/* xlgt_08_bp5758d.ino - bp5758d five channel led support for Tasmota Copyright (C) 2022 Theo Arends and oomg This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #ifdef USE_LIGHT #ifdef USE_BP5758D /*********************************************************************************************\ * BP5758D RGBCW Led bulbs commonly used by Tuya hardware * * Example configuration for a Fitop RGBCCT filament light bulb: * {"NAME":"Fitop Filament RGBCCT","GPIO":[1,1,0,1,1,0,0,0,8416,0,8384,0,0,0],"FLAG":0,"BASE":18,"CMND":"RGBWWTable 255,109,245,255,255"} \*********************************************************************************************/ #define XLGT_08 8 // Layout: Bits B[7:8]=10 (address selection identification bits), B[5:6] sleep mode if set to 00, B[0:4] Address selection #define BP5758D_ADDR_SLEEP 0x80 //10 00 xxxx: Set to sleep mode #define BP5758D_ADDR_SETUP 0x90 //10 01 0000: OUT1-5 enable/disable setup - used during init #define BP5758D_ADDR_OUT1_CR 0x91 //10 01 0001: OUT1 current range #define BP5758D_ADDR_OUT2_CR 0x92 //10 01 0010: OUT2 current range #define BP5758D_ADDR_OUT3_CR 0x93 //10 01 0011: OUT3 current range #define BP5758D_ADDR_OUT4_CR 0x94 //10 01 0100: OUT4 current range #define BP5758D_ADDR_OUT5_CR 0x95 //10 01 0101: OUT5 current range #define BP5758D_ADDR_OUT1_GL 0x96 //10 01 0110: OUT1 gray-scale level #define BP5758D_ADDR_OUT2_GL 0x98 //10 01 1000: OUT2 gray-scale level #define BP5758D_ADDR_OUT3_GL 0x9A //10 01 1010: OUT3 gray-scale level #define BP5758D_ADDR_OUT4_GL 0x9C //10 01 1100: OUT4 gray-scale level #define BP5758D_ADDR_OUT5_GL 0x9E //10 01 1110: OUT5 gray-scale level // Output enabled (OUT1-5, represented by lower 5 bits) #define BP5758D_ENABLE_OUTPUTS_ALL 0x1F #define BP5758D_DISABLE_OUTPUTS_ALL 0x00 // Current values: Bit 6 to 0 represent 30mA, 32mA, 16mA, 8mA, 4mA, 2mA, 1mA respectively #define BP5758D_10MA 0x0A // 0 0001010 #define BP5758D_14MA 0x0E // 0 0001110 #define BP5758D_15MA 0x0F // 0 0001111 #define BP5758D_65MA 0x63 // 0 1100011 #define BP5758D_90MA 0x7C // 0 1111100 struct BP5758D { uint8_t clk = 0; uint8_t data = 0; uint8_t current; } Bp5758d; /*********************************************************************************************\ * Bp5758d code - inspired by SM2135 and github.com/dbuezas/esphome-bp5758 \*********************************************************************************************/ const uint8_t BP5758D_DELAY = 2; void Bp5758dInit(void) { pinMode(Bp5758d.data, OUTPUT); pinMode(Bp5758d.clk, OUTPUT); Bp5758dStop(); } void Bp5758dWrite(uint8_t value) { for (int bit_idx = 7; bit_idx >= 0; bit_idx--) { bool bit = bitRead(value, bit_idx); digitalWrite(Bp5758d.data, bit); delayMicroseconds(BP5758D_DELAY); digitalWrite(Bp5758d.clk, HIGH); delayMicroseconds(BP5758D_DELAY); digitalWrite(Bp5758d.clk, LOW); delayMicroseconds(BP5758D_DELAY); } // Wait for ACK pinMode(Bp5758d.data, INPUT); digitalWrite(Bp5758d.clk, HIGH); delayMicroseconds(BP5758D_DELAY); digitalWrite(Bp5758d.clk, LOW); delayMicroseconds(BP5758D_DELAY); pinMode(Bp5758d.data, OUTPUT); } void Bp5758dStart(uint8_t addr) { digitalWrite(Bp5758d.data, LOW); delayMicroseconds(BP5758D_DELAY); digitalWrite(Bp5758d.clk, LOW); delayMicroseconds(BP5758D_DELAY); Bp5758dWrite(addr); } void