separate debug component for each platform in different file (#6715)

Co-authored-by: Jesse Hills <3060199+jesserockz@users.noreply.github.com>
This commit is contained in:
tomaszduda23 2024-05-13 01:54:43 +02:00 committed by GitHub
parent 61b65e2726
commit 67ca60e2af
No known key found for this signature in database
GPG Key ID: B5690EEEBB952194
7 changed files with 479 additions and 366 deletions

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@ -8,62 +8,16 @@
#include <cinttypes>
#include <climits>
#ifdef USE_ESP32
#include <esp_heap_caps.h>
#include <esp_system.h>
#include <esp_chip_info.h>
#if defined(USE_ESP32_VARIANT_ESP32)
#include <esp32/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32C3)
#include <esp32c3/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32C6)
#include <esp32c6/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32S2)
#include <esp32s2/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32S3)
#include <esp32s3/rom/rtc.h>
#endif
#endif // USE_ESP32
#ifdef USE_ARDUINO
#ifdef USE_RP2040
#include <Arduino.h>
#elif defined(USE_ESP32) || defined(USE_ESP8266)
#include <Esp.h>
#endif
#endif
namespace esphome {
namespace debug {
static const char *const TAG = "debug";
static uint32_t get_free_heap() {
#if defined(USE_ESP8266)
return ESP.getFreeHeap(); // NOLINT(readability-static-accessed-through-instance)
#elif defined(USE_ESP32)
return heap_caps_get_free_size(MALLOC_CAP_INTERNAL);
#elif defined(USE_RP2040)
return rp2040.getFreeHeap();
#elif defined(USE_LIBRETINY)
return lt_heap_get_free();
#elif defined(USE_HOST)
return INT_MAX;
#endif
}
void DebugComponent::dump_config() {
#ifndef ESPHOME_LOG_HAS_DEBUG
return; // Can't log below if debug logging is disabled
#endif
std::string device_info;
std::string reset_reason;
device_info.reserve(256);
ESP_LOGCONFIG(TAG, "Debug component:");
#ifdef USE_TEXT_SENSOR
LOG_TEXT_SENSOR(" ", "Device info", this->device_info_);
@ -76,305 +30,15 @@ void DebugComponent::dump_config() {
#endif // defined(USE_ESP8266) && USE_ARDUINO_VERSION_CODE >= VERSION_CODE(2, 5, 2)
#endif // USE_SENSOR
std::string device_info;
device_info.reserve(256);
ESP_LOGD(TAG, "ESPHome version %s", ESPHOME_VERSION);
device_info += ESPHOME_VERSION;
this->free_heap_ = get_free_heap();
this->free_heap_ = get_free_heap_();
ESP_LOGD(TAG, "Free Heap Size: %" PRIu32 " bytes", this->free_heap_);
#if defined(USE_ARDUINO) && (defined(USE_ESP32) || defined(USE_ESP8266))
const char *flash_mode;
switch (ESP.getFlashChipMode()) { // NOLINT(readability-static-accessed-through-instance)
case FM_QIO:
flash_mode = "QIO";
break;
case FM_QOUT:
flash_mode = "QOUT";
break;
case FM_DIO:
flash_mode = "DIO";
break;
case FM_DOUT:
flash_mode = "DOUT";
break;
#ifdef USE_ESP32
case FM_FAST_READ:
flash_mode = "FAST_READ";
break;
case FM_SLOW_READ:
flash_mode = "SLOW_READ";
break;
#endif
default:
flash_mode = "UNKNOWN";
}
ESP_LOGD(TAG, "Flash Chip: Size=%ukB Speed=%uMHz Mode=%s",
ESP.getFlashChipSize() / 1024, // NOLINT
ESP.getFlashChipSpeed() / 1000000, flash_mode); // NOLINT
device_info += "|Flash: " + to_string(ESP.getFlashChipSize() / 1024) + // NOLINT
"kB Speed:" + to_string(ESP.getFlashChipSpeed() / 1000000) + "MHz Mode:"; // NOLINT
device_info += flash_mode;
