// TODO: all called funcs should be in IRAM to work with disabled flash cache
static void * esp_dbg_stubs_data_alloc(uint32_t size)
{
ESP_LOGV(TAG, "%s %d", __func__, size);
void *p = malloc(size);
ESP_LOGV(TAG, "%s EXIT %p", __func__, p);
return p;
}
esp_err_t sdmmc_send_cmd(sdmmc_card_t* card, sdmmc_command_t* cmd)
{
if (card->host.command_timeout_ms != 0) {
cmd->timeout_ms = card->host.command_timeout_ms;
} else if (cmd->timeout_ms == 0) {
cmd->timeout_ms = SDMMC_DEFAULT_CMD_TIMEOUT_MS;
}
int slot = card->host.slot;
ESP_LOGV(TAG, "sending cmd slot=%d op=%d arg=%x flags=%x data=%p blklen=%d datalen=%d timeout=%d",
slot, cmd->opcode, cmd->arg, cmd->flags, cmd->data, cmd->blklen, cmd->datalen, cmd->timeout_ms);
esp_err_t err = (*card->host.do_transaction)(slot, cmd);
if (err != 0) {
ESP_LOGD(TAG, "cmd=%d, sdmmc_req_run returned 0x%x", cmd->opcode, err);
return err;
}
int state = MMC_R1_CURRENT_STATE(cmd->response);
ESP_LOGV(TAG, "cmd response %08x %08x %08x %08x err=0x%x state=%d",
cmd->response[0],
cmd->response[1],
cmd->response[2],
cmd->response[3],
cmd->error,
state);
return cmd->error;
}
void Subscription::feed_data(MQTT_Packet data) {
if(on_received == nullptr) return;
if(data.topic.length() < topic.length()) return;
std::string topicRest;
int i=0;
while(true) {
if(topic.at(i) == '#') {
topicRest = std::string(data.topic.data() + i, data.topic.length() - i);
break;
}
if(topic.at(i) != data.topic.at(i)) return;
i++;
if(i == topic.length()) {
if(i != data.topic.length())
return;
else
break;
}
}
ESP_LOGV(mqtt_tag, "Topic %s matched! (Topic-Rest:%s)", topic.data(), topicRest.data());
on_received({topicRest, data.data});
}
esp_err_t WL_Ext_Perf::erase_sector_fit(uint32_t start_sector, uint32_t count)
{
ESP_LOGV(TAG, "%s begin, start_sector = 0x%08x, count = %i", __func__, start_sector, count);
// This method works with one flash device sector and able to erase "count" of fatfs sectors from this sector
esp_err_t result = ESP_OK;
uint32_t pre_check_start = start_sector % this->size_factor;
for (int i = 0; i < this->size_factor; i++) {
if ((i < pre_check_start) || (i >= count + pre_check_start)) {
result = this->read(start_sector / this->size_factor * this->flash_sector_size + i * this->fat_sector_size, &this->sector_buffer[i * this->fat_sector_size / sizeof(uint32_t)], this->fat_sector_size);
WL_EXT_RESULT_CHECK(result);
}
}
result = WL_Flash::erase_sector(start_sector / this->size_factor); // erase comlete flash sector
WL_EXT_RESULT_CHECK(result);
// And write back only data that should not be erased...
for (int i = 0; i < this->size_factor; i++) {
if ((i < pre_check_start) || (i >= count + pre_check_start)) {
result = this->write(start_sector / this->size_factor * this->flash_sector_size + i * this->fat_sector_size, &this->sector_buffer[i * this->fat_sector_size / sizeof(uint32_t)], this->fat_sector_size);
WL_EXT_RESULT_CHECK(result);
}
}
return ESP_OK;
}
static void spiffs_api_check(spiffs *fs, spiffs_check_type type,
spiffs_check_report report, uint32_t arg1, uint32_t arg2)
{
static const char * spiffs_check_type_str[3] = {
"LOOKUP",
"INDEX",
"PAGE"
};
static const char * spiffs_check_report_str[7] = {
"PROGRESS",
"ERROR",
"FIX INDEX",
"FIX LOOKUP",
"DELETE ORPHANED INDEX",
"DELETE PAGE",
"DELETE BAD FILE"
};
if (report != SPIFFS_CHECK_PROGRESS) {
ESP_LOGE(TAG, "CHECK: type:%s, report:%s, %x:%x", spiffs_check_type_str[type],
spiffs_check_report_str[report], arg1, arg2);
} else {
ESP_LOGV(TAG, "CHECK PROGRESS: report:%s, %x:%x",
spiffs_check_report_str[report], arg1, arg2);
}
}
/**
* @brief Take a semaphore.
