Merge branch 'esp32-s2' into dev

This commit is contained in:
Blaz Kristan 2022-09-20 21:52:40 +02:00
commit fc0dc4472b
25 changed files with 2876 additions and 2508 deletions

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@ -8,7 +8,7 @@
#error This audio reactive usermod does not support the ESP8266. #error This audio reactive usermod does not support the ESP8266.
#endif #endif
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
#include <esp_timer.h> #include <esp_timer.h>
#endif #endif
@ -41,13 +41,15 @@
constexpr i2s_port_t I2S_PORT = I2S_NUM_0; constexpr i2s_port_t I2S_PORT = I2S_NUM_0;
constexpr int BLOCK_SIZE = 128; constexpr int BLOCK_SIZE = 128;
constexpr int SAMPLE_RATE = 22050; // Base sample rate in Hz - 22Khz is a standard rate. Physical sample time -> 23ms constexpr SRate_t SAMPLE_RATE = 22050; // Base sample rate in Hz - 22Khz is a standard rate. Physical sample time -> 23ms
//constexpr int SAMPLE_RATE = 20480; // Base sample rate in Hz - 20Khz is experimental. Physical sample time -> 25ms //constexpr SRate_t SAMPLE_RATE = 16000; // 16kHz - use if FFTtask takes more than 20ms. Physical sample time -> 32ms
//constexpr int SAMPLE_RATE = 10240; // Base sample rate in Hz - previous default. Physical sample time -> 50ms //constexpr SRate_t SAMPLE_RATE = 20480; // Base sample rate in Hz - 20Khz is experimental. Physical sample time -> 25ms
//constexpr SRate_t SAMPLE_RATE = 10240; // Base sample rate in Hz - previous default. Physical sample time -> 50ms
#define FFT_MIN_CYCLE 18 // minimum time before FFT task is repeated. Use with 22Khz sampling #define FFT_MIN_CYCLE 21 // minimum time before FFT task is repeated. Use with 22Khz sampling
//#define FFT_MIN_CYCLE 22 // minimum time before FFT task is repeated. Use with 20Khz sampling //#define FFT_MIN_CYCLE 30 // Use with 16Khz sampling
//#define FFT_MIN_CYCLE 44 // minimum time before FFT task is repeated. Use with 10Khz sampling //#define FFT_MIN_CYCLE 23 // minimum time before FFT task is repeated. Use with 20Khz sampling
//#define FFT_MIN_CYCLE 46 // minimum time before FFT task is repeated. Use with 10Khz sampling
// globals // globals
static uint8_t inputLevel = 128; // UI slider value static uint8_t inputLevel = 128; // UI slider value
@ -112,7 +114,7 @@ static void autoResetPeak(void); // peak auto-reset function
#else #else
// lib_deps += https://github.com/blazoncek/arduinoFFT.git // lib_deps += https://github.com/blazoncek/arduinoFFT.git
#endif #endif
#include "arduinoFFT.h" #include <arduinoFFT.h>
// FFT Output variables shared with animations // FFT Output variables shared with animations
#define NUM_GEQ_CHANNELS 16 // number of frequency channels. Don't change !! #define NUM_GEQ_CHANNELS 16 // number of frequency channels. Don't change !!
@ -144,9 +146,9 @@ static float fftAvg[NUM_GEQ_CHANNELS] = {0.0f}; // Calcula
static float fftResultMax[NUM_GEQ_CHANNELS] = {0.0f}; // A table used for testing to determine how our post-processing is working. static float fftResultMax[NUM_GEQ_CHANNELS] = {0.0f}; // A table used for testing to determine how our post-processing is working.
#endif #endif
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
static unsigned long fftTime = 0; static uint64_t fftTime = 0;
static unsigned long sampleTime = 0; static uint64_t sampleTime = 0;
#endif #endif
// Table of multiplication factors so that we can even out the frequency response. // Table of multiplication factors so that we can even out the frequency response.
@ -182,31 +184,33 @@ void FFTcode(void * parameter)
// see https://www.freertos.org/vtaskdelayuntil.html // see https://www.freertos.org/vtaskdelayuntil.html
const TickType_t xFrequency = FFT_MIN_CYCLE * portTICK_PERIOD_MS; const TickType_t xFrequency = FFT_MIN_CYCLE * portTICK_PERIOD_MS;
TickType_t xLastWakeTime = xTaskGetTickCount();
for(;;) { for(;;) {
TickType_t xLastWakeTime = xTaskGetTickCount();
delay(1); // DO NOT DELETE THIS LINE! It is needed to give the IDLE(0) task enough time and to keep the watchdog happy. delay(1); // DO NOT DELETE THIS LINE! It is needed to give the IDLE(0) task enough time and to keep the watchdog happy.
// taskYIELD(), yield(), vTaskDelay() and esp_task_wdt_feed() didn't seem to work. // taskYIELD(), yield(), vTaskDelay() and esp_task_wdt_feed() didn't seem to work.
vTaskDelayUntil( &xLastWakeTime, xFrequency); // release CPU, and let I2S fill its buffers // Don't run FFT computing code if we're in Receive mode or in realtime mode
// Only run the FFT computing code if we're not in Receive mode and not in realtime mode
if (disableSoundProcessing || (audioSyncEnabled & 0x02)) { if (disableSoundProcessing || (audioSyncEnabled & 0x02)) {
vTaskDelayUntil( &xLastWakeTime, xFrequency); // release CPU, and let I2S fill its buffers
continue; continue;
} }
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
uint64_t start = esp_timer_get_time(); uint64_t start = esp_timer_get_time();
#endif #endif
// get a fresh batch of samples from I2S // get a fresh batch of samples from I2S
if (audioSource) audioSource->getSamples(vReal, samplesFFT); if (audioSource) audioSource->getSamples(vReal, samplesFFT);
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
if (start < esp_timer_get_time()) { // filter out overflows if (start < esp_timer_get_time()) { // filter out overflows
unsigned long sampleTimeInMillis = (esp_timer_get_time() - start +500ULL) / 1000ULL; // "+500" to ensure proper rounding unsigned long sampleTimeInMillis = (esp_timer_get_time() - start +5ULL) / 10ULL; // "+5" to ensure proper rounding
sampleTime = (sampleTimeInMillis*3 + sampleTime*7)/10; // smooth sampleTime = (sampleTimeInMillis*3 + sampleTime*7)/10; // smooth
} }
#endif #endif
xLastWakeTime = xTaskGetTickCount(); // update "last unblocked time" for vTaskDelay
// find highest sample in the batch // find highest sample in the batch
float maxSample = 0.0f; // max sample from FFT batch float maxSample = 0.0f; // max sample from FFT batch
for (int i=0; i < samplesFFT; i++) { for (int i=0; i < samplesFFT; i++) {
@ -220,30 +224,42 @@ void FFTcode(void * parameter)
// early release allows the filters (getSample() and agcAvg()) to work with fresh values - we will have matching gain and noise gate values when we want to process the FFT results. micDataReal = maxSample; // early release allows the filters (getSample() and agcAvg()) to work with fresh values - we will have matching gain and noise gate values when we want to process the FFT results. micDataReal = maxSample;
micDataReal = maxSample; micDataReal = maxSample;
// run FFT (takes 3-5ms on ESP32) #ifdef SR_DEBUG
#ifdef UM_AUDIOREACTIVE_USE_NEW_FFT if (true) { // this allows measure FFT runtimes, as it disables the "only when needed" optimization
FFT.dcRemoval(); // remove DC offset
FFT.windowing( FFTWindow::Flat_top, FFTDirection::Forward); // Weigh data using "Flat Top" function - better amplitude accuracy
//FFT.windowing(FFTWindow::Blackman_Harris, FFTDirection::Forward); // Weigh data using "Blackman- Harris" window - sharp peaks due to excellent sideband rejection
FFT.compute( FFTDirection::Forward ); // Compute FFT
FFT.complexToMagnitude(); // Compute magnitudes
#else #else
FFT.DCRemoval(); // let FFT lib remove DC component, so we don't need to care about this in getSamples() if (sampleAvg > 1) { // noise gate open means that FFT results will be used. Don't run FFT if results are not needed.
#endif
//FFT.Windowing( FFT_WIN_TYP_HAMMING, FFT_FORWARD ); // Weigh data - standard Hamming window // run FFT (takes 3-5ms on ESP32, ~12ms on ESP32-S2)
//FFT.Windowing( FFT_WIN_TYP_BLACKMAN, FFT_FORWARD ); // Blackman window - better side freq rejection #ifdef UM_AUDIOREACTIVE_USE_NEW_FFT
//FFT.Windowing( FFT_WIN_TYP_BLACKMAN_HARRIS, FFT_FORWARD );// Blackman-Harris - excellent sideband rejection FFT.dcRemoval(); // remove DC offset
FFT.Windowing( FFT_WIN_TYP_FLT_TOP, FFT_FORWARD ); // Flat Top Window - better amplitude accuracy FFT.windowing( FFTWindow::Flat_top, FFTDirection::Forward); // Weigh data using "Flat Top" function - better amplitude accuracy
FFT.Compute( FFT_FORWARD ); // Compute FFT //FFT.windowing(FFTWindow::Blackman_Harris, FFTDirection::Forward); // Weigh data using "Blackman- Harris" window - sharp peaks due to excellent sideband rejection
FFT.ComplexToMagnitude(); // Compute magnitudes FFT.compute( FFTDirection::Forward ); // Compute FFT
FFT.complexToMagnitude(); // Compute magnitudes
#else
FFT.DCRemoval(); // let FFT lib remove DC component, so we don't need to care about this in getSamples()
//FFT.Windowing( FFT_WIN_TYP_HAMMING, FFT_FORWARD ); // Weigh data - standard Hamming window
//FFT.Windowing( FFT_WIN_TYP_BLACKMAN, FFT_FORWARD ); // Blackman window - better side freq rejection
//FFT.Windowing( FFT_WIN_TYP_BLACKMAN_HARRIS, FFT_FORWARD );// Blackman-Harris - excellent sideband rejection
FFT.Windowing( FFT_WIN_TYP_FLT_TOP, FFT_FORWARD ); // Flat Top Window - better amplitude accuracy
FFT.Compute( FFT_FORWARD ); // Compute FFT
FFT.ComplexToMagnitude(); // Compute magnitudes
#endif #endif
#ifdef UM_AUDIOREACTIVE_USE_NEW_FFT #ifdef UM_AUDIOREACTIVE_USE_NEW_FFT
FFT.majorPeak(FFT_MajorPeak, FFT_Magnitude); // let the effects know which freq was most dominant FFT.majorPeak(FFT_MajorPeak, FFT_Magnitude); // let the effects know which freq was most dominant
#else #else
FFT.MajorPeak(&FFT_MajorPeak, &FFT_Magnitude); // let the effects know which freq was most dominant FFT.MajorPeak(&FFT_MajorPeak, &FFT_Magnitude); // let the effects know which freq was most dominant
#endif #endif
FFT_MajorPeak = constrain(FFT_MajorPeak, 1.0f, 11025.0f); // restrict value to range expected by effects FFT_MajorPeak = constrain(FFT_MajorPeak, 1.0f, 11025.0f); // restrict value to range expected by effects
} else { // noise gate closed - only clear results as FFT was skipped. MIC samples are still valid when we do this.
memset(vReal, 0, sizeof(vReal));
FFT_MajorPeak = 1;
FFT_Magnitude = 0.001;
}
for (int i = 0; i < samplesFFT; i++) { for (int i = 0; i < samplesFFT; i++) {
float t = fabsf(vReal[i]); // just to be sure - values in fft bins should be positive any way float t = fabsf(vReal[i]); // just to be sure - values in fft bins should be positive any way
@ -380,9 +396,9 @@ void FFTcode(void * parameter)
fftResult[i] = constrain((int)currentResult, 0, 255); fftResult[i] = constrain((int)currentResult, 0, 255);
} }
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
if (start < esp_timer_get_time()) { // filter out overflows if (start < esp_timer_get_time()) { // filter out overflows
unsigned long fftTimeInMillis = ((esp_timer_get_time() - start) +500ULL) / 1000ULL; // "+500" to ensure proper rounding unsigned long fftTimeInMillis = ((esp_timer_get_time() - start) +5ULL) / 10ULL; // "+5" to ensure proper rounding
fftTime = (fftTimeInMillis*3 + fftTime*7)/10; // smooth fftTime = (fftTimeInMillis*3 + fftTime*7)/10; // smooth
} }
#endif #endif
@ -390,6 +406,8 @@ void FFTcode(void * parameter)
autoResetPeak(); autoResetPeak();
detectSamplePeak(); detectSamplePeak();
vTaskDelayUntil( &xLastWakeTime, xFrequency); // release CPU, and let I2S fill its buffers
} // for(;;)ever } // for(;;)ever
} // FFTcode() task end } // FFTcode() task end
@ -448,7 +466,7 @@ class AudioReactive : public Usermod {
int8_t i2swsPin = I2S_WSPIN; int8_t i2swsPin = I2S_WSPIN;
#endif #endif
#ifndef I2S_CKPIN // aka BCLK #ifndef I2S_CKPIN // aka BCLK
int8_t i2sckPin = 14; int8_t i2sckPin = 14; /*PDM: set to I2S_PIN_NO_CHANGE*/
#else #else
int8_t i2sckPin = I2S_CKPIN; int8_t i2sckPin = I2S_CKPIN;
#endif #endif
@ -463,9 +481,9 @@ class AudioReactive : public Usermod {
int8_t sclPin = ES7243_SCLPIN; int8_t sclPin = ES7243_SCLPIN;
#endif #endif
#ifndef MCLK_PIN #ifndef MCLK_PIN
int8_t mclkPin = -1; int8_t mclkPin = I2S_PIN_NO_CHANGE; /* ESP32: only -1, 0, 1, 3 allowed*/
#else #else
int8_t mclkPin = MLCK_PIN; int8_t mclkPin = MCLK_PIN;
#endif #endif
// new "V2" audiosync struct - 40 Bytes // new "V2" audiosync struct - 40 Bytes
@ -949,10 +967,18 @@ class AudioReactive : public Usermod {
// Reset I2S peripheral for good measure // Reset I2S peripheral for good measure
i2s_driver_uninstall(I2S_NUM_0); i2s_driver_uninstall(I2S_NUM_0);
periph_module_reset(PERIPH_I2S0_MODULE); #if !defined(CONFIG_IDF_TARGET_ESP32C3)
periph_module_reset(PERIPH_I2S0_MODULE); // not possible on -C3
#endif
delay(100); // Give that poor microphone some time to setup. delay(100); // Give that poor microphone some time to setup.
switch (dmType) { switch (dmType) {
#if defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C3) || defined(CONFIG_IDF_TARGET_ESP32S3)
// stub cases for not-yet-supported I2S modes on other ESP32 chips
case 0: //ADC analog
#if defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C3)
case 5: //PDM Microphone
#endif
#endif
case 1: case 1:
DEBUGSR_PRINT(F("AR: Generic I2S Microphone - ")); DEBUGSR_PRINTLN(F(I2S_MIC_CHANNEL_TEXT)); DEBUGSR_PRINT(F("AR: Generic I2S Microphone - ")); DEBUGSR_PRINTLN(F(I2S_MIC_CHANNEL_TEXT));
audioSource = new I2SSource(SAMPLE_RATE, BLOCK_SIZE); audioSource = new I2SSource(SAMPLE_RATE, BLOCK_SIZE);
@ -977,12 +1003,16 @@ class AudioReactive : public Usermod {
delay(100); delay(100);
if (audioSource) audioSource->initialize(i2swsPin, i2ssdPin, i2sckPin, mclkPin); if (audioSource) audioSource->initialize(i2swsPin, i2ssdPin, i2sckPin, mclkPin);
break; break;
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3)
case 5: case 5:
DEBUGSR_PRINT(F("AR: I2S PDM Microphone - ")); DEBUGSR_PRINTLN(F(I2S_MIC_CHANNEL_TEXT)); DEBUGSR_PRINT(F("AR: I2S PDM Microphone - ")); DEBUGSR_PRINTLN(F(I2S_MIC_CHANNEL_TEXT));
audioSource = new I2SSource(SAMPLE_RATE, BLOCK_SIZE); audioSource = new I2SSource(SAMPLE_RATE, BLOCK_SIZE);
delay(100); delay(100);
if (audioSource) audioSource->initialize(i2swsPin, i2ssdPin); if (audioSource) audioSource->initialize(i2swsPin, i2ssdPin);
break; break;
#endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
// ADC over I2S is only possible on "classic" ESP32
case 0: case 0:
default: default:
DEBUGSR_PRINTLN(F("AR: Analog Microphone (left channel only).")); DEBUGSR_PRINTLN(F("AR: Analog Microphone (left channel only)."));
@ -990,6 +1020,7 @@ class AudioReactive : public Usermod {
delay(100); delay(100);
if (audioSource) audioSource->initialize(audioPin); if (audioSource) audioSource->initialize(audioPin);
break; break;
#endif
} }
delay(250); // give microphone enough time to initialise delay(250); // give microphone enough time to initialise
@ -1357,13 +1388,15 @@ class AudioReactive : public Usermod {
infoArr.add("off"); infoArr.add("off");
if (audioSyncEnabled && !udpSyncConnected) infoArr.add(" <i>(unconnected)</i>"); if (audioSyncEnabled && !udpSyncConnected) infoArr.add(" <i>(unconnected)</i>");
#ifdef WLED_DEBUG #if defined(WLED_DEBUG) || defined(SR_DEBUG)
infoArr = user.createNestedArray(F("Sampling time")); infoArr = user.createNestedArray(F("Sampling time"));
infoArr.add(sampleTime); infoArr.add(float(sampleTime)/100.0f);
infoArr.add("ms"); infoArr.add(" ms");
infoArr = user.createNestedArray(F("FFT time")); infoArr = user.createNestedArray(F("FFT time"));
infoArr.add(fftTime-sampleTime); infoArr.add(float(fftTime-sampleTime)/100.0f);
infoArr.add("ms"); infoArr.add(" ms");
DEBUGSR_PRINTF("AR Sampling time: %5.2f ms\n", float(sampleTime)/100.0f);
DEBUGSR_PRINTF("AR FFT time : %5.2f ms\n", float(fftTime-sampleTime)/100.0f);
#endif #endif
} }
} }
@ -1529,12 +1562,16 @@ class AudioReactive : public Usermod {
void appendConfigData() void appendConfigData()
{ {
oappend(SET_F("dd=addDropdown('AudioReactive','digitalmic:type');")); oappend(SET_F("dd=addDropdown('AudioReactive','digitalmic:type');"));
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
oappend(SET_F("addOption(dd,'Generic Analog',0);")); oappend(SET_F("addOption(dd,'Generic Analog',0);"));
#endif
oappend(SET_F("addOption(dd,'Generic I2S',1);")); oappend(SET_F("addOption(dd,'Generic I2S',1);"));
oappend(SET_F("addOption(dd,'ES7243',2);")); oappend(SET_F("addOption(dd,'ES7243',2);"));
oappend(SET_F("addOption(dd,'SPH0654',3);")); oappend(SET_F("addOption(dd,'SPH0654',3);"));
oappend(SET_F("addOption(dd,'Generic I2S with Mclk',4);")); oappend(SET_F("addOption(dd,'Generic I2S with Mclk',4);"));
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3)
oappend(SET_F("addOption(dd,'Generic I2S PDM',5);")); oappend(SET_F("addOption(dd,'Generic I2S PDM',5);"));
#endif
oappend(SET_F("dd=addDropdown('AudioReactive','cfg:AGC');")); oappend(SET_F("dd=addDropdown('AudioReactive','cfg:AGC');"));
oappend(SET_F("addOption(dd,'Off',0);")); oappend(SET_F("addOption(dd,'Off',0);"));
oappend(SET_F("addOption(dd,'Normal',1);")); oappend(SET_F("addOption(dd,'Normal',1);"));
@ -1562,7 +1599,11 @@ class AudioReactive : public Usermod {
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',0,'I2S SD');")); oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',0,'I2S SD');"));
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',1,'I2S WS');")); oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',1,'I2S WS');"));
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',2,'I2S SCK');")); oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',2,'I2S SCK');"));
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',3,'I2S Master CLK');")); #if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',3,'I2S Master CLK <i>only use -1, 0, 1 or 3 for MCLK</i>');"));
#else
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',3,'I2S Master CLK');"));
#endif
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',4,'I2C SDA');")); oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',4,'I2C SDA');"));
oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',5,'I2C SCL');")); oappend(SET_F("addInfo('AudioReactive:digitalmic:pin[]',5,'I2C SCL');"));
} }

