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// How to use this library with a FM6126 panel, thanks goes to:
// https://github.com/hzeller/rpi-rgb-led-matrix/issues/746
// IDF
#if defined(IDF_VER)
#include <stdio.h>
#include <freertos/FreeRTOS.h>
#include <freertos/task.h>
#include <driver/gpio.h>
#include "sdkconfig.h"
#endif
#include <Arduino.h>
#include "xtensa/core-macros.h"
#include <ESP32-HUB75-MatrixPanel-I2S-DMA.h>
#include "main.h"
// HUB75E pinout
// R1 | G1
// B1 | GND
// R2 | G2
// B2 | E
// A | B
// C | D
// CLK| LAT
// OE | GND
#define R1 25
#define G1 26
#define BL1 27
#define R2 14 // 21 SDA
#define G2 12 // 22 SDL
#define BL2 13
#define CH_A 23
#define CH_B 19
#define CH_C 5
#define CH_D 17
#define CH_E 32 // assign to any available pin if using two panels or 64x64 panels with 1/32 scan
#define CLK 16
#define LAT 4
#define OE 15
#define M_WIDTH 256
#define M_HEIGHT 64
#define PATTERN_DELAY 2000
#define NUM_LEDS M_WIDTH*M_HEIGHT
//#define USE_FASTLINES
MatrixPanel_I2S_DMA *matrix = nullptr;
uint16_t time_counter = 0, cycles = 0, fps = 0;
unsigned long fps_timer;
//
CRGB *ledbuff;
//
unsigned long t1, t2, s1=0, s2=0, s3=0;
uint32_t ccount1, ccount2;
uint8_t color1 = 0, color2 = 0, color3 = 0;
uint16_t x,y;
void setup(){
Serial.begin(BAUD_RATE);
Serial.println("Starting pattern test...");
HUB75_I2S_CFG::i2s_pins _pins={R1, G1, BL1, R2, G2, BL2, CH_A, CH_B, CH_C, CH_D, CH_E, LAT, OE, CLK};
HUB75_I2S_CFG mxconfig(64, 64, 4, _pins, HUB75_I2S_CFG::FM6126A);
mxconfig.i2sspeed = HUB75_I2S_CFG::HZ_20M;
matrix = new MatrixPanel_I2S_DMA(mxconfig);
matrix->begin();
matrix->setBrightness8(255);
//matrix->setLatBlanking(2);
ledbuff = (CRGB *)malloc(NUM_LEDS * sizeof(CRGB)); // allocate buffer for some tests
buffclear(ledbuff);
}
void loop(){
Serial.printf("Cycle: %d\n", ++cycles);
Serial.print("Estimating clearScreen() - ");
ccount1 = XTHAL_GET_CCOUNT();
matrix->clearScreen();
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
Serial.printf("%d ticks\n", ccount1);
delay(PATTERN_DELAY);
/*
// Power supply tester
// slowly fills matrix with white, stressing PSU
for (int y=0; y!=M_HEIGHT; ++y){
for (int x=0; x!=M_WIDTH; ++x){
matrix->drawPixelRGB888(x, y, 255,255,255);
//matrix->drawPixelRGB888(x, y-1, 255,0,0); // pls, be gentle :)
delay(10);
}
}
delay(5000);
*/
// simple solid colors
Serial.println("Fill screen: RED");
matrix->fillScreenRGB888(255, 0, 0);
delay(PATTERN_DELAY);
Serial.println("Fill screen: GREEN");
matrix->fillScreenRGB888(0, 255, 0);
delay(PATTERN_DELAY);
Serial.println("Fill screen: BLUE");
matrix->fillScreenRGB888(0, 0, 255);
delay(PATTERN_DELAY);
for (uint8_t i=5; i; --i){
Serial.print("Estimating single drawPixelRGB888(r, g, b) ticks: ");
color1 = random8();
ccount1 = XTHAL_GET_CCOUNT();
matrix->drawPixelRGB888(i,i, color1, color1, color1);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
Serial.printf("%d ticks\n", ccount1);
}
// Clearing CRGB ledbuff
Serial.print("Estimating ledbuff clear time: ");
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
buffclear(ledbuff);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n\n", t2, ccount1);
// Bare fillscreen(r, g, b)
Serial.print("Estimating fillscreenRGB888(r, g, b) time: ");
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
matrix->fillScreenRGB888(64, 64, 64); // white
ccount2 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
s1+=t2;
Serial.printf("%lu us, avg: %lu, ccnt: %d\n", t2, s1/cycles, ccount2);
delay(PATTERN_DELAY);
Serial.print("Estimating full-screen fillrate with looped drawPixelRGB888(): ");
y = M_HEIGHT;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
--y;
uint16_t x = M_WIDTH;
do {
--x;
matrix->drawPixelRGB888( x, y, 0, 0, 0);
} while(x);
} while(y);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
// created random color gradient in ledbuff
uint8_t color1 = 0;
uint8_t color2 = random8();
uint8_t color3 = 0;
for (uint16_t i = 0; i<NUM_LEDS; ++i){