* Take a semaphore but return if we haven't obtained it in the given period of milliseconds.
* @param [in] timeoutMs Timeout in milliseconds.
* @param [in] owner The new owner (for debugging)
* @return True if we took the semaphore.
*/
bool FreeRTOS::Semaphore::take(uint32_t timeoutMs, std::string owner) {
ESP_LOGV(LOG_TAG, "Semaphore taking: %s for %s", toString().c_str(), owner.c_str());
bool rc = false;
if (m_usePthreads) {
assert(false); // We apparently don't have a timed wait for pthreads.
} else {
rc = ::xSemaphoreTake(m_semaphore, timeoutMs / portTICK_PERIOD_MS) == pdTRUE;
}
m_owner = owner;
if (rc) {
ESP_LOGV(LOG_TAG, "Semaphore taken: %s", toString().c_str());
} else {
ESP_LOGE(LOG_TAG, "Semaphore NOT taken: %s", toString().c_str());
}
return rc;
} // Semaphore::take
static int vfs_semihost_open(void* ctx, const char * path, int flags, int mode)
{
int fd = -1, host_err = 0;
char *host_path;
vfs_semihost_ctx_t *semi_ctx = ctx;
ESP_LOGV(TAG, "%s: %p '%s 0x%x 0x%x'", __func__, semi_ctx, path, flags, mode);
if (ctx_uses_abspath(semi_ctx)) {
flags |= ESP_O_SEMIHOST_ABSPATH;
host_path = malloc(strlen(semi_ctx->host_path)+strlen(path)+1);
if(host_path == NULL) {
errno = ENOMEM;
return -1;
}
strcpy(host_path, semi_ctx->host_path);
strcat(host_path, path);
} else {
host_path = (char *)path;
}
fd = generic_syscall(SYS_OPEN, (int)host_path, strlen(host_path), flags, mode, &host_err);
if (ctx_uses_abspath(semi_ctx)) {
free(host_path);
}
if (fd == -1) {
errno = host_err;
}
return fd;
}
void esp_dbg_stubs_init()
{
s_dbg_stubs_ctl_data.tramp_addr = (uint32_t)s_stub_code_buf;
s_dbg_stubs_ctl_data.min_stack_addr = (uint32_t)s_stub_min_stack;
s_dbg_stubs_ctl_data.data_alloc = (uint32_t)esp_dbg_stubs_data_alloc;
s_dbg_stubs_ctl_data.data_free = (uint32_t)esp_dbg_stubs_data_free;
s_stub_entry[ESP_DBG_STUB_CONTROL_DATA] = (uint32_t)&s_dbg_stubs_ctl_data;
eri_write(ESP_DBG_STUBS_TRAX_REG, (uint32_t)s_stub_entry);
ESP_LOGV(TAG, "%s stubs %x", __func__, eri_read(ESP_DBG_STUBS_TRAX_REG));
}
static off_t vfs_semihost_lseek(void* ctx, int fd, off_t size, int mode)
{
int ret = -1, host_err = 0;
ESP_LOGV(TAG, "%s: %d %ld %d", __func__, fd, size, mode);
ret = generic_syscall(SYS_SEEK, fd, size, mode, 0, &host_err);
if (ret == -1) {
errno = host_err;
}
return (off_t)ret;
}
static int vfs_semihost_close(void* ctx, int fd)
{
int ret = -1, host_err = 0;
ESP_LOGV(TAG, "%s: %d", __func__, fd);
ret = generic_syscall(SYS_CLOSE, fd, 0, 0, 0, &host_err);
if (ret == -1) {
errno = host_err;
}
return ret;
}
static esp_err_t sdmmc_send_cmd(sdmmc_card_t* card, sdmmc_command_t* cmd)
{
int slot = card->host.slot;
ESP_LOGV(TAG, "sending cmd slot=%d op=%d arg=%x flags=%x data=%p blklen=%d datalen=%d",
slot, cmd->opcode, cmd->arg, cmd->flags, cmd->data, cmd->blklen, cmd->datalen);
esp_err_t err = (*card->host.do_transaction)(slot, cmd);
if (err != 0) {
ESP_LOGD(TAG, "sdmmc_req_run returned 0x%x", err);
return err;
}
int state = MMC_R1_CURRENT_STATE(cmd->response);
ESP_LOGV(TAG, "cmd response %08x %08x %08x %08x err=0x%x state=%d",
cmd->response[0],
cmd->response[1],
cmd->response[2],
cmd->response[3],
cmd->error,
state);
return cmd->error;
}
/**
* @brief Wait for a semaphore to be released by trying to take it and
* then releasing it again.