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@ -4,15 +4,31 @@
#include "wled.h" #include "wled.h"
#include <driver/i2s.h> #include <driver/i2s.h>
#include <driver/adc.h> #include <driver/adc.h>
#include <soc/i2s_reg.h> // needed for SPH0465 timing workaround (classic ESP32)
#if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 4, 0) #if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 4, 0)
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32S3) && !defined(CONFIG_IDF_TARGET_ESP32C3)
#include <driver/adc_deprecated.h> #include <driver/adc_deprecated.h>
#include <driver/adc_types_deprecated.h> #include <driver/adc_types_deprecated.h>
#endif #endif
// type of i2s_config_t.SampleRate was changed from "int" to "unsigned" in IDF 4.4.x
#define SRate_t uint32_t
#else
#define SRate_t int
#endif
//#include <driver/i2s_std.h> //#include <driver/i2s_std.h>
//#include <driver/i2s_pdm.h> //#include <driver/i2s_pdm.h>
//#include <driver/i2s_tdm.h>
//#include <driver/gpio.h> //#include <driver/gpio.h>
// see https://docs.espressif.com/projects/esp-idf/en/latest/esp32s3/hw-reference/chip-series-comparison.html#related-documents
// and https://docs.espressif.com/projects/esp-idf/en/latest/esp32s3/api-reference/peripherals/i2s.html#overview-of-all-modes
#if defined(CONFIG_IDF_TARGET_ESP32C2) || defined(CONFIG_IDF_TARGET_ESP32C3) || defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C5) || defined(CONFIG_IDF_TARGET_ESP32C6) || defined(CONFIG_IDF_TARGET_ESP32H2)
// there are two things in these MCUs that could lead to problems with audio processing:
// * no floating point hardware (FPU) support - FFT uses float calculations. If done in software, a strong slow-down can be expected (between 8x and 20x)
// * single core, so FFT task might slow down other things like LED updates
#warning This audio reactive usermod does not support ESP32-C2, ESP32-C3 or ESP32-S2.
#endif
/* ToDo: remove. ES7243 is controlled via compiler defines /* ToDo: remove. ES7243 is controlled via compiler defines
Until this configuration is moved to the webinterface Until this configuration is moved to the webinterface
@ -20,13 +36,6 @@
// if you have problems to get your microphone work on the left channel, uncomment the following line // if you have problems to get your microphone work on the left channel, uncomment the following line
//#define I2S_USE_RIGHT_CHANNEL // (experimental) define this to use right channel (digital mics only) //#define I2S_USE_RIGHT_CHANNEL // (experimental) define this to use right channel (digital mics only)
#ifdef I2S_USE_RIGHT_CHANNEL
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_RIGHT
#define I2S_MIC_CHANNEL_TEXT "right channel only."
#else
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_LEFT
#define I2S_MIC_CHANNEL_TEXT "left channel only."
#endif
// Uncomment the line below to utilize ADC1 _exclusively_ for I2S sound input. // Uncomment the line below to utilize ADC1 _exclusively_ for I2S sound input.
// benefit: analog mic inputs will be sampled contiously -> better response times and less "glitches" // benefit: analog mic inputs will be sampled contiously -> better response times and less "glitches"
@ -36,18 +45,56 @@
// data type requested from the I2S driver - currently we always use 32bit // data type requested from the I2S driver - currently we always use 32bit
//#define I2S_USE_16BIT_SAMPLES // (experimental) define this to request 16bit - more efficient but possibly less compatible //#define I2S_USE_16BIT_SAMPLES // (experimental) define this to request 16bit - more efficient but possibly less compatible
#ifdef I2S_USE_16BIT_SAMPLES #ifdef I2S_USE_16BIT_SAMPLES
#define I2S_SAMPLE_RESOLUTION I2S_BITS_PER_SAMPLE_16BIT #define I2S_SAMPLE_RESOLUTION I2S_BITS_PER_SAMPLE_16BIT
#define I2S_datatype int16_t #define I2S_datatype int16_t
#define I2S_unsigned_datatype uint16_t #define I2S_unsigned_datatype uint16_t
#define I2S_data_size I2S_BITS_PER_CHAN_16BIT
#undef I2S_SAMPLE_DOWNSCALE_TO_16BIT #undef I2S_SAMPLE_DOWNSCALE_TO_16BIT
#else #else
#define I2S_SAMPLE_RESOLUTION I2S_BITS_PER_SAMPLE_32BIT #define I2S_SAMPLE_RESOLUTION I2S_BITS_PER_SAMPLE_32BIT
//#define I2S_SAMPLE_RESOLUTION I2S_BITS_PER_SAMPLE_24BIT
#define I2S_datatype int32_t #define I2S_datatype int32_t
#define I2S_unsigned_datatype uint32_t #define I2S_unsigned_datatype uint32_t
#define I2S_data_size I2S_BITS_PER_CHAN_32BIT
#define I2S_SAMPLE_DOWNSCALE_TO_16BIT #define I2S_SAMPLE_DOWNSCALE_TO_16BIT
#endif #endif
/* There are several (confusing) options in IDF 4.4.x:
* I2S_CHANNEL_FMT_RIGHT_LEFT, I2S_CHANNEL_FMT_ALL_RIGHT and I2S_CHANNEL_FMT_ALL_LEFT stands for stereo mode, which means two channels will transport different data.
* I2S_CHANNEL_FMT_ONLY_RIGHT and I2S_CHANNEL_FMT_ONLY_LEFT they are mono mode, both channels will only transport same data.
* I2S_CHANNEL_FMT_MULTIPLE means TDM channels, up to 16 channel will available, and they are stereo as default.
* if you want to receive two channels, one is the actual data from microphone and another channel is suppose to receive 0, it's different data in two channels, you need to choose I2S_CHANNEL_FMT_RIGHT_LEFT in this case.
*/
#if (ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 4, 0)) && (ESP_IDF_VERSION <= ESP_IDF_VERSION_VAL(4, 4, 3))
// espressif bug: only_left has no sound, left and right are swapped
// https://github.com/espressif/esp-idf/issues/9635 I2S mic not working since 4.4 (IDFGH-8138)
// https://github.com/espressif/esp-idf/issues/8538 I2S channel selection issue? (IDFGH-6918)
// https://github.com/espressif/esp-idf/issues/6625 I2S: left/right channels are swapped for read (IDFGH-4826)
#ifdef I2S_USE_RIGHT_CHANNEL
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_LEFT
#define I2S_MIC_CHANNEL_TEXT "right channel only (work-around swapped channel bug in IDF 4.4)."
#else
//#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ALL_LEFT
//#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_RIGHT_LEFT
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_RIGHT
#define I2S_MIC_CHANNEL_TEXT "left channel only (work-around swapped channel bug in IDF 4.4)."
#endif
#else
// not swapped
#ifdef I2S_USE_RIGHT_CHANNEL
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_RIGHT
#define I2S_MIC_CHANNEL_TEXT "right channel only."
#else
#define I2S_MIC_CHANNEL I2S_CHANNEL_FMT_ONLY_LEFT
#define I2S_MIC_CHANNEL_TEXT "left channel only."
#endif
#endif
/* Interface class /* Interface class
AudioSource serves as base class for all microphone types AudioSource serves as base class for all microphone types
This enables accessing all microphones with one single interface This enables accessing all microphones with one single interface
@ -91,13 +138,13 @@ class AudioSource {
virtual I2S_datatype postProcessSample(I2S_datatype sample_in) {return(sample_in);} // default method can be overriden by instances (ADC) that need sample postprocessing virtual I2S_datatype postProcessSample(I2S_datatype sample_in) {return(sample_in);} // default method can be overriden by instances (ADC) that need sample postprocessing
// Private constructor, to make sure it is not callable except from derived classes // Private constructor, to make sure it is not callable except from derived classes
AudioSource(int sampleRate, int blockSize) : AudioSource(SRate_t sampleRate, int blockSize) :
_sampleRate(sampleRate), _sampleRate(sampleRate),
_blockSize(blockSize), _blockSize(blockSize),
_initialized(false) _initialized(false)
{}; {};
int _sampleRate; // Microphone sampling rate SRate_t _sampleRate; // Microphone sampling rate
int _blockSize; // I2S block size int _blockSize; // I2S block size
bool _initialized; // Gets set to true if initialization is successful bool _initialized; // Gets set to true if initialization is successful
}; };
@ -107,7 +154,7 @@ class AudioSource {
*/ */
class I2SSource : public AudioSource { class I2SSource : public AudioSource {
public: public:
I2SSource(int sampleRate, int blockSize) : I2SSource(SRate_t sampleRate, int blockSize) :
AudioSource(sampleRate, blockSize) { AudioSource(sampleRate, blockSize) {
_config = { _config = {
.mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX), .mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX),
@ -116,12 +163,19 @@ class I2SSource : public AudioSource {
.channel_format = I2S_MIC_CHANNEL, .channel_format = I2S_MIC_CHANNEL,
#if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 2, 0) #if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 2, 0)
.communication_format = i2s_comm_format_t(I2S_COMM_FORMAT_STAND_I2S), .communication_format = i2s_comm_format_t(I2S_COMM_FORMAT_STAND_I2S),
//.intr_alloc_flags = ESP_INTR_FLAG_LEVEL1,
.intr_alloc_flags = ESP_INTR_FLAG_LEVEL2,
.dma_buf_count = 8,
.dma_buf_len = _blockSize,
.use_apll = 0,
.bits_per_chan = I2S_data_size,
#else #else
.communication_format = i2s_comm_format_t(I2S_COMM_FORMAT_I2S | I2S_COMM_FORMAT_I2S_MSB), .communication_format = i2s_comm_format_t(I2S_COMM_FORMAT_I2S | I2S_COMM_FORMAT_I2S_MSB),
#endif
.intr_alloc_flags = ESP_INTR_FLAG_LEVEL1, .intr_alloc_flags = ESP_INTR_FLAG_LEVEL1,
.dma_buf_count = 8, .dma_buf_count = 8,
.dma_buf_len = _blockSize .dma_buf_len = _blockSize,
.use_apll = false
#endif
}; };
} }
@ -129,18 +183,24 @@ class I2SSource : public AudioSource {
if (i2swsPin != I2S_PIN_NO_CHANGE && i2ssdPin != I2S_PIN_NO_CHANGE) { if (i2swsPin != I2S_PIN_NO_CHANGE && i2ssdPin != I2S_PIN_NO_CHANGE) {
if (!pinManager.allocatePin(i2swsPin, true, PinOwner::UM_Audioreactive) || if (!pinManager.allocatePin(i2swsPin, true, PinOwner::UM_Audioreactive) ||
!pinManager.allocatePin(i2ssdPin, false, PinOwner::UM_Audioreactive)) { // #206 !pinManager.allocatePin(i2ssdPin, false, PinOwner::UM_Audioreactive)) { // #206
DEBUGSR_PRINTF("\nAR: Failed to allocate I2S pins: ws=%d, sd=%d\n", i2swsPin, i2ssdPin);
return; return;
} }
} }
// i2ssckPin needs special treatment, since it might be unused on PDM mics // i2ssckPin needs special treatment, since it might be unused on PDM mics
if (i2sckPin != I2S_PIN_NO_CHANGE) { if (i2sckPin != I2S_PIN_NO_CHANGE) {
if (!pinManager.allocatePin(i2sckPin, true, PinOwner::UM_Audioreactive)) return; if (!pinManager.allocatePin(i2sckPin, true, PinOwner::UM_Audioreactive)) {
DEBUGSR_PRINTF("\nAR: Failed to allocate I2S pins: sck=%d\n", i2sckPin);
return;
}
} else { } else {
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3)
// This is an I2S PDM microphone, these microphones only use a clock and // This is an I2S PDM microphone, these microphones only use a clock and
// data line, to make it simpler to debug, use the WS pin as CLK and SD // data line, to make it simpler to debug, use the WS pin as CLK and SD
// pin as DATA // pin as DATA
_config.mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX | I2S_MODE_PDM); // Change mode to pdm if clock pin not provided _config.mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX | I2S_MODE_PDM); // Change mode to pdm if clock pin not provided. PDM is not supported on ESP32-S2. PDM RX not supported on ESP32-C3
#endif
} }
// Reserve the master clock pin if provided // Reserve the master clock pin if provided
@ -151,6 +211,9 @@ class I2SSource : public AudioSource {
} }
_pinConfig = { _pinConfig = {
#if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 4, 0)
.mck_io_num = mclkPin, // "classic" ESP32 supports setting MCK on GPIO0/GPIO1/GPIO3 only. i2s_set_pin() will fail if wrong mck_io_num is provided.
#endif
.bck_io_num = i2sckPin, .bck_io_num = i2sckPin,
.ws_io_num = i2swsPin, .ws_io_num = i2swsPin,
.data_out_num = I2S_PIN_NO_CHANGE, .data_out_num = I2S_PIN_NO_CHANGE,
@ -166,9 +229,18 @@ class I2SSource : public AudioSource {
err = i2s_set_pin(I2S_NUM_0, &_pinConfig); err = i2s_set_pin(I2S_NUM_0, &_pinConfig);
if (err != ESP_OK) { if (err != ESP_OK) {
DEBUGSR_PRINTF("Failed to set i2s pin config: %d\n", err); DEBUGSR_PRINTF("Failed to set i2s pin config: %d\n", err);
i2s_driver_uninstall(I2S_NUM_0); // uninstall already-installed driver
return; return;
} }
#if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 2, 0)
err = i2s_set_clk(I2S_NUM_0, _sampleRate, I2S_SAMPLE_RESOLUTION, I2S_CHANNEL_MONO); // set bit clocks. Also takes care of MCLK routing if needed.
if (err != ESP_OK) {
DEBUGSR_PRINTF("Failed to configure i2s clocks: %d\n", err);
i2s_driver_uninstall(I2S_NUM_0); // uninstall already-installed driver
return;
}
#endif
_initialized = true; _initialized = true;
} }
@ -222,7 +294,11 @@ class I2SSource : public AudioSource {
protected: protected:
void _routeMclk(int8_t mclkPin) { void _routeMclk(int8_t mclkPin) {
/* Enable the mclk routing depending on the selected mclk pin #if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
// MCLK routing by writing registers is not needed any more with IDF > 4.4.0
#if ESP_IDF_VERSION < ESP_IDF_VERSION_VAL(4, 4, 0)
// this way of MCLK routing only works on "classic" ESP32
/* Enable the mclk routing depending on the selected mclk pin (ESP32: only 0,1,3)
Only I2S_NUM_0 is supported Only I2S_NUM_0 is supported
*/ */
if (mclkPin == GPIO_NUM_0) { if (mclkPin == GPIO_NUM_0) {
@ -235,6 +311,8 @@ class I2SSource : public AudioSource {
PIN_FUNC_SELECT(PERIPHS_IO_MUX_U0RXD_U, FUNC_U0RXD_CLK_OUT2); PIN_FUNC_SELECT(PERIPHS_IO_MUX_U0RXD_U, FUNC_U0RXD_CLK_OUT2);
WRITE_PERI_REG(PIN_CTRL, 0xFF00); WRITE_PERI_REG(PIN_CTRL, 0xFF00);
} }
#endif
#endif
} }
i2s_config_t _config; i2s_config_t _config;
@ -275,7 +353,7 @@ class ES7243 : public I2SSource {
} }
public: public:
ES7243(int sampleRate, int blockSize) : ES7243(SRate_t sampleRate, int blockSize) :
I2SSource(sampleRate, blockSize) { I2SSource(sampleRate, blockSize) {
_config.channel_format = I2S_CHANNEL_FMT_ONLY_RIGHT; _config.channel_format = I2S_CHANNEL_FMT_ONLY_RIGHT;
}; };
@ -307,6 +385,9 @@ public:
int8_t pin_ES7243_SCL; int8_t pin_ES7243_SCL;
}; };
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
// ADC over I2S is only availeable in "classic" ESP32
/* ADC over I2S Microphone /* ADC over I2S Microphone
This microphone is an ADC pin sampled via the I2S interval This microphone is an ADC pin sampled via the I2S interval
This allows to use the I2S API to obtain ADC samples with high sample rates This allows to use the I2S API to obtain ADC samples with high sample rates
@ -314,7 +395,7 @@ public:
*/ */
class I2SAdcSource : public I2SSource { class I2SAdcSource : public I2SSource {
public: public:
I2SAdcSource(int sampleRate, int blockSize) : I2SAdcSource(SRate_t sampleRate, int blockSize) :
I2SSource(sampleRate, blockSize) { I2SSource(sampleRate, blockSize) {
_config = { _config = {
.mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX | I2S_MODE_ADC_BUILT_IN), .mode = i2s_mode_t(I2S_MODE_MASTER | I2S_MODE_RX | I2S_MODE_ADC_BUILT_IN),
@ -363,13 +444,17 @@ class I2SAdcSource : public I2SSource {
return; return;
} }
adc1_config_width(ADC_WIDTH_BIT_12); // ensure that ADC runs with 12bit resolution
// Enable I2S mode of ADC // Enable I2S mode of ADC
err = i2s_set_adc_mode(ADC_UNIT_1, adc1_channel_t(channel)); err = i2s_set_adc_mode(ADC_UNIT_1, adc1_channel_t(channel));
if (err != ESP_OK) { if (err != ESP_OK) {
DEBUGSR_PRINTF("Failed to set i2s adc mode: %d\n", err); DEBUGSR_PRINTF("Failed to set i2s adc mode: %d\n", err);
return; return;
} }
// adc1_config_channel_atten(adc1_channel_t(channel), ADC_ATTEN_DB_11)); //see https://github.com/espressif/arduino-esp32/blob/master/libraries/ESP32/examples/I2S/HiFreq_ADC/HiFreq_ADC.ino
// see example in https://github.com/espressif/arduino-esp32/blob/master/libraries/ESP32/examples/I2S/HiFreq_ADC/HiFreq_ADC.ino
adc1_config_channel_atten(adc1_channel_t(channel), ADC_ATTEN_DB_11); // configure ADC input amplification
#if defined(I2S_GRAB_ADC1_COMPLETELY) #if defined(I2S_GRAB_ADC1_COMPLETELY)
// according to docs from espressif, the ADC needs to be started explicitly // according to docs from espressif, the ADC needs to be started explicitly
@ -489,20 +574,29 @@ class I2SAdcSource : public I2SSource {
int8_t _audioPin; int8_t _audioPin;
int8_t _myADCchannel = 0x0F; // current ADC channel for analog input. 0x0F means "undefined" int8_t _myADCchannel = 0x0F; // current ADC channel for analog input. 0x0F means "undefined"
}; };
#endif
/* SPH0645 Microphone /* SPH0645 Microphone
This is an I2S microphone with some timing quirks that need This is an I2S microphone with some timing quirks that need
special consideration. special consideration.
*/ */
// https://github.com/espressif/esp-idf/issues/7192 SPH0645 i2s microphone issue when migrate from legacy esp-idf version (IDFGH-5453)
// a user recommended this: Try to set .communication_format to I2S_COMM_FORMAT_STAND_I2S and call i2s_set_clk() after i2s_set_pin().
class SPH0654 : public I2SSource { class SPH0654 : public I2SSource {
public: public:
SPH0654(int sampleRate, int blockSize) : SPH0654(SRate_t sampleRate, int blockSize) :
I2SSource(sampleRate, blockSize) I2SSource(sampleRate, blockSize)
{} {}
void initialize(uint8_t i2swsPin, uint8_t i2ssdPin, uint8_t i2sckPin, int8_t = I2S_PIN_NO_CHANGE, int8_t = I2S_PIN_NO_CHANGE, int8_t = I2S_PIN_NO_CHANGE) { void initialize(uint8_t i2swsPin, uint8_t i2ssdPin, uint8_t i2sckPin, int8_t = I2S_PIN_NO_CHANGE, int8_t = I2S_PIN_NO_CHANGE, int8_t = I2S_PIN_NO_CHANGE) {
I2SSource::initialize(i2swsPin, i2ssdPin, i2sckPin); I2SSource::initialize(i2swsPin, i2ssdPin, i2sckPin);
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S3)
// these registers are only existing in "classic" ESP32
REG_SET_BIT(I2S_TIMING_REG(I2S_NUM_0), BIT(9)); REG_SET_BIT(I2S_TIMING_REG(I2S_NUM_0), BIT(9));
REG_SET_BIT(I2S_CONF_REG(I2S_NUM_0), I2S_RX_MSB_SHIFT); REG_SET_BIT(I2S_CONF_REG(I2S_NUM_0), I2S_RX_MSB_SHIFT);
#else
#warning FIX ME! Please.
#endif
} }
}; };