#endif // USE_ARDUINO && (USE_ESP32 || USE_ESP8266)
#ifdef USE_ESP32
esp_chip_info_t info;
esp_chip_info(&info);
const char *model;
#if defined(USE_ESP32_VARIANT_ESP32)
model = "ESP32";
#elif defined(USE_ESP32_VARIANT_ESP32C3)
model = "ESP32-C3";
#elif defined(USE_ESP32_VARIANT_ESP32C6)
model = "ESP32-C6";
#elif defined(USE_ESP32_VARIANT_ESP32S2)
model = "ESP32-S2";
#elif defined(USE_ESP32_VARIANT_ESP32S3)
model = "ESP32-S3";
#elif defined(USE_ESP32_VARIANT_ESP32H2)
model = "ESP32-H2";
#else
model = "UNKNOWN";
#endif
std::string features;
if (info.features & CHIP_FEATURE_EMB_FLASH) {
features += "EMB_FLASH,";
info.features &= ~CHIP_FEATURE_EMB_FLASH;
}
if (info.features & CHIP_FEATURE_WIFI_BGN) {
features += "WIFI_BGN,";
info.features &= ~CHIP_FEATURE_WIFI_BGN;
}
if (info.features & CHIP_FEATURE_BLE) {
features += "BLE,";
info.features &= ~CHIP_FEATURE_BLE;
}
if (info.features & CHIP_FEATURE_BT) {
features += "BT,";
info.features &= ~CHIP_FEATURE_BT;
}
if (info.features & CHIP_FEATURE_EMB_PSRAM) {
features += "EMB_PSRAM,";
info.features &= ~CHIP_FEATURE_EMB_PSRAM;
}
if (info.features)
features += "Other:" + format_hex(info.features);
ESP_LOGD(TAG, "Chip: Model=%s, Features=%s Cores=%u, Revision=%u", model, features.c_str(), info.cores,
info.revision);
device_info += "|Chip: ";
device_info += model;
device_info += " Features:";
device_info += features;
device_info += " Cores:" + to_string(info.cores);
device_info += " Revision:" + to_string(info.revision);
ESP_LOGD(TAG, "ESP-IDF Version: %s", esp_get_idf_version());
device_info += "|ESP-IDF: ";
device_info += esp_get_idf_version();
std::string mac = get_mac_address_pretty();
ESP_LOGD(TAG, "EFuse MAC: %s", mac.c_str());
device_info += "|EFuse MAC: ";
device_info += mac;
switch (rtc_get_reset_reason(0)) {
case POWERON_RESET:
reset_reason = "Power On Reset";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case SW_RESET:
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case RTC_SW_SYS_RESET:
#endif
reset_reason = "Software Reset Digital Core";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case OWDT_RESET:
reset_reason = "Watch Dog Reset Digital Core";
break;
#endif
case DEEPSLEEP_RESET:
reset_reason = "Deep Sleep Reset Digital Core";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case SDIO_RESET:
reset_reason = "SLC Module Reset Digital Core";
break;
#endif
case TG0WDT_SYS_RESET:
reset_reason = "Timer Group 0 Watch Dog Reset Digital Core";
break;
case TG1WDT_SYS_RESET:
reset_reason = "Timer Group 1 Watch Dog Reset Digital Core";
break;
case RTCWDT_SYS_RESET:
reset_reason = "RTC Watch Dog Reset Digital Core";
break;
#if !defined(USE_ESP32_VARIANT_ESP32C6)
case INTRUSION_RESET:
reset_reason = "Intrusion Reset CPU";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32)
case TGWDT_CPU_RESET:
reset_reason = "Timer Group Reset CPU";
break;
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case TG0WDT_CPU_RESET:
reset_reason = "Timer Group 0 Reset CPU";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32)
case SW_CPU_RESET:
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case RTC_SW_CPU_RESET:
#endif
reset_reason = "Software Reset CPU";
break;
case RTCWDT_CPU_RESET:
reset_reason = "RTC Watch Dog Reset CPU";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case EXT_CPU_RESET:
reset_reason = "External CPU Reset";
break;
#endif
case RTCWDT_BROWN_OUT_RESET:
reset_reason = "Voltage Unstable Reset";
break;
case RTCWDT_RTC_RESET:
reset_reason = "RTC Watch Dog Reset Digital Core And RTC Module";
break;
#if defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case TG1WDT_CPU_RESET:
reset_reason = "Timer Group 1 Reset CPU";
break;
case SUPER_WDT_RESET:
reset_reason = "Super Watchdog Reset Digital Core And RTC Module";
break;
case GLITCH_RTC_RESET:
reset_reason = "Glitch Reset Digital Core And RTC Module";
break;
case EFUSE_RESET:
reset_reason = "eFuse Reset Digital Core";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S3)
case USB_UART_CHIP_RESET:
reset_reason = "USB UART Reset Digital Core";
break;
case USB_JTAG_CHIP_RESET:
reset_reason = "USB JTAG Reset Digital Core";
break;
case POWER_GLITCH_RESET:
reset_reason = "Power Glitch Reset Digital Core And RTC Module";
break;
#endif
default:
reset_reason = "Unknown Reset Reason";
}
ESP_LOGD(TAG, "Reset Reason: %s", reset_reason.c_str());
device_info += "|Reset: ";
device_info += reset_reason;
const char *wakeup_reason;
switch (rtc_get_wakeup_cause()) {
case NO_SLEEP:
wakeup_reason = "No Sleep";
break;
case EXT_EVENT0_TRIG:
wakeup_reason = "External Event 0";
break;
case EXT_EVENT1_TRIG:
wakeup_reason = "External Event 1";
break;
case GPIO_TRIG:
wakeup_reason = "GPIO";
break;
case TIMER_EXPIRE:
wakeup_reason = "Wakeup Timer";
break;
case SDIO_TRIG:
wakeup_reason = "SDIO";
break;
case MAC_TRIG:
wakeup_reason = "MAC";
break;
case UART0_TRIG:
wakeup_reason = "UART0";
break;
case UART1_TRIG:
wakeup_reason = "UART1";
break;
case TOUCH_TRIG:
wakeup_reason = "Touch";
break;
case SAR_TRIG:
wakeup_reason = "SAR";
break;
case BT_TRIG:
wakeup_reason = "BT";
break;
default:
wakeup_reason = "Unknown";
}
ESP_LOGD(TAG, "Wakeup Reason: %s", wakeup_reason);
device_info += "|Wakeup: ";
device_info += wakeup_reason;
#endif
#if defined(USE_ESP8266) && !defined(CLANG_TIDY)
ESP_LOGD(TAG, "Chip ID: 0x%08X", ESP.getChipId());
ESP_LOGD(TAG, "SDK Version: %s", ESP.getSdkVersion());
ESP_LOGD(TAG, "Core Version: %s", ESP.getCoreVersion().c_str());
ESP_LOGD(TAG, "Boot Version=%u Mode=%u", ESP.getBootVersion(), ESP.getBootMode());
ESP_LOGD(TAG, "CPU Frequency: %u", ESP.getCpuFreqMHz());
ESP_LOGD(TAG, "Flash Chip ID=0x%08X", ESP.getFlashChipId());
ESP_LOGD(TAG, "Reset Reason: %s", ESP.getResetReason().c_str());
ESP_LOGD(TAG, "Reset Info: %s", ESP.getResetInfo().c_str());
device_info += "|Chip: 0x" + format_hex(ESP.getChipId());
device_info += "|SDK: ";
device_info += ESP.getSdkVersion();
device_info += "|Core: ";
device_info += ESP.getCoreVersion().c_str();
device_info += "|Boot: ";
device_info += to_string(ESP.getBootVersion());
device_info += "|Mode: " + to_string(ESP.getBootMode());
device_info += "|CPU: " + to_string(ESP.getCpuFreqMHz());
device_info += "|Flash: 0x" + format_hex(ESP.getFlashChipId());
device_info += "|Reset: ";
device_info += ESP.getResetReason().c_str();
device_info += "|";
device_info += ESP.getResetInfo().c_str();
reset_reason = ESP.getResetReason().c_str();
#endif
#ifdef USE_RP2040
ESP_LOGD(TAG, "CPU Frequency: %u", rp2040.f_cpu());
device_info += "CPU Frequency: " + to_string(rp2040.f_cpu());
#endif // USE_RP2040