* @param [in] owner A debug tag.
* @return The value associated with the semaphore.
*/
uint32_t FreeRTOS::Semaphore::wait(std::string owner) {
ESP_LOGV(LOG_TAG, ">> wait: Semaphore waiting: %s for %s", toString().c_str(), owner.c_str());
if (m_usePthreads) {
pthread_mutex_lock(&m_pthread_mutex);
} else {
xSemaphoreTake(m_semaphore, portMAX_DELAY);
}
m_owner = owner;
if (m_usePthreads) {
pthread_mutex_unlock(&m_pthread_mutex);
} else {
xSemaphoreGive(m_semaphore);
}
ESP_LOGV(LOG_TAG, "<< wait: Semaphore released: %s", toString().c_str());
m_owner = std::string("<N/A>");
return m_value;
} // wait
static ssize_t vfs_semihost_read(void* ctx, int fd, void* data, size_t size)
{
int host_err = 0;
size_t ret = -1;
ESP_LOGV(TAG, "%s: %d %u bytes", __func__, fd, size);
ret = generic_syscall(SYS_READ, fd, (int)data, size, 0, &host_err);
if (ret == -1) {
errno = host_err;
}
return (ssize_t)ret;
}
/**
* @brief Give a semaphore.
* The Semaphore is given.
*/
void FreeRTOS::Semaphore::give() {
ESP_LOGV(LOG_TAG, "Semaphore giving: %s", toString().c_str());
if (m_usePthreads) {
pthread_mutex_unlock(&m_pthread_mutex);
} else {
xSemaphoreGive(m_semaphore);
}
// #ifdef ARDUINO_ARCH_ESP32
// FreeRTOS::sleep(10);
// #endif
m_owner = std::string("<N/A>");
} // Semaphore::give
esp_err_t esp_flash_encrypt_check_and_update(void)
{
uint32_t efuse_blk0 = REG_READ(EFUSE_BLK0_RDATA0_REG);
ESP_LOGV(TAG, "efuse_blk0 raw value %08x", efuse_blk0);
uint32_t flash_crypt_cnt = (efuse_blk0 & EFUSE_RD_FLASH_CRYPT_CNT_M) >> EFUSE_RD_FLASH_CRYPT_CNT_S;
bool flash_crypt_wr_dis = efuse_blk0 & EFUSE_WR_DIS_FLASH_CRYPT_CNT;
ESP_LOGV(TAG, "efuse FLASH_CRYPT_CNT 0x%x WR_DIS_FLASH_CRYPT_CNT 0x%x", flash_crypt_cnt, flash_crypt_wr_dis);
if (__builtin_parity(flash_crypt_cnt) == 1) {
/* Flash is already encrypted */
int left = (7 - __builtin_popcount(flash_crypt_cnt)) / 2;
if (flash_crypt_wr_dis) {
left = 0; /* can't update FLASH_CRYPT_CNT, no more flashes */
}
ESP_LOGI(TAG, "flash encryption is enabled (%d plaintext flashes left)", left);
return ESP_OK;
}
else {
/* Flash is not encrypted, so encrypt it! */
return encrypt_flash_contents(flash_crypt_cnt, flash_crypt_wr_dis);
}
}
static esp_err_t load_cal_data_from_nvs_handle(nvs_handle handle,
esp_phy_calibration_data_t* out_cal_data)
{
esp_err_t err;
uint32_t cal_data_version;
err = nvs_get_u32(handle, PHY_CAL_VERSION_KEY, &cal_data_version);
if (err != ESP_OK) {