View File

@ -7099,7 +7099,7 @@ uint16_t mode_2DGEQ(void) { // By Will Tatam. Code reduction by Ewoud Wijma.
if (SEGENV.call == 0) for (int i=0; i<cols; i++) previousBarHeight[i] = 0; if (SEGENV.call == 0) for (int i=0; i<cols; i++) previousBarHeight[i] = 0;
bool rippleTime = false; bool rippleTime = false;
if (millis() - SEGENV.step >= (256 - SEGMENT.intensity)) { if (millis() - SEGENV.step >= (256U - SEGMENT.intensity)) {
SEGENV.step = millis(); SEGENV.step = millis();
rippleTime = true; rippleTime = true;
} }

View File

@ -504,7 +504,7 @@ class BusOnOff : public Bus {
uint8_t currentPin = bc.pins[0]; uint8_t currentPin = bc.pins[0];
if (!pinManager.allocatePin(currentPin, true, PinOwner::BusOnOff)) { if (!pinManager.allocatePin(currentPin, true, PinOwner::BusOnOff)) {
deallocatePins(); return; return;
} }
_pin = currentPin; //store only after allocatePin() succeeds _pin = currentPin; //store only after allocatePin() succeeds
pinMode(_pin, OUTPUT); pinMode(_pin, OUTPUT);
@ -540,7 +540,7 @@ class BusOnOff : public Bus {
} }
void cleanup() { void cleanup() {
deallocatePins(); pinManager.deallocatePin(_pin, PinOwner::BusOnOff);
} }
~BusOnOff() { ~BusOnOff() {
@ -550,10 +550,6 @@ class BusOnOff : public Bus {
private: private:
uint8_t _pin = 255; uint8_t _pin = 255;
uint8_t _data = 0; uint8_t _data = 0;
void deallocatePins() {
pinManager.deallocatePin(_pin, PinOwner::BusOnOff);
}
}; };
@ -689,6 +685,8 @@ class BusManager {
busses[numBusses] = new BusNetwork(bc); busses[numBusses] = new BusNetwork(bc);
} else if (IS_DIGITAL(bc.type)) { } else if (IS_DIGITAL(bc.type)) {
busses[numBusses] = new BusDigital(bc, numBusses, colorOrderMap); busses[numBusses] = new BusDigital(bc, numBusses, colorOrderMap);
} else if (bc.type == TYPE_ONOFF) {
busses[numBusses] = new BusOnOff(bc);
} else { } else {
busses[numBusses] = new BusPwm(bc); busses[numBusses] = new BusPwm(bc);
} }

View File

@ -3,6 +3,18 @@
#include "NeoPixelBrightnessBus.h" #include "NeoPixelBrightnessBus.h"
// temporary - these defines should actually be set in platformio.ini
// C3: I2S0 and I2S1 methods not supported
// S2: I2S1 methods not supported
// S3: I2S0 and I2S1 methods not supported yet
#if !defined(WLED_NO_I2S0_PIXELBUS) && (defined(CONFIG_IDF_TARGET_ESP32S3) || defined(CONFIG_IDF_TARGET_ESP32C3))
#define WLED_NO_I2S0_PIXELBUS
#endif
#if !defined(WLED_NO_I2S1_PIXELBUS) && (defined(CONFIG_IDF_TARGET_ESP32S3) || defined(CONFIG_IDF_TARGET_ESP32C3) || defined(CONFIG_IDF_TARGET_ESP32S2))
#define WLED_NO_I2S1_PIXELBUS
#endif
// temporary end
//Hardware SPI Pins //Hardware SPI Pins
#define P_8266_HS_MOSI 13 #define P_8266_HS_MOSI 13
#define P_8266_HS_CLK 14 #define P_8266_HS_CLK 14
@ -117,43 +129,43 @@
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
//RGB //RGB
#define B_32_RN_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32RmtNWs2812xMethod> #define B_32_RN_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32RmtNWs2812xMethod>
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
#define B_32_I0_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s0800KbpsMethod> #define B_32_I0_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s0800KbpsMethod>
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
#define B_32_I1_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s1800KbpsMethod> #define B_32_I1_NEO_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s1800KbpsMethod>
#endif #endif
//RGBW //RGBW
#define B_32_RN_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32RmtNWs2812xMethod> #define B_32_RN_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32RmtNWs2812xMethod>
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
#define B_32_I0_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32I2s0800KbpsMethod> #define B_32_I0_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32I2s0800KbpsMethod>
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
#define B_32_I1_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32I2s1800KbpsMethod> #define B_32_I1_NEO_4 NeoPixelBrightnessBus<NeoGrbwFeature, NeoEsp32I2s1800KbpsMethod>
#endif #endif
//400Kbps //400Kbps
#define B_32_RN_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32RmtN400KbpsMethod> #define B_32_RN_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32RmtN400KbpsMethod>
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
#define B_32_I0_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s0400KbpsMethod> #define B_32_I0_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s0400KbpsMethod>
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
#define B_32_I1_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s1400KbpsMethod> #define B_32_I1_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s1400KbpsMethod>
#endif #endif
//TM1814 (RGBW) //TM1814 (RGBW)
#define B_32_RN_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32RmtNTm1814Method> #define B_32_RN_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32RmtNTm1814Method>
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
#define B_32_I0_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32I2s0Tm1814Method> #define B_32_I0_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32I2s0Tm1814Method>
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
#define B_32_I1_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32I2s1Tm1814Method> #define B_32_I1_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32I2s1Tm1814Method>
#endif #endif
//Bit Bang theoratically possible, but very undesirable and not needed (no pin restrictions on RMT and I2S) //Bit Bang theoratically possible, but very undesirable and not needed (no pin restrictions on RMT and I2S)
//TM1829 (RGB) //TM1829 (RGB)
#define B_32_RN_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32RmtNTm1829Method> #define B_32_RN_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32RmtNTm1829Method>
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
#define B_32_I0_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32I2s0Tm1829Method> #define B_32_I0_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32I2s0Tm1829Method>
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
#define B_32_I1_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32I2s1Tm1829Method> #define B_32_I1_TM2_3 NeoPixelBrightnessBus<NeoBrgFeature, NeoEsp32I2s1Tm1829Method>
#endif #endif
//Bit Bang theoratically possible, but very undesirable and not needed (no pin restrictions on RMT and I2S) //Bit Bang theoratically possible, but very undesirable and not needed (no pin restrictions on RMT and I2S)
@ -237,33 +249,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->Begin(); break; case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->Begin(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->Begin(); break; case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->Begin(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->Begin(); break; case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->Begin(); break;
#endif #endif
case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->Begin(); break; case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->Begin(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->Begin(); break; case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->Begin(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->Begin(); break; case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->Begin(); break;
#endif #endif
case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->Begin(); break; case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->Begin(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->Begin(); break; case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->Begin(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->Begin(); break; case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->Begin(); break;
#endif #endif
case I_32_RN_TM1_4: beginTM1814<B_32_RN_TM1_4*>(busPtr); break; case I_32_RN_TM1_4: beginTM1814<B_32_RN_TM1_4*>(busPtr); break;
case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->Begin(); break; case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->Begin(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: beginTM1814<B_32_I0_TM1_4*>(busPtr); break; case I_32_I0_TM1_4: beginTM1814<B_32_I0_TM1_4*>(busPtr); break;
case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->Begin(); break; case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->Begin(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: beginTM1814<B_32_I1_TM1_4*>(busPtr); break; case I_32_I1_TM1_4: beginTM1814<B_32_I1_TM1_4*>(busPtr); break;
case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->Begin(); break; case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->Begin(); break;
#endif #endif
@ -309,33 +321,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: busPtr = new B_32_RN_NEO_3(len, pins[0], (NeoBusChannel)channel); break; case I_32_RN_NEO_3: busPtr = new B_32_RN_NEO_3(len, pins[0], (NeoBusChannel)channel); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: busPtr = new B_32_I0_NEO_3(len, pins[0]); break; case I_32_I0_NEO_3: busPtr = new B_32_I0_NEO_3(len, pins[0]); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: busPtr = new B_32_I1_NEO_3(len, pins[0]); break; case I_32_I1_NEO_3: busPtr = new B_32_I1_NEO_3(len, pins[0]); break;
#endif #endif
case I_32_RN_NEO_4: busPtr = new B_32_RN_NEO_4(len, pins[0], (NeoBusChannel)channel); break; case I_32_RN_NEO_4: busPtr = new B_32_RN_NEO_4(len, pins[0], (NeoBusChannel)channel); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: busPtr = new B_32_I0_NEO_4(len, pins[0]); break; case I_32_I0_NEO_4: busPtr = new B_32_I0_NEO_4(len, pins[0]); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: busPtr = new B_32_I1_NEO_4(len, pins[0]); break; case I_32_I1_NEO_4: busPtr = new B_32_I1_NEO_4(len, pins[0]); break;
#endif #endif
case I_32_RN_400_3: busPtr = new B_32_RN_400_3(len, pins[0], (NeoBusChannel)channel); break; case I_32_RN_400_3: busPtr = new B_32_RN_400_3(len, pins[0], (NeoBusChannel)channel); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: busPtr = new B_32_I0_400_3(len, pins[0]); break; case I_32_I0_400_3: busPtr = new B_32_I0_400_3(len, pins[0]); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: busPtr = new B_32_I1_400_3(len, pins[0]); break; case I_32_I1_400_3: busPtr = new B_32_I1_400_3(len, pins[0]); break;
#endif #endif
case I_32_RN_TM1_4: busPtr = new B_32_RN_TM1_4(len, pins[0], (NeoBusChannel)channel); break; case I_32_RN_TM1_4: busPtr = new B_32_RN_TM1_4(len, pins[0], (NeoBusChannel)channel); break;
case I_32_RN_TM2_3: busPtr = new B_32_RN_TM2_3(len, pins[0], (NeoBusChannel)channel); break; case I_32_RN_TM2_3: busPtr = new B_32_RN_TM2_3(len, pins[0], (NeoBusChannel)channel); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: busPtr = new B_32_I0_TM1_4(len, pins[0]); break; case I_32_I0_TM1_4: busPtr = new B_32_I0_TM1_4(len, pins[0]); break;
case I_32_I0_TM2_3: busPtr = new B_32_I0_TM2_3(len, pins[0]); break; case I_32_I0_TM2_3: busPtr = new B_32_I0_TM2_3(len, pins[0]); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: busPtr = new B_32_I1_TM1_4(len, pins[0]); break; case I_32_I1_TM1_4: busPtr = new B_32_I1_TM1_4(len, pins[0]); break;
case I_32_I1_TM2_3: busPtr = new B_32_I1_TM2_3(len, pins[0]); break; case I_32_I1_TM2_3: busPtr = new B_32_I1_TM2_3(len, pins[0]); break;
#endif #endif
@ -382,33 +394,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->Show(); break; case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->Show(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->Show(); break; case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->Show(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->Show(); break; case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->Show(); break;
#endif #endif
case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->Show(); break; case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->Show(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->Show(); break; case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->Show(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->Show(); break; case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->Show(); break;
#endif #endif
case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->Show(); break; case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->Show(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->Show(); break; case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->Show(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->Show(); break; case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->Show(); break;
#endif #endif
case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->Show(); break; case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->Show(); break;
case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->Show(); break; case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->Show(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->Show(); break; case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->Show(); break;
case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->Show(); break; case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->Show(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->Show(); break; case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->Show(); break;
case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->Show(); break; case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->Show(); break;
#endif #endif
@ -452,33 +464,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: return (static_cast<B_32_RN_NEO_3*>(busPtr))->CanShow(); break; case I_32_RN_NEO_3: return (static_cast<B_32_RN_NEO_3*>(busPtr))->CanShow(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: return (static_cast<B_32_I0_NEO_3*>(busPtr))->CanShow(); break; case I_32_I0_NEO_3: return (static_cast<B_32_I0_NEO_3*>(busPtr))->CanShow(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: return (static_cast<B_32_I1_NEO_3*>(busPtr))->CanShow(); break; case I_32_I1_NEO_3: return (static_cast<B_32_I1_NEO_3*>(busPtr))->CanShow(); break;
#endif #endif
case I_32_RN_NEO_4: return (static_cast<B_32_RN_NEO_4*>(busPtr))->CanShow(); break; case I_32_RN_NEO_4: return (static_cast<B_32_RN_NEO_4*>(busPtr))->CanShow(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: return (static_cast<B_32_I0_NEO_4*>(busPtr))->CanShow(); break; case I_32_I0_NEO_4: return (static_cast<B_32_I0_NEO_4*>(busPtr))->CanShow(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: return (static_cast<B_32_I1_NEO_4*>(busPtr))->CanShow(); break; case I_32_I1_NEO_4: return (static_cast<B_32_I1_NEO_4*>(busPtr))->CanShow(); break;
#endif #endif
case I_32_RN_400_3: return (static_cast<B_32_RN_400_3*>(busPtr))->CanShow(); break; case I_32_RN_400_3: return (static_cast<B_32_RN_400_3*>(busPtr))->CanShow(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: return (static_cast<B_32_I0_400_3*>(busPtr))->CanShow(); break; case I_32_I0_400_3: return (static_cast<B_32_I0_400_3*>(busPtr))->CanShow(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: return (static_cast<B_32_I1_400_3*>(busPtr))->CanShow(); break; case I_32_I1_400_3: return (static_cast<B_32_I1_400_3*>(busPtr))->CanShow(); break;
#endif #endif
case I_32_RN_TM1_4: return (static_cast<B_32_RN_TM1_4*>(busPtr))->CanShow(); break; case I_32_RN_TM1_4: return (static_cast<B_32_RN_TM1_4*>(busPtr))->CanShow(); break;
case I_32_RN_TM2_3: return (static_cast<B_32_RN_TM2_3*>(busPtr))->CanShow(); break; case I_32_RN_TM2_3: return (static_cast<B_32_RN_TM2_3*>(busPtr))->CanShow(); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: return (static_cast<B_32_I0_TM1_4*>(busPtr))->CanShow(); break; case I_32_I0_TM1_4: return (static_cast<B_32_I0_TM1_4*>(busPtr))->CanShow(); break;
case I_32_I0_TM2_3: return (static_cast<B_32_I0_TM2_3*>(busPtr))->CanShow(); break; case I_32_I0_TM2_3: return (static_cast<B_32_I0_TM2_3*>(busPtr))->CanShow(); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: return (static_cast<B_32_I1_TM1_4*>(busPtr))->CanShow(); break; case I_32_I1_TM1_4: return (static_cast<B_32_I1_TM1_4*>(busPtr))->CanShow(); break;
case I_32_I1_TM2_3: return (static_cast<B_32_I1_TM2_3*>(busPtr))->CanShow(); break; case I_32_I1_TM2_3: return (static_cast<B_32_I1_TM2_3*>(busPtr))->CanShow(); break;
#endif #endif
@ -546,33 +558,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->SetPixelColor(pix, col); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->SetPixelColor(pix, col); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->SetPixelColor(pix, col); break;
#endif #endif
case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->SetPixelColor(pix, col); break;
case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->SetPixelColor(pix, col); break;
case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->SetPixelColor(pix, col); break; case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->SetPixelColor(pix, col); break;
case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break; case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->SetPixelColor(pix, RgbColor(col.R,col.G,col.B)); break;
#endif #endif
@ -616,33 +628,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->SetBrightness(b); break; case I_32_RN_NEO_3: (static_cast<B_32_RN_NEO_3*>(busPtr))->SetBrightness(b); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->SetBrightness(b); break; case I_32_I0_NEO_3: (static_cast<B_32_I0_NEO_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->SetBrightness(b); break; case I_32_I1_NEO_3: (static_cast<B_32_I1_NEO_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->SetBrightness(b); break; case I_32_RN_NEO_4: (static_cast<B_32_RN_NEO_4*>(busPtr))->SetBrightness(b); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->SetBrightness(b); break; case I_32_I0_NEO_4: (static_cast<B_32_I0_NEO_4*>(busPtr))->SetBrightness(b); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->SetBrightness(b); break; case I_32_I1_NEO_4: (static_cast<B_32_I1_NEO_4*>(busPtr))->SetBrightness(b); break;
#endif #endif
case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->SetBrightness(b); break; case I_32_RN_400_3: (static_cast<B_32_RN_400_3*>(busPtr))->SetBrightness(b); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->SetBrightness(b); break; case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->SetBrightness(b); break; case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->SetBrightness(b); break; case I_32_RN_TM1_4: (static_cast<B_32_RN_TM1_4*>(busPtr))->SetBrightness(b); break;
case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->SetBrightness(b); break; case I_32_RN_TM2_3: (static_cast<B_32_RN_TM2_3*>(busPtr))->SetBrightness(b); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->SetBrightness(b); break; case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->SetBrightness(b); break;
case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->SetBrightness(b); break; case I_32_I0_TM2_3: (static_cast<B_32_I0_TM2_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->SetBrightness(b); break; case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->SetBrightness(b); break;
case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->SetBrightness(b); break; case I_32_I1_TM2_3: (static_cast<B_32_I1_TM2_3*>(busPtr))->SetBrightness(b); break;
#endif #endif
@ -687,33 +699,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: col = (static_cast<B_32_RN_NEO_3*>(busPtr))->GetPixelColor(pix); break; case I_32_RN_NEO_3: col = (static_cast<B_32_RN_NEO_3*>(busPtr))->GetPixelColor(pix); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: col = (static_cast<B_32_I0_NEO_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I0_NEO_3: col = (static_cast<B_32_I0_NEO_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: col = (static_cast<B_32_I1_NEO_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I1_NEO_3: col = (static_cast<B_32_I1_NEO_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
case I_32_RN_NEO_4: col = (static_cast<B_32_RN_NEO_4*>(busPtr))->GetPixelColor(pix); break; case I_32_RN_NEO_4: col = (static_cast<B_32_RN_NEO_4*>(busPtr))->GetPixelColor(pix); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: col = (static_cast<B_32_I0_NEO_4*>(busPtr))->GetPixelColor(pix); break; case I_32_I0_NEO_4: col = (static_cast<B_32_I0_NEO_4*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: col = (static_cast<B_32_I1_NEO_4*>(busPtr))->GetPixelColor(pix); break; case I_32_I1_NEO_4: col = (static_cast<B_32_I1_NEO_4*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
case I_32_RN_400_3: col = (static_cast<B_32_RN_400_3*>(busPtr))->GetPixelColor(pix); break; case I_32_RN_400_3: col = (static_cast<B_32_RN_400_3*>(busPtr))->GetPixelColor(pix); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: col = (static_cast<B_32_I0_400_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I0_400_3: col = (static_cast<B_32_I0_400_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: col = (static_cast<B_32_I1_400_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I1_400_3: col = (static_cast<B_32_I1_400_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
case I_32_RN_TM1_4: col = (static_cast<B_32_RN_TM1_4*>(busPtr))->GetPixelColor(pix); break; case I_32_RN_TM1_4: col = (static_cast<B_32_RN_TM1_4*>(busPtr))->GetPixelColor(pix); break;
case I_32_RN_TM2_3: col = (static_cast<B_32_RN_TM2_3*>(busPtr))->GetPixelColor(pix); break; case I_32_RN_TM2_3: col = (static_cast<B_32_RN_TM2_3*>(busPtr))->GetPixelColor(pix); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: col = (static_cast<B_32_I0_TM1_4*>(busPtr))->GetPixelColor(pix); break; case I_32_I0_TM1_4: col = (static_cast<B_32_I0_TM1_4*>(busPtr))->GetPixelColor(pix); break;
case I_32_I0_TM2_3: col = (static_cast<B_32_I0_TM2_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I0_TM2_3: col = (static_cast<B_32_I0_TM2_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: col = (static_cast<B_32_I1_TM1_4*>(busPtr))->GetPixelColor(pix); break; case I_32_I1_TM1_4: col = (static_cast<B_32_I1_TM1_4*>(busPtr))->GetPixelColor(pix); break;
case I_32_I1_TM2_3: col = (static_cast<B_32_I1_TM2_3*>(busPtr))->GetPixelColor(pix); break; case I_32_I1_TM2_3: col = (static_cast<B_32_I1_TM2_3*>(busPtr))->GetPixelColor(pix); break;
#endif #endif
@ -777,33 +789,33 @@ class PolyBus {
#endif #endif
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
case I_32_RN_NEO_3: delete (static_cast<B_32_RN_NEO_3*>(busPtr)); break; case I_32_RN_NEO_3: delete (static_cast<B_32_RN_NEO_3*>(busPtr)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_3: delete (static_cast<B_32_I0_NEO_3*>(busPtr)); break; case I_32_I0_NEO_3: delete (static_cast<B_32_I0_NEO_3*>(busPtr)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_3: delete (static_cast<B_32_I1_NEO_3*>(busPtr)); break; case I_32_I1_NEO_3: delete (static_cast<B_32_I1_NEO_3*>(busPtr)); break;
#endif #endif
case I_32_RN_NEO_4: delete (static_cast<B_32_RN_NEO_4*>(busPtr)); break; case I_32_RN_NEO_4: delete (static_cast<B_32_RN_NEO_4*>(busPtr)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_NEO_4: delete (static_cast<B_32_I0_NEO_4*>(busPtr)); break; case I_32_I0_NEO_4: delete (static_cast<B_32_I0_NEO_4*>(busPtr)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_NEO_4: delete (static_cast<B_32_I1_NEO_4*>(busPtr)); break; case I_32_I1_NEO_4: delete (static_cast<B_32_I1_NEO_4*>(busPtr)); break;
#endif #endif
case I_32_RN_400_3: delete (static_cast<B_32_RN_400_3*>(busPtr)); break; case I_32_RN_400_3: delete (static_cast<B_32_RN_400_3*>(busPtr)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_400_3: delete (static_cast<B_32_I0_400_3*>(busPtr)); break; case I_32_I0_400_3: delete (static_cast<B_32_I0_400_3*>(busPtr)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_400_3: delete (static_cast<B_32_I1_400_3*>(busPtr)); break; case I_32_I1_400_3: delete (static_cast<B_32_I1_400_3*>(busPtr)); break;
#endif #endif
case I_32_RN_TM1_4: delete (static_cast<B_32_RN_TM1_4*>(busPtr)); break; case I_32_RN_TM1_4: delete (static_cast<B_32_RN_TM1_4*>(busPtr)); break;
case I_32_RN_TM2_3: delete (static_cast<B_32_RN_TM2_3*>(busPtr)); break; case I_32_RN_TM2_3: delete (static_cast<B_32_RN_TM2_3*>(busPtr)); break;
#ifndef CONFIG_IDF_TARGET_ESP32C3 #ifndef WLED_NO_I2S0_PIXELBUS
case I_32_I0_TM1_4: delete (static_cast<B_32_I0_TM1_4*>(busPtr)); break; case I_32_I0_TM1_4: delete (static_cast<B_32_I0_TM1_4*>(busPtr)); break;
case I_32_I0_TM2_3: delete (static_cast<B_32_I0_TM2_3*>(busPtr)); break; case I_32_I0_TM2_3: delete (static_cast<B_32_I0_TM2_3*>(busPtr)); break;
#endif #endif
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32C3) #ifndef WLED_NO_I2S1_PIXELBUS
case I_32_I1_TM1_4: delete (static_cast<B_32_I1_TM1_4*>(busPtr)); break; case I_32_I1_TM1_4: delete (static_cast<B_32_I1_TM1_4*>(busPtr)); break;
case I_32_I1_TM2_3: delete (static_cast<B_32_I1_TM2_3*>(busPtr)); break; case I_32_I1_TM2_3: delete (static_cast<B_32_I1_TM2_3*>(busPtr)); break;
#endif #endif