#ifdef USE_LIBRETINY
ESP_LOGD(TAG, "LibreTiny Version: %s", lt_get_version());
ESP_LOGD(TAG, "Chip: %s (%04x) @ %u MHz", lt_cpu_get_model_name(), lt_cpu_get_model(), lt_cpu_get_freq_mhz());
ESP_LOGD(TAG, "Chip ID: 0x%06X", lt_cpu_get_mac_id());
ESP_LOGD(TAG, "Board: %s", lt_get_board_code());
ESP_LOGD(TAG, "Flash: %u KiB / RAM: %u KiB", lt_flash_get_size() / 1024, lt_ram_get_size() / 1024);
ESP_LOGD(TAG, "Reset Reason: %s", lt_get_reboot_reason_name(lt_get_reboot_reason()));
device_info += "|Version: ";
device_info += LT_BANNER_STR + 10;
device_info += "|Reset Reason: ";
device_info += lt_get_reboot_reason_name(lt_get_reboot_reason());
device_info += "|Chip Name: ";
device_info += lt_cpu_get_model_name();
device_info += "|Chip ID: 0x" + format_hex(lt_cpu_get_mac_id());
device_info += "|Flash: " + to_string(lt_flash_get_size() / 1024) + " KiB";
device_info += "|RAM: " + to_string(lt_ram_get_size() / 1024) + " KiB";
reset_reason = lt_get_reboot_reason_name(lt_get_reboot_reason());
#endif // USE_LIBRETINY
get_device_info_(device_info);
#ifdef USE_TEXT_SENSOR
if (this->device_info_ != nullptr) {
@ -383,14 +47,14 @@ void DebugComponent::dump_config() {
this->device_info_->publish_state(device_info);
}
if (this->reset_reason_ != nullptr) {
this->reset_reason_->publish_state(reset_reason);
this->reset_reason_->publish_state(get_reset_reason_());
}
#endif // USE_TEXT_SENSOR
}
void DebugComponent::loop() {
// log when free heap space has halved
uint32_t new_free_heap = get_free_heap();
uint32_t new_free_heap = get_free_heap_();
if (new_free_heap < this->free_heap_ / 2) {
this->free_heap_ = new_free_heap;
ESP_LOGD(TAG, "Free Heap Size: %" PRIu32 " bytes", this->free_heap_);
@ -411,38 +75,16 @@ void DebugComponent::loop() {
void DebugComponent::update() {
#ifdef USE_SENSOR
if (this->free_sensor_ != nullptr) {
this->free_sensor_->publish_state(get_free_heap());
this->free_sensor_->publish_state(get_free_heap_());
}
if (this->block_sensor_ != nullptr) {
#if defined(USE_ESP8266)
// NOLINTNEXTLINE(readability-static-accessed-through-instance)
this->block_sensor_->publish_state(ESP.getMaxFreeBlockSize());
#elif defined(USE_ESP32)
this->block_sensor_->publish_state(heap_caps_get_largest_free_block(MALLOC_CAP_INTERNAL));
#elif defined(USE_LIBRETINY)
this->block_sensor_->publish_state(lt_heap_get_max_alloc());
#endif
}
#if defined(USE_ESP8266) && USE_ARDUINO_VERSION_CODE >= VERSION_CODE(2, 5, 2)
if (this->fragmentation_sensor_ != nullptr) {
// NOLINTNEXTLINE(readability-static-accessed-through-instance)
this->fragmentation_sensor_->publish_state(ESP.getHeapFragmentation());
}
#endif
if (this->loop_time_sensor_ != nullptr) {
this->loop_time_sensor_->publish_state(this->max_loop_time_);
this->max_loop_time_ = 0;
}
#ifdef USE_ESP32
if (this->psram_sensor_ != nullptr) {
this->psram_sensor_->publish_state(heap_caps_get_free_size(MALLOC_CAP_SPIRAM));
}
#endif // USE_ESP32
#endif // USE_SENSOR
update_platform_();
}
float DebugComponent::get_setup_priority() const { return setup_priority::LATE; }

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@ -59,6 +59,11 @@ class DebugComponent : public PollingComponent {
text_sensor::TextSensor *device_info_{nullptr};
text_sensor::TextSensor *reset_reason_{nullptr};