ESP_LOGD(TAG, "%s: failed to get cal_version (0x%x)", __func__, err);
return err;
}
uint32_t cal_format_version = phy_get_rf_cal_version() & (~BIT(16));
ESP_LOGV(TAG, "phy_get_rf_cal_version: %d\n", cal_format_version);
if (cal_data_version != cal_format_version) {
ESP_LOGD(TAG, "%s: expected calibration data format %d, found %d",
__func__, cal_format_version, cal_data_version);
return ESP_FAIL;
}
uint8_t cal_data_mac[6];
size_t length = sizeof(cal_data_mac);
err = nvs_get_blob(handle, PHY_CAL_MAC_KEY, cal_data_mac, &length);
if (err != ESP_OK) {
ESP_LOGD(TAG, "%s: failed to get cal_mac (0x%x)", __func__, err);
return err;
}
if (length != sizeof(cal_data_mac)) {
ESP_LOGD(TAG, "%s: invalid length of cal_mac (%d)", __func__, length);
return ESP_ERR_INVALID_SIZE;
}
uint8_t sta_mac[6];
esp_efuse_mac_get_default(sta_mac);
if (memcmp(sta_mac, cal_data_mac, sizeof(sta_mac)) != 0) {
ESP_LOGE(TAG, "%s: calibration data MAC check failed: expected " \
MACSTR ", found " MACSTR,
__func__, MAC2STR(sta_mac), MAC2STR(cal_data_mac));
return ESP_FAIL;
}
length = sizeof(*out_cal_data);
err = nvs_get_blob(handle, PHY_CAL_DATA_KEY, out_cal_data, &length);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: failed to get cal_data(0x%x)", __func__, err);
return err;
}
if (length != sizeof(*out_cal_data)) {
ESP_LOGD(TAG, "%s: invalid length of cal_data (%d)", __func__, length);
return ESP_ERR_INVALID_SIZE;
}
return ESP_OK;
}
static esp_err_t store_cal_data_to_nvs_handle(nvs_handle handle,
const esp_phy_calibration_data_t* cal_data)
{
esp_err_t err;
uint32_t cal_format_version = phy_get_rf_cal_version() & (~BIT(16));
ESP_LOGV(TAG, "phy_get_rf_cal_version: %d\n", cal_format_version);
err = nvs_set_u32(handle, PHY_CAL_VERSION_KEY, cal_format_version);
if (err != ESP_OK) {
return err;
}
uint8_t sta_mac[6];
esp_efuse_mac_get_default(sta_mac);
err = nvs_set_blob(handle, PHY_CAL_MAC_KEY, sta_mac, sizeof(sta_mac));
if (err != ESP_OK) {
return err;
}
err = nvs_set_blob(handle, PHY_CAL_DATA_KEY, cal_data, sizeof(*cal_data));
return err;
}
static void set_cache_and_start_app(
uint32_t drom_addr,
uint32_t drom_load_addr,
uint32_t drom_size,
uint32_t irom_addr,
uint32_t irom_load_addr,
uint32_t irom_size,
uint32_t entry_addr)
{
ESP_LOGD(TAG, "configure drom and irom and start");
Cache_Read_Disable( 0 );
Cache_Flush( 0 );
/* Clear the MMU entries that are already set up,
so the new app only has the mappings it creates.