View File

@ -540,8 +540,8 @@ void deserializeConfigFromFS() {
if (!success) { //if file does not exist, try reading from EEPROM if (!success) { //if file does not exist, try reading from EEPROM
#ifdef WLED_ADD_EEPROM_SUPPORT #ifdef WLED_ADD_EEPROM_SUPPORT
deEEPSettings(); deEEPSettings();
#endif
return; return;
#endif
} }
if (!requestJSONBufferLock(1)) return; if (!requestJSONBufferLock(1)) return;
@ -946,6 +946,8 @@ void serializeConfig() {
if (f) serializeJson(doc, f); if (f) serializeJson(doc, f);
f.close(); f.close();
releaseJSONBufferLock(); releaseJSONBufferLock();
doSerializeConfig = false;
} }
//settings in /wsec.json, not accessible via webserver, for passwords and tokens //settings in /wsec.json, not accessible via webserver, for passwords and tokens

View File

@ -25,10 +25,14 @@
#ifdef ESP8266 #ifdef ESP8266
#define WLED_MAX_BUSSES 3 #define WLED_MAX_BUSSES 3
#else #else
#ifdef CONFIG_IDF_TARGET_ESP32S2 #if defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C3)
#define WLED_MAX_BUSSES 5 #define WLED_MAX_BUSSES 5
#else #else
#define WLED_MAX_BUSSES 10 #if defined(CONFIG_IDF_TARGET_ESP32S3)
#define WLED_MAX_BUSSES 8
#else
#define WLED_MAX_BUSSES 10
#endif
#endif #endif
#endif #endif
#endif #endif
@ -279,11 +283,15 @@
#endif #endif
#ifndef MAX_LED_MEMORY #ifndef MAX_LED_MEMORY
#ifdef ESP8266 #ifdef ESP8266
#define MAX_LED_MEMORY 4000 #define MAX_LED_MEMORY 4000
#else #else
#define MAX_LED_MEMORY 64000 #ifdef ARDUINO_ARCH_ESP32S2
#endif #define MAX_LED_MEMORY 32000
#else
#define MAX_LED_MEMORY 64000
#endif
#endif
#endif #endif
#ifndef MAX_LEDS_PER_BUS #ifndef MAX_LEDS_PER_BUS
@ -333,7 +341,8 @@
#define JSON_BUFFER_SIZE 24576 #define JSON_BUFFER_SIZE 24576
#endif #endif
#define MIN_HEAP_SIZE (MAX_LED_MEMORY+2048) //#define MIN_HEAP_SIZE (MAX_LED_MEMORY+2048)
#define MIN_HEAP_SIZE (8192)
// Maximum size of node map (list of other WLED instances) // Maximum size of node map (list of other WLED instances)
#ifdef ESP8266 #ifdef ESP8266

View File

@ -1194,7 +1194,7 @@ TD .checkmark, TD .radiomark {
/*filter: brightness(1);*/ /*filter: brightness(1);*/
font-size: 19px; font-size: 19px;
border-radius: 21px; border-radius: 21px;
min-width: 280px; /*min-width: 264px;*/
} }
.seg { .seg {

View File

@ -399,7 +399,7 @@ function presetError(empty)
if (bckstr.length > 10) hasBackup = true; if (bckstr.length > 10) hasBackup = true;
} catch (e) {} } catch (e) {}
var cn = `<div class="pres c" ${empty?'style="padding:8px 0;margin-top: 15px;"':'onclick="loadPresets()" style="cursor:pointer;padding:8px 0;"'}>`; var cn = `<div class="pres c" ${empty?'style="padding:8px;margin-top: 16px;"':'onclick="loadPresets()" style="cursor:pointer;padding:8px;margin-top: 16px;"'}>`;
if (empty) if (empty)
cn += `You have no presets yet!`; cn += `You have no presets yet!`;
else else