#endif // USE_TEXT_SENSOR
std::string get_reset_reason_();
uint32_t get_free_heap_();
void get_device_info_(std::string &device_info);
void update_platform_();
};
} // namespace debug

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@ -0,0 +1,287 @@
#include "debug_component.h"
#ifdef USE_ESP32
#include "esphome/core/log.h"
#include <esp_heap_caps.h>
#include <esp_system.h>
#include <esp_chip_info.h>
#if defined(USE_ESP32_VARIANT_ESP32)
#include <esp32/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32C3)
#include <esp32c3/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32C6)
#include <esp32c6/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32S2)
#include <esp32s2/rom/rtc.h>
#elif defined(USE_ESP32_VARIANT_ESP32S3)
#include <esp32s3/rom/rtc.h>
#endif
#ifdef USE_ARDUINO
#include <Esp.h>
#endif
namespace esphome {
namespace debug {
static const char *const TAG = "debug";
std::string DebugComponent::get_reset_reason_() {
std::string reset_reason;
switch (rtc_get_reset_reason(0)) {
case POWERON_RESET:
reset_reason = "Power On Reset";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case SW_RESET:
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case RTC_SW_SYS_RESET:
#endif
reset_reason = "Software Reset Digital Core";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case OWDT_RESET:
reset_reason = "Watch Dog Reset Digital Core";
break;
#endif
case DEEPSLEEP_RESET:
reset_reason = "Deep Sleep Reset Digital Core";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case SDIO_RESET:
reset_reason = "SLC Module Reset Digital Core";
break;
#endif
case TG0WDT_SYS_RESET:
reset_reason = "Timer Group 0 Watch Dog Reset Digital Core";
break;
case TG1WDT_SYS_RESET:
reset_reason = "Timer Group 1 Watch Dog Reset Digital Core";
break;
case RTCWDT_SYS_RESET:
reset_reason = "RTC Watch Dog Reset Digital Core";
break;
#if !defined(USE_ESP32_VARIANT_ESP32C6)
case INTRUSION_RESET:
reset_reason = "Intrusion Reset CPU";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32)
case TGWDT_CPU_RESET:
reset_reason = "Timer Group Reset CPU";
break;
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case TG0WDT_CPU_RESET:
reset_reason = "Timer Group 0 Reset CPU";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32)
case SW_CPU_RESET:
#elif defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case RTC_SW_CPU_RESET:
#endif
reset_reason = "Software Reset CPU";
break;
case RTCWDT_CPU_RESET:
reset_reason = "RTC Watch Dog Reset CPU";
break;
#if defined(USE_ESP32_VARIANT_ESP32)
case EXT_CPU_RESET:
reset_reason = "External CPU Reset";
break;
#endif
case RTCWDT_BROWN_OUT_RESET:
reset_reason = "Voltage Unstable Reset";
break;
case RTCWDT_RTC_RESET:
reset_reason = "RTC Watch Dog Reset Digital Core And RTC Module";
break;
#if defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
case TG1WDT_CPU_RESET:
reset_reason = "Timer Group 1 Reset CPU";
break;
case SUPER_WDT_RESET:
reset_reason = "Super Watchdog Reset Digital Core And RTC Module";
break;
case GLITCH_RTC_RESET:
reset_reason = "Glitch Reset Digital Core And RTC Module";
break;
case EFUSE_RESET:
reset_reason = "eFuse Reset Digital Core";
break;
#endif
#if defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S3)
case USB_UART_CHIP_RESET:
reset_reason = "USB UART Reset Digital Core";
break;
case USB_JTAG_CHIP_RESET:
reset_reason = "USB JTAG Reset Digital Core";
break;
case POWER_GLITCH_RESET:
reset_reason = "Power Glitch Reset Digital Core And RTC Module";
break;
#endif
default:
reset_reason = "Unknown Reset Reason";
}
ESP_LOGD(TAG, "Reset Reason: %s", reset_reason.c_str());
return reset_reason;
}
uint32_t DebugComponent::get_free_heap_() { return heap_caps_get_free_size(MALLOC_CAP_INTERNAL); }
void DebugComponent::get_device_info_(std::string &device_info) {
#if defined(USE_ARDUINO)
const char *flash_mode;
switch (ESP.getFlashChipMode()) { // NOLINT(readability-static-accessed-through-instance)
case FM_QIO:
flash_mode = "QIO";
break;
case FM_QOUT:
flash_mode = "QOUT";
break;
case FM_DIO:
flash_mode = "DIO";
break;
case FM_DOUT:
flash_mode = "DOUT";
break;
case FM_FAST_READ:
flash_mode = "FAST_READ";
break;
case FM_SLOW_READ:
flash_mode = "SLOW_READ";
break;
default:
flash_mode = "UNKNOWN";
}
ESP_LOGD(TAG, "Flash Chip: Size=%ukB Speed=%uMHz Mode=%s",
ESP.getFlashChipSize() / 1024, // NOLINT
ESP.getFlashChipSpeed() / 1000000, flash_mode); // NOLINT
device_info += "|Flash: " + to_string(ESP.getFlashChipSize() / 1024) + // NOLINT
"kB Speed:" + to_string(ESP.getFlashChipSpeed() / 1000000) + "MHz Mode:"; // NOLINT
device_info += flash_mode;
#endif
esp_chip_info_t info;
esp_chip_info(&info);
const char *model;
#if defined(USE_ESP32_VARIANT_ESP32)
model = "ESP32";
#elif defined(USE_ESP32_VARIANT_ESP32C3)
model = "ESP32-C3";
#elif defined(USE_ESP32_VARIANT_ESP32C6)
model = "ESP32-C6";
#elif defined(USE_ESP32_VARIANT_ESP32S2)
model = "ESP32-S2";
#elif defined(USE_ESP32_VARIANT_ESP32S3)
model = "ESP32-S3";
#elif defined(USE_ESP32_VARIANT_ESP32H2)
model = "ESP32-H2";
#else
model = "UNKNOWN";
#endif
std::string features;
if (info.features & CHIP_FEATURE_EMB_FLASH) {
features += "EMB_FLASH,";
info.features &= ~CHIP_FEATURE_EMB_FLASH;
}
if (info.features & CHIP_FEATURE_WIFI_BGN) {
features += "WIFI_BGN,";
info.features &= ~CHIP_FEATURE_WIFI_BGN;
}
if (info.features & CHIP_FEATURE_BLE) {
features += "BLE,";
info.features &= ~CHIP_FEATURE_BLE;
}
if (info.features & CHIP_FEATURE_BT) {
features += "BT,";
info.features &= ~CHIP_FEATURE_BT;
}
if (info.features & CHIP_FEATURE_EMB_PSRAM) {
features += "EMB_PSRAM,";
info.features &= ~CHIP_FEATURE_EMB_PSRAM;
}
if (info.features)
features += "Other:" + format_hex(info.features);
ESP_LOGD(TAG, "Chip: Model=%s, Features=%s Cores=%u, Revision=%u", model, features.c_str(), info.cores,
info.revision);
device_info += "|Chip: ";
device_info += model;
device_info += " Features:";
device_info += features;
device_info += " Cores:" + to_string(info.cores);
device_info += " Revision:" + to_string(info.revision);
ESP_LOGD(TAG, "ESP-IDF Version: %s", esp_get_idf_version());
device_info += "|ESP-IDF: ";
device_info += esp_get_idf_version();
std::string mac = get_mac_address_pretty();
ESP_LOGD(TAG, "EFuse MAC: %s", mac.c_str());
device_info += "|EFuse MAC: ";
device_info += mac;
device_info += "|Reset: ";
device_info += get_reset_reason_();
const char *wakeup_reason;
switch (rtc_get_wakeup_cause()) {
case NO_SLEEP:
wakeup_reason = "No Sleep";
break;
case EXT_EVENT0_TRIG:
wakeup_reason = "External Event 0";
break;
case EXT_EVENT1_TRIG:
wakeup_reason = "External Event 1";
break;
case GPIO_TRIG:
wakeup_reason = "GPIO";
break;
case TIMER_EXPIRE:
wakeup_reason = "Wakeup Timer";
break;
case SDIO_TRIG:
wakeup_reason = "SDIO";
break;
case MAC_TRIG:
wakeup_reason = "MAC";
break;
case UART0_TRIG:
wakeup_reason = "UART0";
break;
case UART1_TRIG:
wakeup_reason = "UART1";
break;
case TOUCH_TRIG:
wakeup_reason = "Touch";
break;
case SAR_TRIG:
wakeup_reason = "SAR";
break;
case BT_TRIG:
wakeup_reason = "BT";
break;
default:
wakeup_reason = "Unknown";
}
ESP_LOGD(TAG, "Wakeup Reason: %s", wakeup_reason);
device_info += "|Wakeup: ";
device_info += wakeup_reason;
}
void DebugComponent::update_platform_() {
#ifdef USE_SENSOR
if (this->block_sensor_ != nullptr) {
this->block_sensor_->publish_state(heap_caps_get_largest_free_block(MALLOC_CAP_INTERNAL));
}
if (this->psram_sensor_ != nullptr) {
this->psram_sensor_->publish_state(heap_caps_get_free_size(MALLOC_CAP_SPIRAM));
}
#endif
}
} // namespace debug
} // namespace esphome
#endif

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#include "debug_component.h"
#ifdef USE_ESP8266
#include "esphome/core/log.h"
#include <Esp.h>
namespace esphome {
namespace debug {
static const char *const TAG = "debug";
std::string DebugComponent::get_reset_reason_() {
#if !defined(CLANG_TIDY)
return ESP.getResetReason().c_str();
#else
return "";
#endif
}
uint32_t DebugComponent::get_free_heap_() {
return ESP.getFreeHeap(); // NOLINT(readability-static-accessed-through-instance)
}
void DebugComponent::get_device_info_(std::string &device_info) {
const char *flash_mode;
switch (ESP.getFlashChipMode()) { // NOLINT(readability-static-accessed-through-instance)
case FM_QIO:
flash_mode = "QIO";
break;
case FM_QOUT:
flash_mode = "QOUT";
break;
case FM_DIO:
flash_mode = "DIO";
break;
case FM_DOUT:
flash_mode = "DOUT";
break;
default:
flash_mode = "UNKNOWN";
}
ESP_LOGD(TAG, "Flash Chip: Size=%ukB Speed=%uMHz Mode=%s",
ESP.getFlashChipSize() / 1024, // NOLINT
ESP.getFlashChipSpeed() / 1000000, flash_mode); // NOLINT
device_info += "|Flash: " + to_string(ESP.getFlashChipSize() / 1024) + // NOLINT
"kB Speed:" + to_string(ESP.getFlashChipSpeed() / 1000000) + "MHz Mode:"; // NOLINT
device_info += flash_mode;
#if !defined(CLANG_TIDY)
auto reset_reason = get_reset_reason_();
ESP_LOGD(TAG, "Chip ID: 0x%08X", ESP.getChipId());
ESP_LOGD(TAG, "SDK Version: %s", ESP.getSdkVersion());
ESP_LOGD(TAG, "Core Version: %s", ESP.getCoreVersion().c_str());
ESP_LOGD(TAG, "Boot Version=%u Mode=%u", ESP.getBootVersion(), ESP.getBootMode());
ESP_LOGD(TAG, "CPU Frequency: %u", ESP.getCpuFreqMHz());
ESP_LOGD(TAG, "Flash Chip ID=0x%08X", ESP.getFlashChipId());
ESP_LOGD(TAG, "Reset Reason: %s", reset_reason.c_str());
ESP_LOGD(TAG, "Reset Info: %s", ESP.getResetInfo().c_str());
device_info += "|Chip: 0x" + format_hex(ESP.getChipId());
device_info += "|SDK: ";
device_info += ESP.getSdkVersion();
device_info += "|Core: ";
device_info += ESP.getCoreVersion().c_str();
device_info += "|Boot: ";
device_info += to_string(ESP.getBootVersion());
device_info += "|Mode: " + to_string(ESP.getBootMode());
device_info += "|CPU: " + to_string(ESP.getCpuFreqMHz());
device_info += "|Flash: 0x" + format_hex(ESP.getFlashChipId());
device_info += "|Reset: ";
device_info += reset_reason;