*/
for (int i = 0; i < DPORT_FLASH_MMU_TABLE_SIZE; i++) {
DPORT_PRO_FLASH_MMU_TABLE[i] = DPORT_FLASH_MMU_TABLE_INVALID_VAL;
}
uint32_t drom_page_count = (drom_size + 64*1024 - 1) / (64*1024); // round up to 64k
ESP_LOGV(TAG, "d mmu set paddr=%08x vaddr=%08x size=%d n=%d", drom_addr & 0xffff0000, drom_load_addr & 0xffff0000, drom_size, drom_page_count );
int rc = cache_flash_mmu_set( 0, 0, drom_load_addr & 0xffff0000, drom_addr & 0xffff0000, 64, drom_page_count );
ESP_LOGV(TAG, "rc=%d", rc );
rc = cache_flash_mmu_set( 1, 0, drom_load_addr & 0xffff0000, drom_addr & 0xffff0000, 64, drom_page_count );
ESP_LOGV(TAG, "rc=%d", rc );
uint32_t irom_page_count = (irom_size + 64*1024 - 1) / (64*1024); // round up to 64k
ESP_LOGV(TAG, "i mmu set paddr=%08x vaddr=%08x size=%d n=%d", irom_addr & 0xffff0000, irom_load_addr & 0xffff0000, irom_size, irom_page_count );
rc = cache_flash_mmu_set( 0, 0, irom_load_addr & 0xffff0000, irom_addr & 0xffff0000, 64, irom_page_count );
ESP_LOGV(TAG, "rc=%d", rc );
rc = cache_flash_mmu_set( 1, 0, irom_load_addr & 0xffff0000, irom_addr & 0xffff0000, 64, irom_page_count );
ESP_LOGV(TAG, "rc=%d", rc );
DPORT_REG_CLR_BIT( DPORT_PRO_CACHE_CTRL1_REG, (DPORT_PRO_CACHE_MASK_IRAM0) | (DPORT_PRO_CACHE_MASK_IRAM1 & 0) | (DPORT_PRO_CACHE_MASK_IROM0 & 0) | DPORT_PRO_CACHE_MASK_DROM0 | DPORT_PRO_CACHE_MASK_DRAM1 );
DPORT_REG_CLR_BIT( DPORT_APP_CACHE_CTRL1_REG, (DPORT_APP_CACHE_MASK_IRAM0) | (DPORT_APP_CACHE_MASK_IRAM1 & 0) | (DPORT_APP_CACHE_MASK_IROM0 & 0) | DPORT_APP_CACHE_MASK_DROM0 | DPORT_APP_CACHE_MASK_DRAM1 );
Cache_Read_Enable( 0 );
// Application will need to do Cache_Flush(1) and Cache_Read_Enable(1)
ESP_LOGD(TAG, "start: 0x%08x", entry_addr);
typedef void (*entry_t)(void) __attribute__((noreturn));
entry_t entry = ((entry_t) entry_addr);
// TODO: we have used quite a bit of stack at this point.
// use "movsp" instruction to reset stack back to where ROM stack starts.
(*entry)();
}
esp_err_t esp_phy_rf_init(const esp_phy_init_data_t* init_data,
esp_phy_calibration_mode_t mode, esp_phy_calibration_data_t* calibration_data)
{
assert((s_phy_rf_init_count <= 1) && (s_phy_rf_init_count >= 0));
_lock_acquire(&s_phy_rf_init_lock);
if (s_phy_rf_init_count == 0) {
// Enable WiFi/BT common peripheral clock
periph_module_enable(PERIPH_WIFI_BT_COMMON_MODULE);
ESP_LOGV(TAG, "register_chipv7_phy, init_data=%p, cal_data=%p, mode=%d",
init_data, calibration_data, mode);
phy_set_wifi_mode_only(0);
register_chipv7_phy(init_data, calibration_data, mode);
coex_bt_high_prio();
} else {
#if CONFIG_SW_COEXIST_ENABLE
coex_init();
#endif
}
s_phy_rf_init_count++;
_lock_release(&s_phy_rf_init_lock);
return ESP_OK;
}
static void esp_dbg_stubs_data_free(void *addr)
{
ESP_LOGV(TAG, "%s %p", __func__, addr);
free(addr);
ESP_LOGV(TAG, "%s EXIT %p", __func__, addr);
}
esp_err_t WL_Ext_Perf::erase_range(size_t start_address, size_t size)
{
esp_err_t result = ESP_OK;
if ((start_address % this->fat_sector_size) != 0) {
result = ESP_ERR_INVALID_ARG;
}
if (((size % this->fat_sector_size) != 0) || (size == 0)) {
result = ESP_ERR_INVALID_ARG;
}
WL_EXT_RESULT_CHECK(result);
// The range to erase could be allocated in any possible way
// ---------------------------------------------------------
// | | | | |
// |0|0|x|x|x|x|x|x|x|x|x|x|x|x|0|0|
// | pre | rest | rest | post | <- check ranges
//
// Pre check - the data that is not fit to the full sector at the begining of the erased block
// Post check - the data that are not fit to the full sector at the end of the erased block
// rest - data that are fit to the flash device sector at the middle of the erased block
//
// In case of pre and post check situations the data of the non erased area have to be readed first and then
// stored back.