View File

@ -23,7 +23,12 @@
// success event // success event
scE.addEventListener("load", () => { scE.addEventListener("load", () => {
//console.log("File loaded"); //console.log("File loaded");
d.um_p = [];
d.rsvd = [];
d.ro_pins = [];
d.max_gpio = 39;
GetV();checkSi();setABL(); GetV();checkSi();setABL();
if (d.um_p[0]==-1) d.um_p.shift();
}); });
// error event // error event
scE.addEventListener("error", (ev) => { scE.addEventListener("error", (ev) => {
@ -57,9 +62,11 @@
//check for pin conflicts //check for pin conflicts
if (nm=="L0" || nm=="L1" || nm=="L2" || nm=="L3" || nm=="L4" || nm=="RL" || nm=="BT" || nm=="IR") if (nm=="L0" || nm=="L1" || nm=="L2" || nm=="L3" || nm=="L4" || nm=="RL" || nm=="BT" || nm=="IR")
if (LCs[i].value!="" && LCs[i].value!="-1") { if (LCs[i].value!="" && LCs[i].value!="-1") {
if (d.um_p && d.um_p.some((e)=>e==parseInt(LCs[i].value,10))) {alert(`Sorry, pins ${JSON.stringify(d.um_p)} can't be used.`);LCs[i].value="";LCs[i].focus();return false;} var p = []; // used pin array
else if (LCs[i].value > 5 && LCs[i].value < 12) {alert("Sorry, pins 6-11 can not be used.");LCs[i].value="";LCs[i].focus();return false;} for (k=0;k<d.rsvd.length;k++) p.push(d.rsvd[k]); // fill with reservations
else if (!(nm == "IR" || nm=="BT") && LCs[i].value > 33) {alert("Sorry, pins >33 are input only.");LCs[i].value="";LCs[i].focus();return false;} for (k=0;k<d.um_p.length;k++) p.push(d.um_p[k]); // fill with usermod pins
if (p.some((e)=>e==parseInt(LCs[i].value,10))) {alert(`Sorry, pins ${JSON.stringify(p)} can't be used.`);LCs[i].value="";LCs[i].focus();return false;}
else if (!(nm == "IR" || nm=="BT") && d.ro_pins.some((e)=>e==parseInt(LCs[i].value,10))) {alert(`Sorry, pins ${JSON.stringify(d.ro_gpio)} are input only.`);LCs[i].value="";LCs[i].focus();return false;}
for (j=i+1; j<LCs.length; j++) for (j=i+1; j<LCs.length; j++)
{ {
var n2 = LCs[j].name.substring(0,2); var n2 = LCs[j].name.substring(0,2);
@ -230,7 +237,7 @@
LCs[i].style.color="#fff"; LCs[i].style.color="#fff";
continue; // do not check conflicts continue; // do not check conflicts
} else { } else {
LCs[i].max = 33; LCs[i].max = d.max_gpio;
LCs[i].min = -1; LCs[i].min = -1;
} }
} }
@ -238,7 +245,8 @@
if (nm=="L0" || nm=="L1" || nm=="L2" || nm=="L3" || nm=="L4" || nm=="RL" || nm=="BT" || nm=="IR") if (nm=="L0" || nm=="L1" || nm=="L2" || nm=="L3" || nm=="L4" || nm=="RL" || nm=="BT" || nm=="IR")
if (LCs[i].value!="" && LCs[i].value!="-1") { if (LCs[i].value!="" && LCs[i].value!="-1") {
var p = []; // used pin array var p = []; // used pin array
if (d.um_p && Array.isArray(d.um_p)) for (k=0;k<d.um_p.length;k++) p.push(d.um_p[k]); // fill with reservations for (k=0;k<d.rsvd.length;k++) p.push(d.rsvd[k]); // fill with reservations
for (k=0;k<d.um_p.length;k++) p.push(d.um_p[k]); // fill with usermod pins
for (j=0; j<LCs.length; j++) { for (j=0; j<LCs.length; j++) {
if (i==j) continue; if (i==j) continue;
var n2 = LCs[j].name.substring(0,2); var n2 = LCs[j].name.substring(0,2);
@ -252,8 +260,13 @@
} }
} }
// now check for conflicts // now check for conflicts
if (p.some((e)=>e==parseInt(LCs[i].value,10))) LCs[i].style.color="red"; else LCs[i].style.color=parseInt(LCs[i].value,10)>33?"orange":"#fff"; if (p.some((e)=>e==parseInt(LCs[i].value,10))) LCs[i].style.color="red"; else LCs[i].style.color=d.ro_gpio.some((e)=>e==parseInt(LCs[i].value,10))?"orange":"#fff";
} }
// check buttons, IR & relay
if (nm=="IR" || nm=="BT" || nm=="RL") {
LCs[i].max = d.max_gpio;
LCs[i].min = -1;
}
} }
// update total led count // update total led count
gId("lc").textContent = sLC; gId("lc").textContent = sLC;
@ -268,25 +281,25 @@
gId('wreason').innerHTML = (bquot > 80) ? "80% of max. LED memory" +(bquot>100 ? ` (<b>ERROR: Using over ${maxM}B!</b>)` : "") : "800 LEDs per output"; gId('wreason').innerHTML = (bquot > 80) ? "80% of max. LED memory" +(bquot>100 ? ` (<b>ERROR: Using over ${maxM}B!</b>)` : "") : "800 LEDs per output";
// calculate power // calculate power
var val = Math.ceil((100 + sPC * laprev)/500)/2; var val = Math.ceil((100 + sPC * laprev)/500)/2;
val = (val > 5) ? Math.ceil(val) : val; val = (val > 5) ? Math.ceil(val) : val;
var s = ""; var s = "";
var is12V = (d.Sf.LAsel.value == 30); var is12V = (d.Sf.LAsel.value == 30);
var isWS2815 = (d.Sf.LAsel.value == 255); var isWS2815 = (d.Sf.LAsel.value == 255);
if (val < 1.02 && !is12V && !isWS2815) if (val < 1.02 && !is12V && !isWS2815)
{ {
s = "ESP 5V pin with 1A USB supply"; s = "ESP 5V pin with 1A USB supply";
} else } else
{ {
s += is12V ? "12V ": isWS2815 ? "WS2815 12V " : "5V "; s += is12V ? "12V ": isWS2815 ? "WS2815 12V " : "5V ";
s += val; s += val;
s += "A supply connected to LEDs"; s += "A supply connected to LEDs";
} }
var val2 = Math.ceil((100 + sPC * laprev)/1500)/2; var val2 = Math.ceil((100 + sPC * laprev)/1500)/2;
val2 = (val2 > 5) ? Math.ceil(val2) : val2; val2 = (val2 > 5) ? Math.ceil(val2) : val2;
var s2 = "(for most effects, ~"; var s2 = "(for most effects, ~";
s2 += val2; s2 += val2;
s2 += "A is enough)<br>"; s2 += "A is enough)<br>";
gId('psu').innerHTML = s; gId('psu').innerHTML = s;
gId('psu2').innerHTML = isWS2815 ? "" : s2; gId('psu2').innerHTML = isWS2815 ? "" : s2;
gId("json").style.display = d.Sf.IT.value==8 ? "" : "none"; gId("json").style.display = d.Sf.IT.value==8 ? "" : "none";
} }
@ -348,11 +361,11 @@ ${i+1}:
<span id="psd${i}">Start:</span> <input type="number" name="LS${i}" id="ls${i}" class="l starts" min="0" max="8191" value="${lastEnd(i)}" oninput="startsDirty[${i}]=true;UI();" required />&nbsp; <span id="psd${i}">Start:</span> <input type="number" name="LS${i}" id="ls${i}" class="l starts" min="0" max="8191" value="${lastEnd(i)}" oninput="startsDirty[${i}]=true;UI();" required />&nbsp;
<div id="dig${i}c" style="display:inline">Length: <input type="number" name="LC${i}" class="l" min="1" max="${maxPB}" value="1" required oninput="UI()" /></div><br> <div id="dig${i}c" style="display:inline">Length: <input type="number" name="LC${i}" class="l" min="1" max="${maxPB}" value="1" required oninput="UI()" /></div><br>
</div> </div>
<span id="p0d${i}">GPIO:</span> <input type="number" name="L0${i}" min="0" max="33" required class="s" onchange="UI()"/> <span id="p0d${i}">GPIO:</span> <input type="number" name="L0${i}" min="0" max="48" required class="s" onchange="UI()"/>
<span id="p1d${i}"></span><input type="number" name="L1${i}" min="0" max="33" class="s" onchange="UI()"/> <span id="p1d${i}"></span><input type="number" name="L1${i}" min="0" max="48" class="s" onchange="UI()"/>
<span id="p2d${i}"></span><input type="number" name="L2${i}" min="0" max="33" class="s" onchange="UI()"/> <span id="p2d${i}"></span><input type="number" name="L2${i}" min="0" max="48" class="s" onchange="UI()"/>
<span id="p3d${i}"></span><input type="number" name="L3${i}" min="0" max="33" class="s" onchange="UI()"/> <span id="p3d${i}"></span><input type="number" name="L3${i}" min="0" max="48" class="s" onchange="UI()"/>
<span id="p4d${i}"></span><input type="number" name="L4${i}" min="0" max="33" class="s" onchange="UI()"/> <span id="p4d${i}"></span><input type="number" name="L4${i}" min="0" max="48" class="s" onchange="UI()"/>
<div id="dig${i}r" style="display:inline"><br><span id="rev${i}">Reversed</span>: <input type="checkbox" name="CV${i}"></div> <div id="dig${i}r" style="display:inline"><br><span id="rev${i}">Reversed</span>: <input type="checkbox" name="CV${i}"></div>
<div id="dig${i}s" style="display:inline"><br>Skip first LEDs: <input type="number" name="SL${i}" min="0" max="255" value="0" oninput="UI()"></div> <div id="dig${i}s" style="display:inline"><br>Skip first LEDs: <input type="number" name="SL${i}" min="0" max="255" value="0" oninput="UI()"></div>
<div id="dig${i}f" style="display:inline"><br>Off Refresh: <input id="rf${i}" type="checkbox" name="RF${i}"></div> <div id="dig${i}f" style="display:inline"><br>Off Refresh: <input id="rf${i}" type="checkbox" name="RF${i}"></div>
@ -422,7 +435,7 @@ Length: <input type="number" name="XC${i}" id="xc${i}" class="l" min="1" max="65
var c = gId("btns").innerHTML; var c = gId("btns").innerHTML;
var bt = "BT" + String.fromCharCode((i<10?48:55)+i); var bt = "BT" + String.fromCharCode((i<10?48:55)+i);
var be = "BE" + String.fromCharCode((i<10?48:55)+i); var be = "BE" + String.fromCharCode((i<10?48:55)+i);
c += `Button ${i} GPIO: <input type="number" min="-1" max="40" name="${bt}" onchange="UI()" class="xs" value="${p}">`; c += `Button ${i} GPIO: <input type="number" min="-1" max="48" name="${bt}" onchange="UI()" class="xs" value="${p}">`;
c += `&nbsp;<select name="${be}">` c += `&nbsp;<select name="${be}">`
c += `<option value="0" ${t==0?"selected":""}>Disabled</option>`; c += `<option value="0" ${t==0?"selected":""}>Disabled</option>`;
c += `<option value="2" ${t==2?"selected":""}>Pushbutton</option>`; c += `<option value="2" ${t==2?"selected":""}>Pushbutton</option>`;
@ -605,7 +618,7 @@ Length: <input type="number" name="XC${i}" id="xc${i}" class="l" min="1" max="65
<hr style="width:260px"> <hr style="width:260px">
<div id="btns"></div> <div id="btns"></div>
Touch threshold: <input type="number" class="s" min="0" max="100" name="TT" required><br> Touch threshold: <input type="number" class="s" min="0" max="100" name="TT" required><br>
IR GPIO: <input type="number" min="-1" max="40" name="IR" onchange="UI()" class="xs"><select name="IT" onchange="UI()"> IR GPIO: <input type="number" min="-1" max="48" name="IR" onchange="UI()" class="xs"><select name="IT" onchange="UI()">
<option value=0>Remote disabled</option> <option value=0>Remote disabled</option>
<option value=1>24-key RGB</option> <option value=1>24-key RGB</option>
<option value=2>24-key with CT</option> <option value=2>24-key with CT</option>
@ -619,7 +632,7 @@ Length: <input type="number" name="XC${i}" id="xc${i}" class="l" min="1" max="65
Apply IR change to main segment only: <input type="checkbox" name="MSO"><br> Apply IR change to main segment only: <input type="checkbox" name="MSO"><br>
<div id="json" style="display:none;">JSON file: <input type="file" name="data" accept=".json"><button type="button" class="sml" onclick="uploadFile('/ir.json')">Upload</button><br></div> <div id="json" style="display:none;">JSON file: <input type="file" name="data" accept=".json"><button type="button" class="sml" onclick="uploadFile('/ir.json')">Upload</button><br></div>
<a href="https://kno.wled.ge/interfaces/infrared/" target="_blank">IR info</a><br> <a href="https://kno.wled.ge/interfaces/infrared/" target="_blank">IR info</a><br>
Relay GPIO: <input type="number" min="-1" max="33" name="RL" onchange="UI()" class="xs"> Invert <input type="checkbox" name="RM"><span style="cursor: pointer;" onclick="off('RL')">&nbsp;&#x2715;</span><br> Relay GPIO: <input type="number" min="-1" max="48" name="RL" onchange="UI()" class="xs"> Invert <input type="checkbox" name="RM"><span style="cursor: pointer;" onclick="off('RL')">&nbsp;&#x2715;</span><br>
<hr style="width:260px"> <hr style="width:260px">
<h3>Defaults</h3> <h3>Defaults</h3>
Turn LEDs on after power up/reset: <input type="checkbox" name="BO"><br> Turn LEDs on after power up/reset: <input type="checkbox" name="BO"><br>

View File

@ -1,22 +1,21 @@
<!DOCTYPE html> <!DOCTYPE html>
<html> <html>
<head lang="en"> <head lang="en">
<meta charset="utf-8"> <meta charset="utf-8">
<meta name="viewport" content="width=500"> <meta name="viewport" content="width=500">
<meta content="width=device-width, initial-scale=1.0, maximum-scale=1.0, user-scalable=no" name="viewport"/> <meta content="width=device-width, initial-scale=1.0, maximum-scale=1.0, user-scalable=no" name="viewport"/>
<title>Usermod Settings</title> <title>Usermod Settings</title>
<script> <script>
var d = document; var d = document;
var umCfg = {}; var umCfg = {};
var pins = [6,7,8,9,10,11]; var pins = [], pinO = [], owner;
var pinO = ["rsvd","rsvd","rsvd","rsvd","rsvd","rsvd"], owner; var loc = false, locip;
var loc = false, locip; var urows;
var urows; var numM = 0;
var numM = 0; function gId(s) { return d.getElementById(s); }
function gId(s) { return d.getElementById(s); } function isO(i) { return (i && typeof i === 'object' && !Array.isArray(i)); }
function isO(i) { return (i && typeof i === 'object' && !Array.isArray(i)); } function H() { window.open("https://github.com/Aircoookie/WLED/wiki/Settings#usermod-settings"); }
function H() { window.open("https://github.com/Aircoookie/WLED/wiki/Settings#usermod-settings"); } function B() { window.open("/settings","_self"); }
function B() { window.open("/settings","_self"); }
// https://www.educative.io/edpresso/how-to-dynamically-load-a-js-file-in-javascript // https://www.educative.io/edpresso/how-to-dynamically-load-a-js-file-in-javascript
function loadJS(FILE_URL, async = true) { function loadJS(FILE_URL, async = true) {
let scE = d.createElement("script"); let scE = d.createElement("script");
@ -27,7 +26,18 @@
// success event // success event
scE.addEventListener("load", () => { scE.addEventListener("load", () => {
//console.log("File loaded"); //console.log("File loaded");
d.um_p = [];
d.rsvd = [];
d.ro_pins = [];
d.max_gpio = 39;
GetV(); GetV();
for (let k=0; k<d.rsvd.length; k++) { pins.push(d.rsvd[k]); pinO.push("rsvd"); }
if (d.um_p[0]==-1) d.um_p.shift();
d.Sf.SDA.max = d.max_gpio;
d.Sf.SCL.max = d.max_gpio;
d.Sf.MOSI.max = d.max_gpio;
d.Sf.SCLK.max = d.max_gpio;
d.Sf.MISO.max = d.max_gpio;
}); });
// error event // error event
scE.addEventListener("error", (ev) => { scE.addEventListener("error", (ev) => {
@ -35,182 +45,182 @@
alert("Loading of configuration script failed.\nIncomplete page data!"); alert("Loading of configuration script failed.\nIncomplete page data!");
}); });
} }
function S() { function S() {
if (window.location.protocol == "file:") { if (window.location.protocol == "file:") {
loc = true; loc = true;
locip = localStorage.getItem('locIp'); locip = localStorage.getItem('locIp');
if (!locip) { if (!locip) {
locip = prompt("File Mode. Please enter WLED IP!"); locip = prompt("File Mode. Please enter WLED IP!");
localStorage.setItem('locIp', locip); localStorage.setItem('locIp', locip);
} }
} }
ldS(); ldS();
if (!numM) gId("um").innerHTML = "No Usermods installed."; if (!numM) gId("um").innerHTML = "No Usermods installed.";
} }
// https://stackoverflow.com/questions/3885817/how-do-i-check-that-a-number-is-float-or-integer // https://stackoverflow.com/questions/3885817/how-do-i-check-that-a-number-is-float-or-integer
function isF(n) { return n === +n && n !== (n|0); } function isF(n) { return n === +n && n !== (n|0); }
function isI(n) { return n === +n && n === (n|0); } function isI(n) { return n === +n && n === (n|0); }
function check(o,k) { // input object, pin owner key function check(o,k) { // input object, pin owner key
var n = o.name.replace("[]","").substr(-3); var n = o.name.replace("[]","").substr(-3);
if (o.type=="number" && n.substr(0,3)=="pin") { if (o.type=="number" && n.substr(0,3)=="pin") {
for (var i=0; i<pins.length; i++) { for (var i=0; i<pins.length; i++) {
if (k==pinO[i]) continue; if (k==pinO[i]) continue;
if (o.value==pins[i] && pinO[i]==="if") { o.style.color="lime"; break; } if (o.value==pins[i] && pinO[i]==="if") { o.style.color="lime"; break; }
if (o.value==pins[i] || o.value<-1 || o.value>39) { o.style.color="red"; break; } else o.style.color=o.value>33?"orange":"#fff"; if (o.value==pins[i] || o.value<-1 || o.value>d.max_gpio) { o.style.color="red"; break; } else o.style.color=d.ro_gpio.some((e)=>e==parseInt(o.value,10))?"orange":"#fff";
} }
} else { } else {
switch (o.name) { switch (o.name) {
case "SDA": break; case "SDA": break;
case "SCL": break; case "SCL": break;
case "MOSI": break; case "MOSI": break;
case "SCLK": break; case "SCLK": break;
case "CS": break; case "MISO": break;
default: return; default: return;
} }
for (var i=0; i<pins.length; i++) { for (var i=0; i<pins.length; i++) {
if (k==pinO[i]) continue; //if (k==pinO[i]) continue; // same owner
if (o.value==pins[i] && pinO[i]==="if") { o.style.color="lime"; break; } if (o.value==pins[i] && pinO[i]==="if") { o.style.color="tomato"; break; }
if (o.value==pins[i] || o.value<-1 || o.value>39) { o.style.color="red"; break; } else o.style.color=o.value>33?"orange":"#fff"; if (o.value==pins[i] || o.value<-1 || o.value>d.max_gpio) { o.style.color="red"; break; } else o.style.color=d.ro_gpio.some((e)=>e==parseInt(o.value,10))?"orange":"#fff";
} }
} }
} }
function getPins(o) { function getPins(o) {
if (isO(o)) { if (isO(o)) {
for (const [k,v] of Object.entries(o)) { for (const [k,v] of Object.entries(o)) {
if (isO(v)) { if (isO(v)) {
owner = k; owner = k;
getPins(v); getPins(v);
continue; continue;
} }
if (k.replace("[]","").substr(-3)=="pin") { if (k.replace("[]","").substr(-3)=="pin") {
if (Array.isArray(v)) { if (Array.isArray(v)) {
for (var i=0; i<v.length; i++) if (v[i]>=0) { pins.push(v[i]); pinO.push(owner); } for (var i=0; i<v.length; i++) if (v[i]>=0) { pins.push(v[i]); pinO.push(owner); }
} else { } else {
if (v>=0) { pins.push(v); pinO.push(owner); } if (v>=0) { pins.push(v); pinO.push(owner); }
} }
} else if (Array.isArray(v)) { } else if (Array.isArray(v)) {
for (var i=0; i<v.length; i++) getPins(v[i]); for (var i=0; i<v.length; i++) getPins(v[i]);
} }
} }
} }
} }
function addField(k,f,o,a=false) { //key, field, (sub)object, isArray function addField(k,f,o,a=false) { //key, field, (sub)object, isArray
if (isO(o)) { if (isO(o)) {
urows += '<hr style="width:260px">'; urows += '<hr style="width:260px">';
for (const [s,v] of Object.entries(o)) { for (const [s,v] of Object.entries(o)) {
// possibility to nest objects (only 1 level) // possibility to nest objects (only 1 level)
if (f!=='unknown' && !k.includes(":")) addField(k+":"+f,s,v); if (f!=='unknown' && !k.includes(":")) addField(k+":"+f,s,v);
else addField(k,s,v); else addField(k,s,v);
} }
} else if (Array.isArray(o)) { } else if (Array.isArray(o)) {
for (var j=0; j<o.length; j++) { for (var j=0; j<o.length; j++) {
addField(k,f,o[j],true); addField(k,f,o[j],true);
} }
} else { } else {
var c, t = typeof o; var c, t = typeof o;
switch (t) { switch (t) {
case "boolean": case "boolean":
t = "checkbox"; c = 'value="true"' + (o ? ' checked' : ''); t = "checkbox"; c = 'value="true"' + (o ? ' checked' : '');
break; break;
case "number": case "number":
c = `value="${o}"`; c = `value="${o}"`;
if (f.substr(-3)==="pin") { if (f.substr(-3)==="pin") {
c += ' max="39" min="-1" class="s"'; c += ` max="${d.max_gpio}" min="-1" class="s"`;
t = "int"; t = "int";
} else { } else {
c += ' step="any" class="xxl"'; c += ' step="any" class="xxl"';
} }
break; break;
default: default:
t = "text"; c = `value="${o}" style="width:250px;"`; t = "text"; c = `value="${o}" style="width:250px;"`;
break; break;
} }
if (k.includes(":")) urows += k.substr(k.indexOf(":")+1); if (k.includes(":")) urows += k.substr(k.indexOf(":")+1);
urows += ` ${f}: `; urows += ` ${f}: `;
// https://stackoverflow.com/questions/11657123/posting-both-checked-and-unchecked-checkboxes // https://stackoverflow.com/questions/11657123/posting-both-checked-and-unchecked-checkboxes
if (t=="checkbox") urows += `<input type="hidden" name="${k}:${f}${a?"[]":""}" value="false">`; if (t=="checkbox") urows += `<input type="hidden" name="${k}:${f}${a?"[]":""}" value="false">`;
else if (!a) urows += `<input type="hidden" name="${k}:${f}${a?"[]":""}" value="${t}">`; else if (!a) urows += `<input type="hidden" name="${k}:${f}${a?"[]":""}" value="${t}">`;
urows += `<input type="${t==="int"?"number":t}" name="${k}:${f}${a?"[]":""}" ${c} oninput="check(this,'${k.substr(k.indexOf(":")+1)}')"><br>`; urows += `<input type="${t==="int"?"number":t}" name="${k}:${f}${a?"[]":""}" ${c} oninput="check(this,'${k.substr(k.indexOf(":")+1)}')"><br>`;
} }
} }
// https://stackoverflow.com/questions/39729741/javascript-change-input-text-to-select-option // https://stackoverflow.com/questions/39729741/javascript-change-input-text-to-select-option
function addDropdown(um,fld) { function addDropdown(um,fld) {
let sel = d.createElement('select'); let sel = d.createElement('select');
let arr = d.getElementsByName(um+":"+fld); let arr = d.getElementsByName(um+":"+fld);
let inp = arr[1]; // assume 1st field to be hidden (type) let inp = arr[1]; // assume 1st field to be hidden (type)
if (inp && inp.tagName === "INPUT" && (inp.type === "text" || inp.type === "number")) { // may also use nodeName if (inp && inp.tagName === "INPUT" && (inp.type === "text" || inp.type === "number")) { // may also use nodeName
let v = inp.value; let v = inp.value;
let n = inp.name; let n = inp.name;
// copy the existing input element's attributes to the new select element // copy the existing input element's attributes to the new select element
for (var i = 0; i < inp.attributes.length; ++ i) { for (var i = 0; i < inp.attributes.length; ++ i) {
var att = inp.attributes[i]; var att = inp.attributes[i];
// type and value don't apply, so skip them // type and value don't apply, so skip them
// ** you might also want to skip style, or others -- modify as needed ** // ** you might also want to skip style, or others -- modify as needed **
if (att.name != 'type' && att.name != 'value' && att.name != 'class' && att.name != 'style') { if (att.name != 'type' && att.name != 'value' && att.name != 'class' && att.name != 'style') {
sel.setAttribute(att.name, att.value); sel.setAttribute(att.name, att.value);
} }
} }
sel.setAttribute("data-val", v); sel.setAttribute("data-val", v);
// finally, replace the old input element with the new select element // finally, replace the old input element with the new select element
inp.parentElement.replaceChild(sel, inp); inp.parentElement.replaceChild(sel, inp);
return sel; return sel;
} }
return null; return null;
} }
function addOption(sel,txt,val) { function addOption(sel,txt,val) {
if (sel===null) return; // select object missing if (sel===null) return; // select object missing
let opt = d.createElement("option"); let opt = d.createElement("option");
opt.value = val; opt.value = val;
opt.text = txt; opt.text = txt;
sel.appendChild(opt); sel.appendChild(opt);
for (let i=0; i<sel.childNodes.length; i++) { for (let i=0; i<sel.childNodes.length; i++) {
let c = sel.childNodes[i]; let c = sel.childNodes[i];
if (c.value == sel.dataset.val) sel.selectedIndex = i; if (c.value == sel.dataset.val) sel.selectedIndex = i;
} }
} }
// https://stackoverflow.com/questions/26440494/insert-text-after-this-input-element-with-javascript // https://stackoverflow.com/questions/26440494/insert-text-after-this-input-element-with-javascript
function addInfo(name,el,txt) { function addInfo(name,el,txt) {
let obj = d.getElementsByName(name); let obj = d.getElementsByName(name);
if (!obj.length) return; if (!obj.length) return;
if (typeof el === "string" && obj[0]) obj[0].placeholder = el; if (typeof el === "string" && obj[0]) obj[0].placeholder = el;
else if (obj[el]) obj[el].insertAdjacentHTML('afterend', '&nbsp;'+txt); else if (obj[el]) obj[el].insertAdjacentHTML('afterend', '&nbsp;'+txt);
} }
// load settings and insert values into DOM // load settings and insert values into DOM
function ldS() { function ldS() {
var url = (loc?`http://${locip}`:'') + '/cfg.json'; var url = (loc?`http://${locip}`:'') + '/cfg.json';
fetch(url, { fetch(url, {
method: 'get' method: 'get'
}) })
.then(res => { .then(res => {
if (!res.ok) gId('lserr').style.display = "inline"; if (!res.ok) gId('lserr').style.display = "inline";
return res.json(); return res.json();
}) })
.then(json => { .then(json => {
umCfg = json.um; umCfg = json.um;
getPins(json); getPins(json);
urows=""; urows="";
if (isO(umCfg)) { if (isO(umCfg)) {
for (const [k,o] of Object.entries(umCfg)) { for (const [k,o] of Object.entries(umCfg)) {
urows += `<hr><h3>${k}</h3>`; urows += `<hr><h3>${k}</h3>`;
addField(k,'unknown',o); addField(k,'unknown',o);
} }
} }
if (urows==="") urows = "Usermods configuration not found.<br>Press <i>Save</i> to initialize defaults."; if (urows==="") urows = "Usermods configuration not found.<br>Press <i>Save</i> to initialize defaults.";
gId("um").innerHTML = urows; gId("um").innerHTML = urows;
var url = (loc?`http://${locip}`:'') + '/settings/s.js?p=8'; var url = (loc?`http://${locip}`:'') + '/settings/s.js?p=8';
loadJS(url, false); // If we set async false, file is loaded and executed, then next statement is processed loadJS(url, false); // If we set async false, file is loaded and executed, then next statement is processed
}) })
.catch((error)=>{ .catch((error)=>{
gId('lserr').style.display = "inline"; gId('lserr').style.display = "inline";
console.log(error); console.log(error);
}); });
} }
function svS(e) { function svS(e) {
e.preventDefault(); e.preventDefault();
if (d.Sf.checkValidity()) d.Sf.submit(); //https://stackoverflow.com/q/37323914 if (d.Sf.checkValidity()) d.Sf.submit(); //https://stackoverflow.com/q/37323914
} }
</script> </script>
<style>@import url("style.css");</style> <style>@import url("style.css");</style>
</head> </head>
<body onload="S()"> <body onload="S()">
@ -222,17 +232,17 @@
<span id="lserr" style="color:red; display:none">&#9888; Could not load configuration.</span><hr> <span id="lserr" style="color:red; display:none">&#9888; Could not load configuration.</span><hr>
</div> </div>
<h2>Usermod Setup</h2> <h2>Usermod Setup</h2>
Global I<sup>2</sup>C GPIOs (HW)<br> Global I<sup>2</sup>C GPIOs (HW)<br>
<i style="color: orange;">(only changable on ESP32, change requires reboot!)</i><br> <i style="color: orange;">(only changable on ESP32, change requires reboot!)</i><br>
SDA:<input type="number" min="-1" max="33" name="SDA" onchange="check(this,'if')" class="s" placeholder="SDA"> SDA:<input type="number" min="-1" max="48" name="SDA" onchange="check(this,'if')" class="s" placeholder="SDA">
SCL:<input type="number" min="-1" max="33" name="SCL" onchange="check(this,'if')" class="s" placeholder="SCL"> SCL:<input type="number" min="-1" max="48" name="SCL" onchange="check(this,'if')" class="s" placeholder="SCL">
<hr style="width:260px"> <hr style="width:260px">
Global SPI GPIOs (HW)<br> Global SPI GPIOs (HW)<br>
<i style="color: orange;">(only changable on ESP32, change requires reboot!)</i><br> <i style="color: orange;">(only changable on ESP32, change requires reboot!)</i><br>
MOSI:<input type="number" min="-1" max="33" name="MOSI" onchange="check(this,'if')" class="s" placeholder="MOSI"> MOSI:<input type="number" min="-1" max="48" name="MOSI" onchange="check(this,'if')" class="s" placeholder="MOSI">
MISO:<input type="number" min="-1" max="33" name="MISO" onchange="check(this,'if')" class="s" placeholder="MISO"> MISO:<input type="number" min="-1" max="48" name="MISO" onchange="check(this,'if')" class="s" placeholder="MISO">
SCLK:<input type="number" min="-1" max="33" name="SCLK" onchange="check(this,'if')" class="s" placeholder="SCLK"> SCLK:<input type="number" min="-1" max="48" name="SCLK" onchange="check(this,'if')" class="s" placeholder="SCLK">
<div id="um">Loading settings...</div> <div id="um">Loading settings...</div>
<hr><button type="button" onclick="B()">Back</button><button type="submit">Save</button> <hr><button type="button" onclick="B()">Back</button><button type="submit">Save</button>
</form> </form>
</body> </body>