Bp5758dStop(void) { digitalWrite(Bp5758d.clk, HIGH); delayMicroseconds(BP5758D_DELAY); digitalWrite(Bp5758d.data, HIGH); delayMicroseconds(BP5758D_DELAY); } /********************************************************************************************/ bool Bp5758dSetChannels(void) { static bool bIsSleeping = false; //Save sleep state of Lamp uint16_t *cur_col_10 = (uint16_t*)XdrvMailbox.command; // If we receive 0 for all channels, we'll assume that the lightbulb is off, and activate BP5758d's sleep mode. if (cur_col_10[0]==0 && cur_col_10[1]==0 && cur_col_10[2]==0 && cur_col_10[3]==0 && cur_col_10[4]==0) { Bp5758dStart(BP5758D_ADDR_SETUP); Bp5758dWrite(BP5758D_DISABLE_OUTPUTS_ALL); Bp5758dStop(); Bp5758dStart(BP5758D_ADDR_SLEEP); Bp5758dStop(); bIsSleeping = true; return true; } if (bIsSleeping) { bIsSleeping = false; //No need to run it every time a val gets changed Bp5758dStart(BP5758D_ADDR_SETUP); //Sleep mode gets disabled too since bits 5:6 get set to 01 Bp5758dWrite(BP5758D_ENABLE_OUTPUTS_ALL); //Set all outputs to ON Bp5758dStop(); } // Even though we could address changing channels only, in practice we observed that the lightbulb always sets all channels. Bp5758dStart(BP5758D_ADDR_OUT1_GL); // Brigtness values are transmitted as two bytes. The light-bulb accepts a 10-bit integer (0-1023) as an input value. // The first 5bits of this input are transmitted in second byte, the second 5bits in the first byte. Bp5758dWrite((uint8_t)(cur_col_10[0] & 0x1F)); //Red Bp5758dWrite((uint8_t)(cur_col_10[0] >> 5)); Bp5758dWrite((uint8_t)(cur_col_10[1] & 0x1F)); //Green Bp5758dWrite((uint8_t)(cur_col_10[1] >> 5)); Bp5758dWrite((uint8_t)(cur_col_10[2] & 0x1F)); //Blue Bp5758dWrite((uint8_t)(cur_col_10[2] >> 5)); Bp5758dWrite((uint8_t)(cur_col_10[4] & 0x1F)); //Cold Bp5758dWrite((uint8_t)(cur_col_10[4] >> 5)); Bp5758dWrite((uint8_t)(cur_col_10[3] & 0x1F)); //Warm Bp5758dWrite((uint8_t)(cur_col_10[3] >> 5)); Bp5758dStop(); return true; } void Bp5758dModuleSelected(void) { if (PinUsed(GPIO_BP5758D_CLK) && PinUsed(GPIO_BP5758D_DAT)) { Bp5758d.clk = Pin(GPIO_BP5758D_CLK); Bp5758d.data = Pin(GPIO_BP5758D_DAT); // For it's init sequence, BP5758D just sets all fields Bp5758dInit(); Bp5758dStart(BP5758D_ADDR_SETUP); // Output enabled: enable all outputs since we're using a RGBCW light Bp5758dWrite(BP5758D_ENABLE_OUTPUTS_ALL); // Set currents for OUT1-OUT5 Bp5758dWrite(BP5758D_14MA); Bp5758dWrite(BP5758D_14MA); Bp5758dWrite(BP5758D_14MA); Bp5758dWrite(BP5758D_14MA); Bp5758dWrite(BP5758D_14MA); // Set grayscale levels ouf all outputs to 0 Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dWrite(0x00); Bp5758dStop(); TasmotaGlobal.light_type = LT_RGBWC; TasmotaGlobal.light_driver = XLGT_08; AddLog(LOG_LEVEL_DEBUG, PSTR("LGT: BP5758D Found")); } } /*********************************************************************************************\ * Interface \*********************************************************************************************/ bool Xlgt08(uint8_t function) { bool result = false; switch (function) { case FUNC_SET_CHANNELS: result = Bp5758dSetChannels(); break; case FUNC_MODULE_INIT: Bp5758dModuleSelected(); break; } return result; } #endif // USE_BP5758D #endif // USE_LIGHT