIG_SPI_FLASH_ENABLE_COUNTERS
static inline void dump_counter(spi_flash_counter_t *counter, const char *name)
{
ESP_LOGI(TAG, "%s count=%8d time=%8dus bytes=%8d\n", name,
counter->count, counter->time, counter->bytes);
}
const spi_flash_counters_t *spi_flash_get_counters(void)
{
return &s_flash_stats;
}
void spi_flash_reset_counters(void)
{
memset(&s_flash_stats, 0, sizeof(s_flash_stats));
}
void spi_flash_dump_counters(void)
{
dump_counter(&s_flash_stats.read, "read ");
dump_counter(&s_flash_stats.write, "write");
dump_counter(&s_flash_stats.erase, "erase");
}
#endif //CONFIG_SPI_FLASH_ENABLE_COUNTERS
#if CONFIG_IDF_TARGET_ESP32S2BETA
#define SPICACHE SPIMEM0
#define SPIFLASH SPIMEM1
#define FLASH_WRAP_CMD 0x77
esp_err_t spi_flash_wrap_set(spi_flash_wrap_mode_t mode)
{
uint32_t reg_bkp_ctrl = SPIFLASH.ctrl.val;
uint32_t reg_bkp_usr = SPIFLASH.user.val;
SPIFLASH.user.fwrite_dio = 0;
SPIFLASH.user.fwrite_dual = 0;
SPIFLASH.user.fwrite_qio = 1;
SPIFLASH.user.fwrite_quad = 0;
SPIFLASH.ctrl.fcmd_dual = 0;
SPIFLASH.ctrl.fcmd_quad = 0;
SPIFLASH.user.usr_dummy = 0;
SPIFLASH.user.usr_addr = 1;
SPIFLASH.user.usr_command = 1;
SPIFLASH.user2.usr_command_bitlen = 7;
SPIFLASH.user2.usr_command_value = FLASH_WRAP_CMD;
SPIFLASH.user1.usr_addr_bitlen = 23;
SPIFLASH.addr = 0;
SPIFLASH.user.usr_miso = 0;
SPIFLASH.user.usr_mosi = 1;
SPIFLASH.mosi_dlen.usr_mosi_bit_len = 7;
SPIFLASH.data_buf[0] = (uint32_t) mode << 4;;
SPIFLASH.cmd.usr = 1;
while(SPIFLASH.cmd.usr != 0)
{ }
SPIFLASH.ctrl.val = reg_bkp_ctrl;
SPIFLASH.user.val = reg_bkp_usr;
return ESP_OK;
}
esp_err_t spi_flash_enable_wrap(uint32_t wrap_size)
{
switch(wrap_size) {
case 8:
return spi_flash_wrap_set(FLASH_WRAP_MODE_8B);
case 16:
return spi_flash_wrap_set(FLASH_WRAP_MODE_16B);
case 32:
return spi_flash_wrap_set(FLASH_WRAP_MODE_32B);
case 64:
return spi_flash_wrap_set(FLASH_WRAP_MODE_64B);
default:
return ESP_FAIL;
}
}
void spi_flash_disable_wrap(void)
{
spi_flash_wrap_set(FLASH_WRAP_MODE_DISABLE);
}
bool spi_flash_support_wrap_size(uint32_t wrap_size)
{
if (!REG_GET_BIT(SPI_MEM_CTRL_REG(0), SPI_MEM_FREAD_QIO) || !REG_GET_BIT(SPI_MEM_CTRL_REG(0), SPI_MEM_FASTRD_MODE)){
return ESP_FAIL;
}
switch(wrap_size) {
case 0:
case 8:
case 16:
case 32:
case 64:
return true;
default:
return false;
}
}
#endif
#if defined(CONFIG_SPI_FLASH_USE_LEGACY_IMPL) && defined(CONFIG_IDF_TARGET_ESP32S2BETA)
// TODO esp32s2beta: Remove once ESP32S2Beta has new SPI Flash API support
esp_flash_t *esp_flash_default_chip = NULL;
#endif