View File

@ -191,8 +191,8 @@ int16_t loadPlaylist(JsonObject playlistObject, byte presetId = 0);
void handlePlaylist(); void handlePlaylist();
//presets.cpp //presets.cpp
void handlePresets(bool force = false); void handlePresets();
bool applyPreset(byte index, byte callMode = CALL_MODE_DIRECT_CHANGE, bool fromJson = false); bool applyPreset(byte index, byte callMode = CALL_MODE_DIRECT_CHANGE);
inline bool applyTemporaryPreset() {return applyPreset(255);}; inline bool applyTemporaryPreset() {return applyPreset(255);};
void savePreset(byte index, const char* pname = nullptr, JsonObject saveobj = JsonObject()); void savePreset(byte index, const char* pname = nullptr, JsonObject saveobj = JsonObject());
inline void saveTemporaryPreset() {savePreset(255);}; inline void saveTemporaryPreset() {savePreset(255);};

File diff suppressed because it is too large Load Diff

File diff suppressed because it is too large Load Diff

View File

@ -728,7 +728,7 @@ void handleIR()
{ {
if (results.value != 0) // only print results if anything is received ( != 0 ) if (results.value != 0) // only print results if anything is received ( != 0 )
{ {
if (!pinManager.isPinAllocated(1) || pinManager.getPinOwner(1) == PinOwner::DebugOut) //GPIO 1 - Serial TX pin if (!pinManager.isPinAllocated(hardwareTX) || pinManager.getPinOwner(hardwareTX) == PinOwner::DebugOut) // Serial TX pin (GPIO 1 on ESP32 and ESP8266)
Serial.printf_P(PSTR("IR recv: 0x%lX\n"), (unsigned long)results.value); Serial.printf_P(PSTR("IR recv: 0x%lX\n"), (unsigned long)results.value);
} }
decodeIR(results.value); decodeIR(results.value);

View File

@ -680,7 +680,11 @@ void serializeInfo(JsonObject root)
wifi_info[F("txPower")] = (int) WiFi.getTxPower(); wifi_info[F("txPower")] = (int) WiFi.getTxPower();
wifi_info[F("sleep")] = (bool) WiFi.getSleep(); wifi_info[F("sleep")] = (bool) WiFi.getSleep();
#endif #endif
root[F("arch")] = "esp32"; #if !defined(CONFIG_IDF_TARGET_ESP32C2) && !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32S3)
root[F("arch")] = "esp32";
#else
root[F("arch")] = ESP.getChipModel();
#endif
root[F("core")] = ESP.getSdkVersion(); root[F("core")] = ESP.getSdkVersion();
//root[F("maxalloc")] = ESP.getMaxAllocHeap(); //root[F("maxalloc")] = ESP.getMaxAllocHeap();
#ifdef WLED_DEBUG #ifdef WLED_DEBUG

View File

@ -160,7 +160,23 @@ bool PinManagerClass::allocateMultiplePins(const managed_pin_type * mptArray, by
bool PinManagerClass::allocatePin(byte gpio, bool output, PinOwner tag) bool PinManagerClass::allocatePin(byte gpio, bool output, PinOwner tag)
{ {
// HW I2C & SPI pins have to be allocated using allocateMultiplePins variant since there is always SCL/SDA pair // HW I2C & SPI pins have to be allocated using allocateMultiplePins variant since there is always SCL/SDA pair
if (!isPinOk(gpio, output) || tag==PinOwner::HW_I2C || tag==PinOwner::HW_SPI) return false; if (!isPinOk(gpio, output) || tag==PinOwner::HW_I2C || tag==PinOwner::HW_SPI) {
#ifdef WLED_DEBUG
if (gpio < 255) { // 255 (-1) is the "not defined GPIO"
if (!isPinOk(gpio, output)) {
DEBUG_PRINT(F("PIN ALLOC: FAIL for owner "));
DebugPrintOwnerTag(tag);
DEBUG_PRINT(F(": GPIO ")); DEBUG_PRINT(gpio);
if (output) DEBUG_PRINTLN(F(" cannot be used for i/o on this MCU."));
else DEBUG_PRINTLN(F(" cannot be used as input on this MCU."));
} else {
DEBUG_PRINT(F("PIN ALLOC: FAIL: GPIO ")); DEBUG_PRINT(gpio);
DEBUG_PRINTLN(F(" - HW I2C & SPI pins have to be allocated using allocateMultiplePins()"));
}
}
#endif
return false;
}
if (isPinAllocated(gpio)) { if (isPinAllocated(gpio)) {
#ifdef WLED_DEBUG #ifdef WLED_DEBUG
DEBUG_PRINT(F("PIN ALLOC: Pin ")); DEBUG_PRINT(F("PIN ALLOC: Pin "));
@ -179,7 +195,7 @@ bool PinManagerClass::allocatePin(byte gpio, bool output, PinOwner tag)
#ifdef WLED_DEBUG #ifdef WLED_DEBUG
DEBUG_PRINT(F("PIN ALLOC: Pin ")); DEBUG_PRINT(F("PIN ALLOC: Pin "));
DEBUG_PRINT(gpio); DEBUG_PRINT(gpio);
DEBUG_PRINT(F(" allocated by ")); DEBUG_PRINT(F(" successfully allocated by "));
DebugPrintOwnerTag(tag); DebugPrintOwnerTag(tag);
DEBUG_PRINTLN(F("")); DEBUG_PRINTLN(F(""));
#endif #endif
@ -198,6 +214,45 @@ bool PinManagerClass::isPinAllocated(byte gpio, PinOwner tag)
return bitRead(pinAlloc[by], bi); return bitRead(pinAlloc[by], bi);
} }
#if defined(CONFIG_IDF_TARGET_ESP32S3) || defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C3)
// ESP32-S3 GPIO layout
/* see https://docs.espressif.com/projects/esp-idf/en/latest/esp32s3/api-reference/peripherals/gpio.html
* The ESP32-S3 chip features 45 physical GPIO pins (GPIO0 ~ GPIO21 and GPIO26 ~ GPIO48). Each pin can be used as a general-purpose I/O
* Strapping pins: GPIO0, GPIO3, GPIO45 and GPIO46 are strapping pins. For more infomation, please refer to ESP32-S3 datasheet.
* Serial TX = GPIO43, RX = GPIO44; LED BUILTIN is usually GPIO39
* USB-JTAG: GPIO 19 and 20 are used by USB-JTAG by default. In order to use them as GPIOs, USB-JTAG will be disabled by the drivers.
* SPI0/1: GPIO26-32 are usually used for SPI flash and PSRAM and not recommended for other uses.
* When using Octal Flash or Octal PSRAM or both, GPIO33~37 are connected to SPIIO4 ~ SPIIO7 and SPIDQS. Therefore, on boards embedded with ESP32-S3R8 / ESP32-S3R8V chip, GPIO33~37 are also not recommended for other uses.
*
* see https://docs.espressif.com/projects/esp-idf/en/v4.4.2/esp32s3/api-reference/peripherals/adc.html
* https://docs.espressif.com/projects/esp-idf/en/latest/esp32s3/api-reference/peripherals/adc_oneshot.html
* ADC1: GPIO1 - GPIO10 (channel 0..9)
* ADC2: GPIO11 - GPIO20 (channel 0..9)
* adc_power_acquire(): Please do not use the interrupt of GPIO36 and GPIO39 when using ADC or Wi-Fi and Bluetooth with sleep mode enabled. As a workaround, call adc_power_acquire() in the APP.
* Since the ADC2 module is also used by the Wi-Fi, reading operation of adc2_get_raw() may fail between esp_wifi_start() and esp_wifi_stop(). Use the return code to see whether the reading is successful.
*/
bool PinManagerClass::isPinOk(byte gpio, bool output)
{
#if defined(CONFIG_IDF_TARGET_ESP32C3)
if ((gpio > 10) && (gpio < 18)) return false; // 11-17 SPI FLASH
if (gpio < 22) return true;
#else // S2 & S3
#if defined(CONFIG_IDF_TARGET_ESP32S3)
if (gpio < 19) return true; // 00 to 18 are for general use. Be careful about straping pins GPIO0 and GPIO3 - these may be pulled-up or pulled-down on your board.
if (gpio < 21) return false; // 19 + 20 = USB-JTAG. Not recommended for other uses.
if ((gpio > 21) && (gpio < 33)) return false; // 22 to 32: not connected + SPI FLASH
//if (gpio <38) return false; // 33 to 37: not available if using _octal_ SPI Flash or _octal_ PSRAM
if (gpio < 49) return true; // 38 to 48 are for general use. Be careful about straping pins GPIO45 and GPIO46 - these may be pull-up or pulled-down on your board.
#elif defined(CONFIG_IDF_TARGET_ESP32S2)
if (gpio < 22) return true; // 00 to 21 are for general use.
if ((gpio > 21) && (gpio < 33)) return false; // 22 to 32: not connected + SPI FLASH
if (gpio < 46) return true; // 33 to 45 are for general use.
if (gpio == 46 && !output) return true; // 46 input only
#endif
#endif
return false;
}
#else // ESP32 and ESP8266 GPIO layout
bool PinManagerClass::isPinOk(byte gpio, bool output) bool PinManagerClass::isPinOk(byte gpio, bool output)
{ {
if (gpio < 6) return true; if (gpio < 6) return true;
@ -212,6 +267,7 @@ bool PinManagerClass::isPinOk(byte gpio, bool output)
return false; return false;
} }
#endif
PinOwner PinManagerClass::getPinOwner(byte gpio) { PinOwner PinManagerClass::getPinOwner(byte gpio) {
if (!isPinOk(gpio, false)) return PinOwner::None; if (!isPinOk(gpio, false)) return PinOwner::None;
@ -219,11 +275,20 @@ PinOwner PinManagerClass::getPinOwner(byte gpio) {
} }
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
#if defined(CONFIG_IDF_TARGET_ESP32C3)
#define MAX_LED_CHANNELS 6
#else
#if defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32S3)
#define MAX_LED_CHANNELS 8
#else
#define MAX_LED_CHANNELS 16
#endif
#endif
byte PinManagerClass::allocateLedc(byte channels) byte PinManagerClass::allocateLedc(byte channels)
{ {
if (channels > 16 || channels == 0) return 255; if (channels > MAX_LED_CHANNELS || channels == 0) return 255;
byte ca = 0; byte ca = 0;
for (byte i = 0; i < 16; i++) { for (byte i = 0; i < MAX_LED_CHANNELS; i++) {
byte by = i >> 3; byte by = i >> 3;
byte bi = i - 8*by; byte bi = i - 8*by;
if (bitRead(ledcAlloc[by], bi)) { //found occupied pin if (bitRead(ledcAlloc[by], bi)) { //found occupied pin
@ -248,7 +313,7 @@ byte PinManagerClass::allocateLedc(byte channels)
void PinManagerClass::deallocateLedc(byte pos, byte channels) void PinManagerClass::deallocateLedc(byte pos, byte channels)
{ {
for (byte j = pos; j < pos + channels; j++) { for (byte j = pos; j < pos + channels; j++) {
if (j > 16) return; if (j > MAX_LED_CHANNELS) return;
byte by = j >> 3; byte by = j >> 3;
byte bi = j - 8*by; byte bi = j - 8*by;
bitWrite(ledcAlloc[by], bi, false); bitWrite(ledcAlloc[by], bi, false);