// For the rest area this operation not needed because complete flash device sector will be erased.
ESP_LOGV(TAG, "%s begin, addr = 0x%08x, size = %i", __func__, start_address, size);
// Calculate pre check values
uint32_t pre_check_start = (start_address / this->fat_sector_size) % this->size_factor;
uint32_t sectors_count = size / this->fat_sector_size;
uint32_t pre_check_count = (this->size_factor - pre_check_start);
if (pre_check_count > sectors_count) {
pre_check_count = sectors_count;
}
// Calculate post ckeck
uint32_t post_check_count = (sectors_count - pre_check_count) % this->size_factor;
uint32_t post_check_start = ((start_address + size - post_check_count * this->fat_sector_size) / this->fat_sector_size);
// Calculate rest
uint32_t rest_check_count = sectors_count - pre_check_count - post_check_count;
if ((pre_check_count == this->size_factor) && (0 == pre_check_start)) {
rest_check_count+=this->size_factor;
pre_check_count = 0;
}
uint32_t rest_check_start = start_address + pre_check_count * this->fat_sector_size;
// Here we will clear pre_check_count amount of sectors
if (pre_check_count != 0) {
result = this->erase_sector_fit(start_address / this->fat_sector_size, pre_check_count);
WL_EXT_RESULT_CHECK(result);
}
ESP_LOGV(TAG, "%s rest_check_start = %i, pre_check_count=%i, rest_check_count=%i, post_check_count=%i\n", __func__, rest_check_start, pre_check_count, rest_check_count, post_check_count);
if (rest_check_count > 0) {
rest_check_count = rest_check_count / this->size_factor;
size_t start_sector = rest_check_start / this->flash_sector_size;
for (size_t i = 0; i < rest_check_count; i++) {
result = WL_Flash::erase_sector(start_sector + i);
WL_EXT_RESULT_CHECK(result);
}
}
if (post_check_count != 0) {
result = this->erase_sector_fit(post_check_start, post_check_count);
WL_EXT_RESULT_CHECK(result);
}
return ESP_OK;
}
esp_err_t sdmmc_card_init(const sdmmc_host_t* config,
sdmmc_card_t* card)
{
ESP_LOGD(TAG, "%s", __func__);
memset(card, 0, sizeof(*card));
memcpy(&card->host, config, sizeof(*config));
esp_err_t err = sdmmc_send_cmd_go_idle_state(card);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: go_idle_state (1) returned 0x%x", __func__, err);
return err;
}
ets_delay_us(10000);
uint32_t host_ocr = get_host_ocr(config->io_voltage);
err = sdmmc_send_cmd_send_if_cond(card, host_ocr);
if (err == ESP_OK) {
ESP_LOGD(TAG, "SDHC/SDXC card");
host_ocr |= SD_OCR_SDHC_CAP;
} else if (err == ESP_ERR_TIMEOUT) {
ESP_LOGD(TAG, "CMD8 timeout; not an SDHC/SDXC card");
} else {
ESP_LOGE(TAG, "%s: send_if_cond (1) returned 0x%x", __func__, err);
return err;
}
err = sdmmc_send_cmd_send_op_cond(card, host_ocr, &card->ocr);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: send_op_cond (1) returned 0x%x", __func__, err);
return err;
}
host_ocr &= card->ocr;
ESP_LOGD(TAG, "sdmmc_card_init: host_ocr=%08x, card_ocr=%08x", host_ocr, card->ocr);
err = sddmc_send_cmd_all_send_cid(card, &card->cid);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: all_send_cid returned 0x%x", __func__, err);
