/* MIT License Copyright (c) 2018-2019, Alexey Dynda Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "oled_ssd1351.h" #include "lcd_common.h" #include "ssd1351_commands.h" #include "intf/ssd1306_interface.h" #include "intf/spi/ssd1306_spi.h" #include "ssd1306_hal/io.h" #include "nano_gfx_types.h" #ifdef SDL_EMULATION #include "sdl_core.h" #endif #define CMD_ARG 0xFF extern uint16_t ssd1306_color; extern uint32_t s_ssd1306_spi_clock; static const PROGMEM uint8_t s_oled128x128_initData[] = { #ifdef SDL_EMULATION SDL_LCD_SSD1351, 0x00, #endif SSD1351_UNLOCK, CMD_ARG, 0x12, SSD1351_UNLOCK, CMD_ARG, 0xB1, SSD1351_SLEEP_ON, SSD1351_CLOCKDIV, CMD_ARG, 0xF1, // 7:4 = Oscillator Frequency, 3:0 = CLK Div Ratio (A[3:0]+1 = 1..16) SSD1351_SETMULTIPLEX, CMD_ARG, 127, // Reset to default MUX. See datasheet SSD1351_SEGREMAP, CMD_ARG, 0B00110101, // 16-bit rgb color mode SSD1351_SETSTARTLINE, CMD_ARG, 0x00, // First line to start scanning from SSD1351_SETDISPLAYOFFSET, CMD_ARG, 0x00, // Set display offset SSD1351_SETGPIO, CMD_ARG, 0x00, // GPIO OFF SSD1351_SETFUNCTION, CMD_ARG, 0x01, SSD1351_SETPRECHARGE, CMD_ARG, 0x32, // Phase 1 and Phase 2 periods SSD1351_VCOMH, CMD_ARG, 0x05, // SSD1351_PRECHARGELEVEL, CMD_ARG, 0x17, SSD1351_NORMALDISPLAY, SSD1351_CONTRAST, CMD_ARG, 0xC8, // RED CMD_ARG, 0x80, // GREEN CMD_ARG, 0xC8, // BLUE SSD1351_MASTERCURRENT, CMD_ARG, 0x0F, // SSD1351_EXTVSL, CMD_ARG, 0xA0, CMD_ARG, 0xB5, CMD_ARG, 0x55, SSD1351_PRECHARGESECOND, CMD_ARG, 0x01, // SSD1351_SLEEP_OFF, // Disable power-safe mode SSD1351_NORMALDISPLAY, }; static uint8_t s_column; static uint8_t s_page; static void ssd1351_setBlock(lcduint_t x, lcduint_t y, lcduint_t w) { uint8_t rx = w ? (x + w - 1) : (ssd1306_lcd.width - 1); s_column = x; s_page = y; ssd1306_intf.start(); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1351_COLUMNADDR); ssd1306_spiDataMode(1); // According to datasheet all args must be passed in data mode ssd1306_intf.send(x); ssd1306_intf.send(rx < ssd1306_lcd.width ? rx : (ssd1306_lcd.width - 1)); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1351_ROWADDR); ssd1306_spiDataMode(1); // According to datasheet all args must be passed in data mode ssd1306_intf.send(y<<3); ssd1306_intf.send(((y<<3) + 7) < ssd1306_lcd.height ? ((y<<3) + 7) : (ssd1306_lcd.height - 1)); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1331_WRITEDATA); ssd1306_spiDataMode(1); } static void ssd1351_setBlock2(lcduint_t x, lcduint_t y, lcduint_t w) { uint8_t rx = w ? (x + w - 1) : (ssd1306_lcd.width - 1); ssd1306_intf.start(); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1351_COLUMNADDR); ssd1306_spiDataMode(1); // According to datasheet all args must be passed in data mode ssd1306_intf.send(x); ssd1306_intf.send(rx < ssd1306_lcd.width ? rx : (ssd1306_lcd.width - 1)); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1351_ROWADDR); ssd1306_spiDataMode(1); // According to datasheet all args must be passed in data mode ssd1306_intf.send(y); ssd1306_intf.send(ssd1306_lcd.height - 1); ssd1306_spiDataMode(0); ssd1306_intf.send(SSD1331_WRITEDATA); ssd1306_spiDataMode(1); } static void ssd1351_nextPage(void) { ssd1306_intf.stop(); ssd1351_setBlock(s_column,s_page+1,0); } static void ssd1351_nextPage2(void) { } void ssd1351_setMode(lcd_mode_t mode) { ssd1306_intf.start(); ssd1306_spiDataMode(0); ssd1306_intf.send( SSD1351_SEGREMAP ); ssd1306_spiDataMode(1); ssd1306_intf.send( 0B00110100 | mode ); ssd1306_intf.stop(); if (mode == LCD_MODE_SSD1306_COMPAT) { ssd1306_lcd.set_block = ssd1351_setBlock; ssd1306_lcd.next_page = ssd1351_nextPage; } else if (mode == LCD_MODE_NORMAL ) { ssd1306_lcd.set_block = ssd1351_setBlock2; ssd1306_lcd.next_page = ssd1351_nextPage2; } } static void ssd1351_sendPixels(uint8_t data) { for (uint8_t i=8; i>0; i--) { if ( data & 0x01 ) { ssd1306_intf.send( (uint8_t)(ssd1306_color>>8) ); ssd1306_intf.send( (uint8_t)(ssd1306_color) ); } else { ssd1306_intf.send( 0B00000000 ); ssd1306_intf.send( 0B00000000 ); } data >>= 1; } } static void ssd1351_sendPixelsBuffer(const uint8_t *buffer, uint16_t len) { while(len--) { ssd1351_sendPixels(*buffer); buffer++; } } static void ssd1351_sendPixel8(uint8_t data) { uint16_t color = RGB8_TO_RGB16(data); ssd1306_intf.send( color >> 8 ); ssd1306_intf.send( color & 0xFF ); } static void ssd1351_sendPixel16(uint16_t color) { ssd1306_intf.send( color >> 8 ); ssd1306_intf.send( color & 0xFF ); } void ssd1351_128x128_init() { ssd1306_lcd.type = LCD_TYPE_SSD1331; ssd1306_lcd.height = 128; ssd1306_lcd.width = 128; ssd1306_lcd.set_block = ssd1351_setBlock; ssd1306_lcd.next_page = ssd1351_nextPage; ssd1306_lcd.send_pixels1 = ssd1351_sendPixels; ssd1306_lcd.send_pixels_buffer1 = ssd1351_sendPixelsBuffer; ssd1306_lcd.send_pixels8 = ssd1351_sendPixel8; ssd1306_lcd.send_pixels16 = ssd1351_sendPixel16; ssd1306_lcd.set_mode = ssd1351_setMode; ssd1306_intf.start(); ssd1306_spiDataMode(0); for( uint8_t i=0; i=0) { ssd1306_resetController( rstPin, 20 ); } /* ssd1351 cannot work faster than at 4MHz per datasheet */ s_ssd1306_spi_clock = 4400000; ssd1306_spiInit(cesPin, dcPin); ssd1351_128x128_init(); }