View File

@ -11,33 +11,43 @@ static char *tmpRAMbuffer = nullptr;
static volatile byte presetToApply = 0; static volatile byte presetToApply = 0;
static volatile byte callModeToApply = 0; static volatile byte callModeToApply = 0;
bool applyPreset(byte index, byte callMode, bool fromJson) bool applyPreset(byte index, byte callMode)
{ {
DEBUG_PRINT(F("Request to apply preset: ")); DEBUG_PRINT(F("Request to apply preset: "));
DEBUG_PRINTLN(index); DEBUG_PRINTLN(index);
presetToApply = index; presetToApply = index;
callModeToApply = callMode; callModeToApply = callMode;
/*
// the following is needed in case of HTTP JSON API call to return correct state to the caller // the following is needed in case of HTTP JSON API call to return correct state to the caller
// fromJson is true in case when deserializeState() was called with presetId==0 // fromJson is true in case when deserializeState() was called with presetId==0
if (fromJson) handlePresets(true); // force immediate processing if (fromJson) handlePresets(true); // force immediate processing
*/
return true; return true;
} }
void handlePresets(bool force) void handlePresets()
{ {
bool changePreset = false; bool changePreset = false;
uint8_t tmpPreset = presetToApply; // store temporary since deserializeState() may call applyPreset() uint8_t tmpPreset = presetToApply; // store temporary since deserializeState() may call applyPreset()
uint8_t tmpMode = callModeToApply; uint8_t tmpMode = callModeToApply;
if (tmpPreset == 0 || (fileDoc && !force)) return; // JSON buffer already allocated and not force apply or no preset waiting if (tmpPreset == 0 || (fileDoc /*&& !force*/)) return; // JSON buffer already allocated and not force apply or no preset waiting
JsonObject fdo; JsonObject fdo;
const char *filename = tmpPreset < 255 ? "/presets.json" : "/tmp.json"; const char *filename = tmpPreset < 255 ? "/presets.json" : "/tmp.json";
/*
* The following code is no longer needed as handlePreset() is never run from
* network callback.
* **************************************************************************
*
//crude way to determine if this was called by a network request //crude way to determine if this was called by a network request
uint8_t core = 1; uint8_t core = 1;
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
core = xPortGetCoreID(); #if !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S2)
// this does not make sense on single core
core = xPortGetCoreID();
#endif
#endif #endif
//only allow use of fileDoc from the core responsible for network requests (AKA HTTP JSON API) //only allow use of fileDoc from the core responsible for network requests (AKA HTTP JSON API)
//do not use active network request doc from preset called by main loop (playlist, schedule, ...) //do not use active network request doc from preset called by main loop (playlist, schedule, ...)
@ -77,7 +87,7 @@ void handlePresets(bool force)
} }
if (force) return; // something went wrong with force option (most likely WS request), quit and wait for async load if (force) return; // something went wrong with force option (most likely WS request), quit and wait for async load
*/
// allocate buffer // allocate buffer
if (!requestJSONBufferLock(9)) return; // will also assign fileDoc if (!requestJSONBufferLock(9)) return; // will also assign fileDoc

View File

@ -478,8 +478,8 @@ void handleSettingsSet(AsyncWebServerRequest *request, byte subPage)
if (!requestJSONBufferLock(5)) return; if (!requestJSONBufferLock(5)) return;
// global I2C & SPI pins // global I2C & SPI pins
int8_t hw_sda_pin = !request->arg(F("SDA")).length() ? -1 : max(-1,min(33,(int)request->arg(F("SDA")).toInt())); int8_t hw_sda_pin = !request->arg(F("SDA")).length() ? -1 : (int)request->arg(F("SDA")).toInt();
int8_t hw_scl_pin = !request->arg(F("SCL")).length() ? -1 : max(-1,min(33,(int)request->arg(F("SCL")).toInt())); int8_t hw_scl_pin = !request->arg(F("SCL")).length() ? -1 : (int)request->arg(F("SCL")).toInt();
#ifdef ESP8266 #ifdef ESP8266
// cannot change pins on ESP8266 // cannot change pins on ESP8266
if (hw_sda_pin >= 0 && hw_sda_pin != HW_PIN_SDA) hw_sda_pin = HW_PIN_SDA; if (hw_sda_pin >= 0 && hw_sda_pin != HW_PIN_SDA) hw_sda_pin = HW_PIN_SDA;
@ -501,9 +501,9 @@ void handleSettingsSet(AsyncWebServerRequest *request, byte subPage)
i2c_sda = -1; i2c_sda = -1;
i2c_scl = -1; i2c_scl = -1;
} }
int8_t hw_mosi_pin = !request->arg(F("MOSI")).length() ? -1 : max(-1,min(33,(int)request->arg(F("MOSI")).toInt())); int8_t hw_mosi_pin = !request->arg(F("MOSI")).length() ? -1 : (int)request->arg(F("MOSI")).toInt();
int8_t hw_miso_pin = !request->arg(F("MISO")).length() ? -1 : max(-1,min(33,(int)request->arg(F("MISO")).toInt())); int8_t hw_miso_pin = !request->arg(F("MISO")).length() ? -1 : (int)request->arg(F("MISO")).toInt();
int8_t hw_sclk_pin = !request->arg(F("SCLK")).length() ? -1 : max(-1,min(33,(int)request->arg(F("SCLK")).toInt())); int8_t hw_sclk_pin = !request->arg(F("SCLK")).length() ? -1 : (int)request->arg(F("SCLK")).toInt();
#ifdef ESP8266 #ifdef ESP8266
// cannot change pins on ESP8266 // cannot change pins on ESP8266
if (hw_mosi_pin >= 0 && hw_mosi_pin != HW_PIN_DATASPI) hw_mosi_pin = HW_PIN_DATASPI; if (hw_mosi_pin >= 0 && hw_mosi_pin != HW_PIN_DATASPI) hw_mosi_pin = HW_PIN_DATASPI;
@ -607,7 +607,7 @@ void handleSettingsSet(AsyncWebServerRequest *request, byte subPage)
} }
} }
usermods.readFromConfig(um); // force change of usermod parameters usermods.readFromConfig(um); // force change of usermod parameters
DEBUG_PRINTLN(F("Done re-init usermods."));
releaseJSONBufferLock(); releaseJSONBufferLock();
} }
@ -638,7 +638,7 @@ void handleSettingsSet(AsyncWebServerRequest *request, byte subPage)
#endif #endif
lastEditTime = millis(); lastEditTime = millis();
if (subPage != 2 && !doReboot) serializeConfig(); //do not save if factory reset or LED settings (which are saved after LED re-init) if (subPage != 2 && !doReboot) doSerializeConfig = true; //serializeConfig(); //do not save if factory reset or LED settings (which are saved after LED re-init)
if (subPage == 4) alexaInit(); if (subPage == 4) alexaInit();
} }

View File

@ -71,6 +71,8 @@ void WLED::loop()
yield(); yield();
if (doSerializeConfig) serializeConfig();
if (doReboot && !doInitBusses) // if busses have to be inited & saved, wait until next iteration if (doReboot && !doInitBusses) // if busses have to be inited & saved, wait until next iteration
reset(); reset();
@ -265,6 +267,9 @@ void WLED::setup()
Serial.begin(115200); Serial.begin(115200);
Serial.setTimeout(50); Serial.setTimeout(50);
#if defined(WLED_DEBUG) && (defined(CONFIG_IDF_TARGET_ESP32S2) || defined(CONFIG_IDF_TARGET_ESP32C3))
delay(2500); // allow CDC USB serial to initialise
#endif
DEBUG_PRINTLN(); DEBUG_PRINTLN();
DEBUG_PRINT(F("---WLED ")); DEBUG_PRINT(F("---WLED "));
DEBUG_PRINT(versionString); DEBUG_PRINT(versionString);
@ -274,6 +279,31 @@ void WLED::setup()
#ifdef ARDUINO_ARCH_ESP32 #ifdef ARDUINO_ARCH_ESP32
DEBUG_PRINT(F("esp32 ")); DEBUG_PRINT(F("esp32 "));
DEBUG_PRINTLN(ESP.getSdkVersion()); DEBUG_PRINTLN(ESP.getSdkVersion());
#if defined(ESP_ARDUINO_VERSION)
//DEBUG_PRINTF(F("arduino-esp32 0x%06x\n"), ESP_ARDUINO_VERSION);
DEBUG_PRINTF("arduino-esp32 v%d.%d.%d\n", int(ESP_ARDUINO_VERSION_MAJOR), int(ESP_ARDUINO_VERSION_MINOR), int(ESP_ARDUINO_VERSION_PATCH)); // availeable since v2.0.0
#else
DEBUG_PRINTLN(F("arduino-esp32 v1.0.x\n")); // we can't say in more detail.
#endif
DEBUG_PRINT(F("CPU: ")); DEBUG_PRINT(ESP.getChipModel());
DEBUG_PRINT(F(" rev.")); DEBUG_PRINT(ESP.getChipRevision());
DEBUG_PRINT(F(", ")); DEBUG_PRINT(ESP.getChipCores()); DEBUG_PRINT(F(" core(s)"));
DEBUG_PRINT(F(", ")); DEBUG_PRINT(ESP.getCpuFreqMHz()); DEBUG_PRINTLN(F("MHz."));
DEBUG_PRINT(F("FLASH: ")); DEBUG_PRINT((ESP.getFlashChipSize()/1024)/1024);
DEBUG_PRINT(F("MB, Mode ")); DEBUG_PRINT(ESP.getFlashChipMode());
#ifdef WLED_DEBUG
switch (ESP.getFlashChipMode()) {
// missing: Octal modes
case FM_QIO: DEBUG_PRINT(F(" (QIO)")); break;
case FM_QOUT: DEBUG_PRINT(F(" (QOUT)"));break;
case FM_DIO: DEBUG_PRINT(F(" (DIO)")); break;
case FM_DOUT: DEBUG_PRINT(F(" (DOUT)"));break;
default: break;
}
#endif
DEBUG_PRINT(F(", speed ")); DEBUG_PRINT(ESP.getFlashChipSpeed()/1000000);DEBUG_PRINTLN(F("MHz."));
#else #else
DEBUG_PRINT(F("esp8266 ")); DEBUG_PRINT(F("esp8266 "));
DEBUG_PRINTLN(ESP.getCoreVersion()); DEBUG_PRINTLN(ESP.getCoreVersion());
@ -283,17 +313,29 @@ void WLED::setup()
#if defined(ARDUINO_ARCH_ESP32) && defined(WLED_USE_PSRAM) #if defined(ARDUINO_ARCH_ESP32) && defined(WLED_USE_PSRAM)
if (psramFound()) { if (psramFound()) {
#if !defined(CONFIG_IDF_TARGET_ESP32C3) && !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32S3)
// GPIO16/GPIO17 reserved for SPI RAM // GPIO16/GPIO17 reserved for SPI RAM
managed_pin_type pins[2] = { {16, true}, {17, true} }; managed_pin_type pins[2] = { {16, true}, {17, true} };
pinManager.allocateMultiplePins(pins, 2, PinOwner::SPI_RAM); pinManager.allocateMultiplePins(pins, 2, PinOwner::SPI_RAM);
} #elif defined(CONFIG_IDF_TARGET_ESP32S3)
// S3: add GPIO 33-37 for "octal" PSRAM
managed_pin_type pins[5] = { {33, true}, {34, true}, {35, true}, {36, true}, {37, true} };
pinManager.allocateMultiplePins(pins, 5, PinOwner::SPI_RAM);
#endif
DEBUG_PRINT(F("Total PSRAM: ")); DEBUG_PRINT(ESP.getPsramSize()/1024); DEBUG_PRINTLN("kB");
DEBUG_PRINT(F("Free PSRAM : ")); DEBUG_PRINT(ESP.getFreePsram()/1024); DEBUG_PRINTLN("kB");
} else
DEBUG_PRINTLN(F("No PSRAM found."));
#endif
#if defined(ARDUINO_ARCH_ESP32) && defined(BOARD_HAS_PSRAM) && !defined(WLED_USE_PSRAM)
DEBUG_PRINTLN(F("PSRAM not used."));
#endif #endif
//DEBUG_PRINT(F("LEDs inited. heap usage ~")); //DEBUG_PRINT(F("LEDs inited. heap usage ~"));
//DEBUG_PRINTLN(heapPreAlloc - ESP.getFreeHeap()); //DEBUG_PRINTLN(heapPreAlloc - ESP.getFreeHeap());
#ifdef WLED_DEBUG #ifdef WLED_DEBUG
pinManager.allocatePin(1, true, PinOwner::DebugOut); // GPIO1 reserved for debug output pinManager.allocatePin(hardwareTX, true, PinOwner::DebugOut); // TX (GPIO1 on ESP32) reserved for debug output
#endif #endif
#ifdef WLED_ENABLE_DMX //reserve GPIO2 as hardcoded DMX pin #ifdef WLED_ENABLE_DMX //reserve GPIO2 as hardcoded DMX pin
pinManager.allocatePin(2, true, PinOwner::DMX); pinManager.allocatePin(2, true, PinOwner::DMX);
@ -320,6 +362,7 @@ void WLED::setup()
#endif #endif
updateFSInfo(); updateFSInfo();
strcpy_P(apSSID, PSTR("WLED-AP")); // otherwise it is empty on first boot until config is saved
DEBUG_PRINTLN(F("Reading config")); DEBUG_PRINTLN(F("Reading config"));
deserializeConfigFromFS(); deserializeConfigFromFS();
@ -348,7 +391,7 @@ void WLED::setup()
#ifdef WLED_ENABLE_ADALIGHT #ifdef WLED_ENABLE_ADALIGHT
//Serial RX (Adalight, Improv, Serial JSON) only possible if GPIO3 unused //Serial RX (Adalight, Improv, Serial JSON) only possible if GPIO3 unused
//Serial TX (Debug, Improv, Serial JSON) only possible if GPIO1 unused //Serial TX (Debug, Improv, Serial JSON) only possible if GPIO1 unused
if (!pinManager.isPinAllocated(3) && !pinManager.isPinAllocated(1)) { if (!pinManager.isPinAllocated(hardwareRX) && !pinManager.isPinAllocated(hardwareTX)) {
Serial.println(F("Ada")); Serial.println(F("Ada"));
} }
#endif #endif
@ -357,25 +400,16 @@ void WLED::setup()
escapedMac = WiFi.macAddress(); escapedMac = WiFi.macAddress();
escapedMac.replace(":", ""); escapedMac.replace(":", "");
escapedMac.toLowerCase(); escapedMac.toLowerCase();
if (strcmp(cmDNS, "x") == 0) // fill in unique mdns default // fill in unique mdns default
{ if (strcmp(cmDNS, "x") == 0) sprintf_P(cmDNS, PSTR("wled-%*s"), 6, escapedMac.c_str() + 6);
strcpy_P(cmDNS, PSTR("wled-")); if (mqttDeviceTopic[0] == 0) sprintf_P(mqttDeviceTopic, PSTR("wled/%*s"), 6, escapedMac.c_str() + 6);
sprintf(cmDNS + 5, "%*s", 6, escapedMac.c_str() + 6); if (mqttClientID[0] == 0) sprintf_P(mqttClientID, PSTR("WLED-%*s"), 6, escapedMac.c_str() + 6);
}
if (mqttDeviceTopic[0] == 0) {
strcpy_P(mqttDeviceTopic, PSTR("wled/"));
sprintf(mqttDeviceTopic + 5, "%*s", 6, escapedMac.c_str() + 6);
}
if (mqttClientID[0] == 0) {
strcpy_P(mqttClientID, PSTR("WLED-"));
sprintf(mqttClientID + 5, "%*s", 6, escapedMac.c_str() + 6);
}
#ifdef WLED_ENABLE_ADALIGHT #ifdef WLED_ENABLE_ADALIGHT
if (Serial.available() > 0 && Serial.peek() == 'I') handleImprovPacket(); if (Serial.available() > 0 && Serial.peek() == 'I') handleImprovPacket();
#endif #endif
strip.service(); strip.service(); // why?
#ifndef WLED_DISABLE_OTA #ifndef WLED_DISABLE_OTA
if (aOtaEnabled) { if (aOtaEnabled) {
@ -443,10 +477,10 @@ void WLED::initAP(bool resetAP)
if (apBehavior == AP_BEHAVIOR_BUTTON_ONLY && !resetAP) if (apBehavior == AP_BEHAVIOR_BUTTON_ONLY && !resetAP)
return; return;
if (!apSSID[0] || resetAP) if (resetAP) {
strcpy_P(apSSID, PSTR("WLED-AP")); strcpy_P(apSSID, PSTR("WLED-AP"));
if (resetAP)
strcpy_P(apPass, PSTR(DEFAULT_AP_PASS)); strcpy_P(apPass, PSTR(DEFAULT_AP_PASS));
}
DEBUG_PRINT(F("Opening access point ")); DEBUG_PRINT(F("Opening access point "));
DEBUG_PRINTLN(apSSID); DEBUG_PRINTLN(apSSID);
WiFi.softAPConfig(IPAddress(4, 3, 2, 1), IPAddress(4, 3, 2, 1), IPAddress(255, 255, 255, 0)); WiFi.softAPConfig(IPAddress(4, 3, 2, 1), IPAddress(4, 3, 2, 1), IPAddress(255, 255, 255, 0));
@ -800,7 +834,7 @@ void WLED::handleStatusLED()
ledStatusType = 4; ledStatusType = 4;
} else if (apActive) { } else if (apActive) {
c = RGBW32(0,0,255,0); c = RGBW32(0,0,255,0);
ledStatusType = 2; ledStatusType = 1;
} }
if (ledStatusType) { if (ledStatusType) {
if (millis() - ledStatusLastMillis >= (1000/ledStatusType)) { if (millis() - ledStatusLastMillis >= (1000/ledStatusType)) {

