/* Various LED Driver chips might need some specific code for initialisation/control logic */ #include #include "ESP32-HUB75-MatrixPanel-I2S-DMA.h" #define CLK_PULSE digitalWrite(_cfg.gpio.clk, HIGH); digitalWrite(_cfg.gpio.clk, LOW); /** * @brief - pre-init procedures for specific led-drivers * this method is called before DMA/I2S setup while GPIOs * aint yet assigned for DMA operation * */ void MatrixPanel_I2S_DMA::shiftDriver(const HUB75_I2S_CFG& _cfg){ switch (_cfg.driver){ case HUB75_I2S_CFG::ICN2038S: case HUB75_I2S_CFG::FM6124: case HUB75_I2S_CFG::FM6126A: fm6124init(_cfg); break; case HUB75_I2S_CFG::MBI5124: /* MBI5124 chips must be clocked with positive-edge, since it's LAT signal * resets on clock's rising edge while high * https://github.com/mrfaptastic/ESP32-HUB75-MatrixPanel-I2S-DMA/files/5952216/5a542453754da.pdf */ m_cfg.clkphase=true; break; case HUB75_I2S_CFG::SHIFTREG: default: break; } } void MatrixPanel_I2S_DMA::fm6124init(const HUB75_I2S_CFG& _cfg){ #if SERIAL_DEBUG Serial.println( F("MatrixPanel_I2S_DMA - initializing FM6124 driver...")); #endif bool REG1[16] = {0,0,0,0,0, 1,1,1,1,1,1, 0,0,0,0,0}; // this sets global matrix brightness power bool REG2[16] = {0,0,0,0,0, 0,0,0,0,1,0, 0,0,0,0,0}; // a single bit enables the matrix output for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2, _cfg.gpio.clk, _cfg.gpio.lat, _cfg.gpio.oe}){ pinMode(_pin, OUTPUT); digitalWrite(_pin, LOW); } digitalWrite(_cfg.gpio.oe, HIGH); // Disable Display // Send Data to control register REG1 // this sets the matrix brightness actually for (int l = 0; l < PIXELS_PER_ROW; l++){ for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2}) digitalWrite(_pin, REG1[l%16]); // we have 16 bits shifters and write the same value all over the matrix array if (l > PIXELS_PER_ROW - 12){ // pull the latch 11 clocks before the end of matrix so that REG1 starts counting to save the value digitalWrite(_cfg.gpio.lat, HIGH); } CLK_PULSE } // drop the latch and save data to the REG1 all over the FM6124 chips digitalWrite(_cfg.gpio.lat, LOW); // Send Data to control register REG2 (enable LED output) for (int l = 0; l < PIXELS_PER_ROW; l++){ for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2}) digitalWrite(_pin, REG2[l%16]); // we have 16 bits shifters and we write the same value all over the matrix array if (l > PIXELS_PER_ROW - 13){ // pull the latch 12 clocks before the end of matrix so that reg2 stars counting to save the value digitalWrite(_cfg.gpio.lat, HIGH); } CLK_PULSE } // drop the latch and save data to the REG1 all over the FM6126 chips digitalWrite(_cfg.gpio.lat, LOW); // blank data regs to keep matrix clear after manipulations for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2}) digitalWrite(_pin, LOW); for (int l = 0; l < PIXELS_PER_ROW; ++l){ CLK_PULSE } digitalWrite(_cfg.gpio.lat, HIGH); CLK_PULSE digitalWrite(_cfg.gpio.lat, LOW); digitalWrite(_cfg.gpio.oe, LOW); // Enable Display CLK_PULSE }