ledbuff[i].r=color1++;
ledbuff[i].g=color2;
if (i%M_WIDTH==0)
color3+=255/M_HEIGHT;
ledbuff[i].b=color3;
}
//
//
Serial.print("Estimating ledbuff-to-matrix fillrate with drawPixelRGB888(), time: ");
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
mxfill(ledbuff);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
s2+=t2;
Serial.printf("%lu us, avg: %lu, %d ticks:\n", t2, s2/cycles, ccount1);
delay(PATTERN_DELAY);
//
#ifdef USE_FASTLINES
// Fillrate for fillRect() function
Serial.print("Estimating fullscreen fillrate with fillRect() time: ");
t1 = micros();
matrix->fillRect(0, 0, M_WIDTH, M_HEIGHT, 0, 224, 0);
t2 = micros()-t1;
Serial.printf("%lu us\n", t2);
delay(PATTERN_DELAY);
Serial.print("Chessboard with fillRect(): "); // шахматка
matrix->fillScreen(0);
x =0, y = 0;
color1 = random8();
color2 = random8();
color3 = random8();
bool toggle=0;
t1 = micros();
do {
do{
matrix->fillRect(x, y, 8, 8, color1, color2, color3);
x+=16;
}while(x < M_WIDTH);
y+=8;
toggle = !toggle;
x = toggle ? 8 : 0;
}while(y < M_HEIGHT);
t2 = micros()-t1;
Serial.printf("%lu us\n", t2);
delay(PATTERN_DELAY);
#endif
// ======== V-Lines ==========
Serial.println("Estimating V-lines with drawPixelRGB888(): "); //
matrix->fillScreen(0);
color1 = random8();
color2 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
y=0;
do{
matrix->drawPixelRGB888(x, y, color1, color2, color3);
} while(++y != M_HEIGHT);
x+=2;
} while(x != M_WIDTH);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
#ifdef USE_FASTLINES
Serial.println("Estimating V-lines with vlineDMA(): "); //
matrix->fillScreen(0);
color2 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
matrix->drawFastVLine(x, y, M_HEIGHT, color1, color2, color3);
x+=2;
} while(x != M_WIDTH);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
Serial.println("Estimating V-lines with fillRect(): "); //
matrix->fillScreen(0);
color1 = random8();
color2 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
matrix->fillRect(x, y, 1, M_HEIGHT, color1, color2, color3);
x+=2;
} while(x != M_WIDTH);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
#endif
// ======== H-Lines ==========
Serial.println("Estimating H-lines with drawPixelRGB888(): "); //
matrix->fillScreen(0);
color2 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
x=0;
do{
matrix->drawPixelRGB888(x, y, color1, color2, color3);
} while(++x != M_WIDTH);
y+=2;
} while(y != M_HEIGHT);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
#ifdef USE_FASTLINES
Serial.println("Estimating H-lines with hlineDMA(): ");
matrix->fillScreen(0);
color2 = random8();
color3 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
matrix->drawFastHLine(x, y, M_WIDTH, color1, color2, color3);
y+=2;
} while(y != M_HEIGHT);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
Serial.println("Estimating H-lines with fillRect(): "); //
matrix->fillScreen(0);
color2 = random8();
color3 = random8();
x = y = 0;
t1 = micros();
ccount1 = XTHAL_GET_CCOUNT();
do {
matrix->fillRect(x, y, M_WIDTH, 1, color1, color2, color3);
y+=2;
} while(y != M_HEIGHT);
ccount1 = XTHAL_GET_CCOUNT() - ccount1;
t2 = micros()-t1;
Serial.printf("%lu us, %u ticks\n", t2, ccount1);
delay(PATTERN_DELAY);
#endif
Serial.println("\n====\n");
// take a rest for a while
delay(10000);
}
void buffclear(CRGB *buf){
memset(buf, 0x00, NUM_LEDS * sizeof(CRGB)); // flush buffer to black
}
void IRAM_ATTR mxfill(CRGB *leds){
uint16_t y = M_HEIGHT;
do {
--y;
uint16_t x = M_WIDTH;
do {
--x;
uint16_t _pixel = y * M_WIDTH + x;
matrix->drawPixelRGB888( x, y, leds[_pixel].r, leds[_pixel].g, leds[_pixel].b);
} while(x);
} while(y);
}
//
/**
* The one for 256+ matrixes
* otherwise this:
* for (uint8_t i = 0; i < MATRIX_WIDTH; i++) {}
* turns into an infinite loop
*/
uint16_t XY16( uint16_t x, uint16_t y)
{
if (x<M_WIDTH && y < M_HEIGHT){
return (y * M_WIDTH) + x; // everything offset by one to capute out of bounds stuff - never displayed by ShowFrame()
} else {
return 0;
}
}
|