View File

@ -8,7 +8,7 @@
*/ */
// version code in format yymmddb (b = daily build) // version code in format yymmddb (b = daily build)
#define VERSION 2209091 #define VERSION 2209201
//uncomment this if you have a "my_config.h" file you'd like to use //uncomment this if you have a "my_config.h" file you'd like to use
//#define WLED_USE_MY_CONFIG //#define WLED_USE_MY_CONFIG
@ -251,6 +251,16 @@ WLED_GLOBAL int8_t irPin _INIT(-1);
WLED_GLOBAL int8_t irPin _INIT(IRPIN); WLED_GLOBAL int8_t irPin _INIT(IRPIN);
#endif #endif
#if defined(CONFIG_IDF_TARGET_ESP32S3) || defined(CONFIG_IDF_TARGET_ESP32C3) || defined(CONFIG_IDF_TARGET_ESP32S2) || (defined(RX) && defined(TX))
// use RX/TX as set by the framework - these boards do _not_ have RX=3 and TX=1
constexpr uint8_t hardwareRX = RX;
constexpr uint8_t hardwareTX = TX;
#else
// use defaults for RX/TX
constexpr uint8_t hardwareRX = 3;
constexpr uint8_t hardwareTX = 1;
#endif
//WLED_GLOBAL byte presetToApply _INIT(0); //WLED_GLOBAL byte presetToApply _INIT(0);
WLED_GLOBAL char ntpServerName[33] _INIT("0.wled.pool.ntp.org"); // NTP server to use WLED_GLOBAL char ntpServerName[33] _INIT("0.wled.pool.ntp.org"); // NTP server to use
@ -609,8 +619,9 @@ WLED_GLOBAL byte errorFlag _INIT(0);
WLED_GLOBAL String messageHead, messageSub; WLED_GLOBAL String messageHead, messageSub;
WLED_GLOBAL byte optionType; WLED_GLOBAL byte optionType;
WLED_GLOBAL bool doReboot _INIT(false); // flag to initiate reboot from async handlers WLED_GLOBAL bool doSerializeConfig _INIT(false); // flag to initiate saving of config
WLED_GLOBAL bool doPublishMqtt _INIT(false); WLED_GLOBAL bool doReboot _INIT(false); // flag to initiate reboot from async handlers
WLED_GLOBAL bool doPublishMqtt _INIT(false);
// status led // status led
#if defined(STATUSLED) #if defined(STATUSLED)

View File

@ -26,7 +26,7 @@ void updateBaudRate(uint32_t rate){
if (rate100 == currentBaud || rate100 < 96) return; if (rate100 == currentBaud || rate100 < 96) return;
currentBaud = rate100; currentBaud = rate100;
if (!pinManager.isPinAllocated(1) || pinManager.getPinOwner(1) == PinOwner::DebugOut){ if (!pinManager.isPinAllocated(hardwareTX) || pinManager.getPinOwner(hardwareTX) == PinOwner::DebugOut){
Serial.print(F("Baud is now ")); Serial.println(rate); Serial.print(F("Baud is now ")); Serial.println(rate);
} }
@ -36,7 +36,7 @@ void updateBaudRate(uint32_t rate){
void handleSerial() void handleSerial()
{ {
if (pinManager.isPinAllocated(3)) return; if (pinManager.isPinAllocated(hardwareRX)) return;
#ifdef WLED_ENABLE_ADALIGHT #ifdef WLED_ENABLE_ADALIGHT
static auto state = AdaState::Header_A; static auto state = AdaState::Header_A;
@ -72,7 +72,7 @@ void handleSerial()
} else if (next == 0xB7) {updateBaudRate(1500000); } else if (next == 0xB7) {updateBaudRate(1500000);
} else if (next == 'l') { //RGB(W) LED data return as JSON array. Slow, but easy to use on the other end. } else if (next == 'l') { //RGB(W) LED data return as JSON array. Slow, but easy to use on the other end.
if (!pinManager.isPinAllocated(1) || pinManager.getPinOwner(1) == PinOwner::DebugOut){ if (!pinManager.isPinAllocated(hardwareTX) || pinManager.getPinOwner(hardwareTX) == PinOwner::DebugOut){
uint16_t used = strip.getLengthTotal(); uint16_t used = strip.getLengthTotal();
Serial.write('['); Serial.write('[');
for (uint16_t i=0; i<used; i+=1) { for (uint16_t i=0; i<used; i+=1) {
@ -82,7 +82,7 @@ void handleSerial()
Serial.println("]"); Serial.println("]");
} }
} else if (next == 'L') { //RGB LED data returned as bytes in tpm2 format. Faster, and slightly less easy to use on the other end. } else if (next == 'L') { //RGB LED data returned as bytes in tpm2 format. Faster, and slightly less easy to use on the other end.
if (!pinManager.isPinAllocated(1) || pinManager.getPinOwner(1) == PinOwner::DebugOut) { if (!pinManager.isPinAllocated(hardwareTX) || pinManager.getPinOwner(hardwareTX) == PinOwner::DebugOut) {
Serial.write(0xC9); Serial.write(0xDA); Serial.write(0xC9); Serial.write(0xDA);
uint16_t used = strip.getLengthTotal(); uint16_t used = strip.getLengthTotal();
uint16_t len = used*3; uint16_t len = used*3;
@ -107,7 +107,7 @@ void handleSerial()
} }
verboseResponse = deserializeState(doc.as<JsonObject>()); verboseResponse = deserializeState(doc.as<JsonObject>());
//only send response if TX pin is unused for other purposes //only send response if TX pin is unused for other purposes
if (verboseResponse && (!pinManager.isPinAllocated(1) || pinManager.getPinOwner(1) == PinOwner::DebugOut)) { if (verboseResponse && (!pinManager.isPinAllocated(hardwareTX) || pinManager.getPinOwner(hardwareTX) == PinOwner::DebugOut)) {
doc.clear(); doc.clear();
JsonObject state = doc.createNestedObject("state"); JsonObject state = doc.createNestedObject("state");
serializeState(state); serializeState(state);

View File

@ -207,7 +207,7 @@ void initServer()
if (!isConfig) { if (!isConfig) {
serveJson(request); return; //if JSON contains "v" serveJson(request); return; //if JSON contains "v"
} else { } else {
serializeConfig(); //Save new settings to FS doSerializeConfig = true; //serializeConfig(); //Save new settings to FS
} }
} }
request->send(200, "application/json", F("{\"success\":true}")); request->send(200, "application/json", F("{\"success\":true}"));

View File

@ -111,13 +111,18 @@ void sendDataWs(AsyncWebSocketClient * client)
DEBUG_PRINTF("JSON buffer size: %u for WS request (%u).\n", doc.memoryUsage(), len); DEBUG_PRINTF("JSON buffer size: %u for WS request (%u).\n", doc.memoryUsage(), len);
size_t heap1 = ESP.getFreeHeap(); size_t heap1 = ESP.getFreeHeap();
buffer = ws.makeBuffer(len); // will not allocate correct memory sometimes buffer = ws.makeBuffer(len); // will not allocate correct memory sometimes on ESP8266
#ifdef ESP8266
size_t heap2 = ESP.getFreeHeap(); size_t heap2 = ESP.getFreeHeap();
#else
size_t heap2 = 0; // ESP32 variants do not have the same issue and will work without checking heap allocation
#endif
if (!buffer || heap1-heap2<len) { if (!buffer || heap1-heap2<len) {
releaseJSONBufferLock(); releaseJSONBufferLock();
DEBUG_PRINTLN(F("WS buffer allocation failed.")); DEBUG_PRINTLN(F("WS buffer allocation failed."));
ws.closeAll(1013); //code 1013 = temporary overload, try again later ws.closeAll(1013); //code 1013 = temporary overload, try again later
ws.cleanupClients(0); //disconnect all clients to release memory ws.cleanupClients(0); //disconnect all clients to release memory
ws._cleanBuffers();
return; //out of memory return; //out of memory
} }

View File

@ -167,6 +167,112 @@ void fillUMPins(JsonObject &mods)
} }
} }
void appendGPIOinfo() {
char nS[8];
oappend(SET_F("d.um_p=[-1")); // has to have 1 element
if (i2c_sda > -1 && i2c_scl > -1) {
oappend(","); oappend(itoa(i2c_sda,nS,10));
oappend(","); oappend(itoa(i2c_scl,nS,10));
}
if (spi_mosi > -1 && spi_sclk > -1) {
oappend(","); oappend(itoa(spi_mosi,nS,10));
oappend(","); oappend(itoa(spi_sclk,nS,10));
}
// usermod pin reservations will become unnecessary when settings pages will read cfg.json directly
if (requestJSONBufferLock(6)) {
// if we can't allocate JSON buffer ignore usermod pins
JsonObject mods = doc.createNestedObject(F("um"));
usermods.addToConfig(mods);
if (!mods.isNull()) fillUMPins(mods);
releaseJSONBufferLock();
}
oappend(SET_F("];"));
// add reserved and usermod pins as d.um_p array
#if defined(CONFIG_IDF_TARGET_ESP32S2)
oappend(SET_F("d.rsvd=[22,23,24,25,26,27,28,29,30,31,32"));
#elif defined(CONFIG_IDF_TARGET_ESP32S3)
oappend(SET_F("d.rsvd=[19,20,22,23,24,25,26,27,28,29,30,31,32")); // includes 19+20 for USB OTG (JTAG)
#elif defined(CONFIG_IDF_TARGET_ESP32C3)
oappend(SET_F("d.rsvd=[11,12,13,14,15,16,17"));
#elif defined(ESP32)
oappend(SET_F("d.rsvd=[6,7,8,9,10,11,24,28,29,30,31"));
#else
oappend(SET_F("d.rsvd=[6,7,8,9,10,11"));
#endif
#ifdef WLED_ENABLE_DMX
oappend(SET_F(",2")); // DMX hardcoded pin
#endif
#ifdef WLED_DEBUG
oappend(SET_F(",")); oappend(itoa(hardwareTX,nS,10));// debug output (TX) pin
#endif
//Note: Using pin 3 (RX) disables Adalight / Serial JSON
#if defined(ARDUINO_ARCH_ESP32) && defined(WLED_USE_PSRAM)
#if !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32S3) && !defined(CONFIG_IDF_TARGET_ESP32C3)
if (psramFound()) oappend(SET_F(",16,17")); // GPIO16 & GPIO17 reserved for SPI RAM on ESP32 (not on S2, S3 or C3)
#elif defined(CONFIG_IDF_TARGET_ESP32S3)
if (psramFound()) oappend(SET_F(",33,34,35,36,37")); // in use for "octal" PSRAM or "octal" FLASH -seems that octal PSRAM is very common on S3.
#endif
#endif
#ifdef WLED_USE_ETHERNET
if (ethernetType != WLED_ETH_NONE && ethernetType < WLED_NUM_ETH_TYPES) {
for (uint8_t p=0; p<WLED_ETH_RSVD_PINS_COUNT; p++) { oappend(","); oappend(itoa(esp32_nonconfigurable_ethernet_pins[p].pin,nS,10)); }
if (ethernetBoards[ethernetType].eth_power>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_power,nS,10)); }
if (ethernetBoards[ethernetType].eth_mdc>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_mdc,nS,10)); }
if (ethernetBoards[ethernetType].eth_mdio>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_mdio,nS,10)); }
switch (ethernetBoards[ethernetType].eth_clk_mode) {
case ETH_CLOCK_GPIO0_IN:
case ETH_CLOCK_GPIO0_OUT:
oappend(SET_F(",0"));
break;
case ETH_CLOCK_GPIO16_OUT:
oappend(SET_F(",16"));
break;
case ETH_CLOCK_GPIO17_OUT:
oappend(SET_F(",17"));
break;
}
}
#endif
oappend(SET_F("];"));
// add info for read-only GPIO
oappend(SET_F("d.ro_gpio=["));
#if defined(CONFIG_IDF_TARGET_ESP32S2)
oappendi(46);
#elif defined(CONFIG_IDF_TARGET_ESP32S3)
// none for S3
#elif defined(CONFIG_IDF_TARGET_ESP32C3)
// none for C3
#elif defined(ESP32)
oappend(SET_F("34,35,36,37,38,39"));
#else
// none for ESP8266
#endif
oappend(SET_F("];"));
// add info about max. # of pins
oappend(SET_F("d.max_gpio="));
#if defined(CONFIG_IDF_TARGET_ESP32S2)
oappendi(46);
#elif defined(CONFIG_IDF_TARGET_ESP32S3)
oappendi(48);
#elif defined(CONFIG_IDF_TARGET_ESP32C3)
oappendi(21);
#elif defined(ESP32)
oappendi(39);
#else
oappendi(16);
#endif
oappend(SET_F(";"));
}
//get values for settings form in javascript //get values for settings form in javascript
void getSettingsJS(byte subPage, char* dest) void getSettingsJS(byte subPage, char* dest)
@ -257,69 +363,13 @@ void getSettingsJS(byte subPage, char* dest)
{ {
char nS[8]; char nS[8];
// Pin reservations will become unnecessary when settings pages will read cfg.json directly appendGPIOinfo();
// add reserved and usermod pins as d.um_p array
oappend(SET_F("d.um_p=[6,7,8,9,10,11"));
if (i2c_sda > -1 && i2c_scl > -1) {
oappend(","); oappend(itoa(i2c_sda,nS,10));
oappend(","); oappend(itoa(i2c_scl,nS,10));
}
if (spi_mosi > -1 && spi_sclk > -1) {
oappend(","); oappend(itoa(spi_mosi,nS,10));
oappend(","); oappend(itoa(spi_sclk,nS,10));
}
if (requestJSONBufferLock(6)) {
// if we can't allocate JSON buffer ignore usermod pins
JsonObject mods = doc.createNestedObject(F("um"));
usermods.addToConfig(mods);
if (!mods.isNull()) fillUMPins(mods);
releaseJSONBufferLock();
}
#ifdef WLED_ENABLE_DMX
oappend(SET_F(",2")); // DMX hardcoded pin
#endif
#ifdef WLED_DEBUG
oappend(SET_F(",1")); // debug output (TX) pin
#endif
//Note: Using pin 3 (RX) disables Adalight / Serial JSON
#if defined(ARDUINO_ARCH_ESP32) && defined(WLED_USE_PSRAM)
if (psramFound()) oappend(SET_F(",16,17")); // GPIO16 & GPIO17 reserved for SPI RAM
#endif
#ifdef WLED_USE_ETHERNET
if (ethernetType != WLED_ETH_NONE && ethernetType < WLED_NUM_ETH_TYPES) {
for (uint8_t p=0; p<WLED_ETH_RSVD_PINS_COUNT; p++) { oappend(","); oappend(itoa(esp32_nonconfigurable_ethernet_pins[p].pin,nS,10)); }
if (ethernetBoards[ethernetType].eth_power>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_power,nS,10)); }
if (ethernetBoards[ethernetType].eth_mdc>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_mdc,nS,10)); }
if (ethernetBoards[ethernetType].eth_mdio>=0) { oappend(","); oappend(itoa(ethernetBoards[ethernetType].eth_mdio,nS,10)); }
switch (ethernetBoards[ethernetType].eth_clk_mode) {
case ETH_CLOCK_GPIO0_IN:
case ETH_CLOCK_GPIO0_OUT:
oappend(SET_F(",0"));
break;
case ETH_CLOCK_GPIO16_OUT:
oappend(SET_F(",16"));
break;
case ETH_CLOCK_GPIO17_OUT:
oappend(SET_F(",17"));
break;
}
}
#endif
oappend(SET_F("];"));
// set limits // set limits
oappend(SET_F("bLimits(")); oappend(SET_F("bLimits("));
#if defined(ESP32) && defined(USERMOD_AUDIOREACTIVE) #if defined(ESP32) && defined(USERMOD_AUDIOREACTIVE) && !defined(CONFIG_IDF_TARGET_ESP32S2) && !defined(CONFIG_IDF_TARGET_ESP32S3) && !defined(CONFIG_IDF_TARGET_ESP32C3)
// requested by @softhack007 https://github.com/blazoncek/WLED/issues/33 // requested by @softhack007 https://github.com/blazoncek/WLED/issues/33
oappend(itoa(WLED_MAX_BUSSES-2,nS,10)); oappend(","); // prevent use of I2S buses if audio installed oappend(itoa(WLED_MAX_BUSSES-2,nS,10)); oappend(","); // prevent use of I2S buses if audio installed. ESP32-S3 currently does not support these busses.
#else #else
oappend(itoa(WLED_MAX_BUSSES,nS,10)); oappend(","); oappend(itoa(WLED_MAX_BUSSES,nS,10)); oappend(",");
#endif #endif
@ -500,14 +550,14 @@ void getSettingsJS(byte subPage, char* dest)
char hueErrorString[25]; char hueErrorString[25];
switch (hueError) switch (hueError)
{ {
case HUE_ERROR_INACTIVE : strcpy(hueErrorString,(char*)F("Inactive")); break; case HUE_ERROR_INACTIVE : strcpy_P(hueErrorString,PSTR("Inactive")); break;
case HUE_ERROR_ACTIVE : strcpy(hueErrorString,(char*)F("Active")); break; case HUE_ERROR_ACTIVE : strcpy_P(hueErrorString,PSTR("Active")); break;
case HUE_ERROR_UNAUTHORIZED : strcpy(hueErrorString,(char*)F("Unauthorized")); break; case HUE_ERROR_UNAUTHORIZED : strcpy_P(hueErrorString,PSTR("Unauthorized")); break;
case HUE_ERROR_LIGHTID : strcpy(hueErrorString,(char*)F("Invalid light ID")); break; case HUE_ERROR_LIGHTID : strcpy_P(hueErrorString,PSTR("Invalid light ID")); break;
case HUE_ERROR_PUSHLINK : strcpy(hueErrorString,(char*)F("Link button not pressed")); break; case HUE_ERROR_PUSHLINK : strcpy_P(hueErrorString,PSTR("Link button not pressed")); break;
case HUE_ERROR_JSON_PARSING : strcpy(hueErrorString,(char*)F("JSON parsing error")); break; case HUE_ERROR_JSON_PARSING : strcpy_P(hueErrorString,PSTR("JSON parsing error")); break;
case HUE_ERROR_TIMEOUT : strcpy(hueErrorString,(char*)F("Timeout")); break; case HUE_ERROR_TIMEOUT : strcpy_P(hueErrorString,PSTR("Timeout")); break;
default: sprintf(hueErrorString,(char*)F("Bridge Error %i"),hueError); default: sprintf_P(hueErrorString,PSTR("Bridge Error %i"),hueError);
} }
sappends('m',SET_F("(\"sip\")[0]"),hueErrorString); sappends('m',SET_F("(\"sip\")[0]"),hueErrorString);
@ -630,6 +680,7 @@ void getSettingsJS(byte subPage, char* dest)
if (subPage == 8) //usermods if (subPage == 8) //usermods
{ {
appendGPIOinfo();
oappend(SET_F("numM=")); oappend(SET_F("numM="));
oappendi(usermods.getModCount()); oappendi(usermods.getModCount());
oappend(";"); oappend(";");