return err;
}
err = sdmmc_send_cmd_set_relative_addr(card, &card->rca);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: set_relative_addr returned 0x%x", __func__, err);
return err;
}
err = sdmmc_send_cmd_send_csd(card, &card->csd);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: send_csd returned 0x%x", __func__, err);
return err;
}
const size_t max_sdsc_capacity = UINT32_MAX / card->csd.sector_size + 1;
if (!(card->ocr & SD_OCR_SDHC_CAP) &&
card->csd.capacity > max_sdsc_capacity) {
ESP_LOGW(TAG, "%s: SDSC card reports capacity=%u. Limiting to %u.",
__func__, card->csd.capacity, max_sdsc_capacity);
card->csd.capacity = max_sdsc_capacity;
}
err = sdmmc_send_cmd_select_card(card);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: select_card returned 0x%x", __func__, err);
return err;
}
if ((card->ocr & SD_OCR_SDHC_CAP) == 0) {
err = sdmmc_send_cmd_set_blocklen(card, &card->csd);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: set_blocklen returned 0x%x", __func__, err);
return err;
}
}
err = sdmmc_send_cmd_send_scr(card, &card->scr);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: send_scr returned 0x%x", __func__, err);
return err;
}
if ((config->flags & SDMMC_HOST_FLAG_4BIT) &&
(card->scr.bus_width & SCR_SD_BUS_WIDTHS_4BIT)) {
ESP_LOGD(TAG, "switching to 4-bit bus mode");
err = sdmmc_send_cmd_set_bus_width(card, 4);
if (err != ESP_OK) {
ESP_LOGE(TAG, "set_bus_width failed");
return err;
}
err = (*config->set_bus_width)(config->slot, 4);
if (err != ESP_OK) {
ESP_LOGE(TAG, "slot->set_bus_width failed");
return err;
}
uint32_t status;
err = sdmmc_send_cmd_stop_transmission(card, &status);
if (err != ESP_OK) {
ESP_LOGE(TAG, "stop_transmission failed (0x%x)", err);
return err;
}
}
uint32_t status = 0;
while (!(status & MMC_R1_READY_FOR_DATA)) {
// TODO: add some timeout here
uint32_t count = 0;
err = sdmmc_send_cmd_send_status(card, &status);
if (err != ESP_OK) {
return err;
}
if (++count % 10 == 0) {
ESP_LOGV(TAG, "waiting for card to become ready (%d)", count);
}
}
if (config->max_freq_khz >= SDMMC_FREQ_HIGHSPEED &&
card->csd.tr_speed / 1000 >= SDMMC_FREQ_HIGHSPEED) {
ESP_LOGD(TAG, "switching to HS bus mode");
err = (*config->set_card_clk)(config->slot, SDMMC_FREQ_HIGHSPEED);
if (err != ESP_OK) {
ESP_LOGE(TAG, "failed to switch peripheral to HS bus mode");
return err;
}
} else if (config->max_freq_khz >= SDMMC_FREQ_DEFAULT &&
card->csd.tr_speed / 1000 >= SDMMC_FREQ_DEFAULT) {
ESP_LOGD(TAG, "switching to DS bus mode");
err = (*config->set_card_clk)(config->slot, SDMMC_FREQ_DEFAULT);
if (err != ESP_OK) {
ESP_LOGE(TAG, "failed to switch peripheral to HS bus mode");
return err;
}
}
sdmmc_scr_t scr_tmp;
err = sdmmc_send_cmd_send_scr(card, &scr_tmp);
if (err != ESP_OK) {
ESP_LOGE(TAG, "%s: send_scr returned 0x%x", __func__, err);
return err;
}
if (memcmp(&card->scr, &scr_tmp, sizeof(scr_tmp)) != 0) {
ESP_LOGE(TAG, "data check fail!");
return ESP_ERR_INVALID_RESPONSE;
}
return ESP_OK;
}