device_info += "|";
device_info += ESP.getResetInfo().c_str();
#endif
}
void DebugComponent::update_platform_() {
#ifdef USE_SENSOR
if (this->block_sensor_ != nullptr) {
// NOLINTNEXTLINE(readability-static-accessed-through-instance)
this->block_sensor_->publish_state(ESP.getMaxFreeBlockSize());
}
#if USE_ARDUINO_VERSION_CODE >= VERSION_CODE(2, 5, 2)
if (this->fragmentation_sensor_ != nullptr) {
// NOLINTNEXTLINE(readability-static-accessed-through-instance)
this->fragmentation_sensor_->publish_state(ESP.getHeapFragmentation());
}
#endif
#endif
}
} // namespace debug
} // namespace esphome
#endif

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#include "debug_component.h"
#ifdef USE_HOST
#include <climits>
namespace esphome {
namespace debug {
std::string DebugComponent::get_reset_reason_() { return ""; }
uint32_t DebugComponent::get_free_heap_() { return INT_MAX; }
void DebugComponent::get_device_info_(std::string &device_info) {}
void DebugComponent::update_platform_() {}
} // namespace debug
} // namespace esphome
#endif

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#include "debug_component.h"
#ifdef USE_LIBRETINY
#include "esphome/core/log.h"
namespace esphome {
namespace debug {
static const char *const TAG = "debug";
std::string DebugComponent::get_reset_reason_() { return lt_get_reboot_reason_name(lt_get_reboot_reason()); }
uint32_t DebugComponent::get_free_heap_() { return lt_heap_get_free(); }
void DebugComponent::get_device_info_(std::string &device_info) {
reset_reason = get_reset_reason_();
ESP_LOGD(TAG, "LibreTiny Version: %s", lt_get_version());
ESP_LOGD(TAG, "Chip: %s (%04x) @ %u MHz", lt_cpu_get_model_name(), lt_cpu_get_model(), lt_cpu_get_freq_mhz());
ESP_LOGD(TAG, "Chip ID: 0x%06X", lt_cpu_get_mac_id());
ESP_LOGD(TAG, "Board: %s", lt_get_board_code());
ESP_LOGD(TAG, "Flash: %u KiB / RAM: %u KiB", lt_flash_get_size() / 1024, lt_ram_get_size() / 1024);
ESP_LOGD(TAG, "Reset Reason: %s", reset_reason.c_str());
device_info += "|Version: ";
device_info += LT_BANNER_STR + 10;
device_info += "|Reset Reason: ";
device_info += reset_reason;
device_info += "|Chip Name: ";
device_info += lt_cpu_get_model_name();
device_info += "|Chip ID: 0x" + format_hex(lt_cpu_get_mac_id());
device_info += "|Flash: " + to_string(lt_flash_get_size() / 1024) + " KiB";
device_info += "|RAM: " + to_string(lt_ram_get_size() / 1024) + " KiB";
}
void DebugComponent::update_platform_() {
#ifdef USE_SENSOR
if (this->block_sensor_ != nullptr) {
this->block_sensor_->publish_state(lt_heap_get_max_alloc());
}
#endif
}
} // namespace debug
} // namespace esphome
#endif

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#include "debug_component.h"
#ifdef USE_RP2040
#include "esphome/core/log.h"
#include <Arduino.h>
namespace esphome {
namespace debug {
static const char *const TAG = "debug";
std::string DebugComponent::get_reset_reason_() { return ""; }
uint32_t DebugComponent::get_free_heap_() { return rp2040.getFreeHeap(); }
void DebugComponent::get_device_info_(std::string &device_info) {
ESP_LOGD(TAG, "CPU Frequency: %u", rp2040.f_cpu());
device_info += "CPU Frequency: " + to_string(rp2040.f_cpu());
}
void DebugComponent::update_platform_() {}
} // namespace debug
} // namespace esphome
#endif