NerdNos-Firmware/Lib/TFT_eSPI/Processors/TFT_eSPI_ESP8266.h

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//////////////////////////////////////////////////////
// TFT_eSPI driver functions for ESP8266 processors //
//////////////////////////////////////////////////////
#ifndef _TFT_eSPI_ESP8266H_
#define _TFT_eSPI_ESP8266H_
// Processor ID reported by getSetup()
#define PROCESSOR_ID 0x8266
// Include processor specific header
// None
// Processor specific code used by SPI bus transaction startWrite and endWrite functions
#define SET_BUS_WRITE_MODE SPI1U=SPI1U_WRITE
#define SET_BUS_READ_MODE SPI1U=SPI1U_READ
// Code to check if DMA is busy, used by SPI bus transaction transaction and endWrite functions
#define DMA_BUSY_CHECK // DMA not available, leave blank
// Initialise processor specific SPI functions, used by init()
#if (!defined (SUPPORT_TRANSACTIONS) && defined (ARDUINO_ARCH_ESP8266))
#define INIT_TFT_DATA_BUS \
spi.setBitOrder(MSBFIRST); \
spi.setDataMode(TFT_SPI_MODE); \
spi.setFrequency(SPI_FREQUENCY);
#else
#define INIT_TFT_DATA_BUS
#endif
// If smooth fonts are enabled the filing system may need to be loaded
#ifdef SMOOTH_FONT
// Call up the SPIFFS FLASH filing system for the anti-aliased fonts
#define FS_NO_GLOBALS
#include <FS.h>
#define FONT_FS_AVAILABLE
#endif
// Do not allow parallel mode for ESP8266
#ifdef ESP32_PARALLEL
#undef ESP32_PARALLEL
#endif
#ifdef TFT_PARALLEL_8_BIT
#undef TFT_PARALLEL_8_BIT
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Define the DC (TFT Data/Command or Register Select (RS))pin drive code
////////////////////////////////////////////////////////////////////////////////////////
#ifndef TFT_DC
#define DC_C // No macro allocated so it generates no code
#define DC_D // No macro allocated so it generates no code
#else
#if (TFT_DC == 16)
#define DC_C digitalWrite(TFT_DC, LOW)
#define DC_D digitalWrite(TFT_DC, HIGH)
#else
#define DC_C GPOC=dcpinmask
#define DC_D GPOS=dcpinmask
#endif
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Define the CS (TFT chip select) pin drive code
////////////////////////////////////////////////////////////////////////////////////////
#ifndef TFT_CS
#define CS_L // No macro allocated so it generates no code
#define CS_H // No macro allocated so it generates no code
#else
#if (TFT_CS == 16)
#define CS_L digitalWrite(TFT_CS, LOW)
#define CS_H digitalWrite(TFT_CS, HIGH)
#else
#define CS_L GPOC=cspinmask
#define CS_H GPOS=cspinmask
#endif
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Define the WR (TFT Write) pin drive code
////////////////////////////////////////////////////////////////////////////////////////
#ifdef TFT_WR
#define WR_L GPOC=wrpinmask
#define WR_H GPOS=wrpinmask
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Define the touch screen chip select pin drive code
////////////////////////////////////////////////////////////////////////////////////////
#ifndef TOUCH_CS
#define T_CS_L // No macro allocated so it generates no code
#define T_CS_H // No macro allocated so it generates no code
#else
#define T_CS_L digitalWrite(TOUCH_CS, LOW)
#define T_CS_H digitalWrite(TOUCH_CS, HIGH)
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Make sure TFT_MISO is defined if not used to avoid an error message
////////////////////////////////////////////////////////////////////////////////////////
#ifndef TFT_MISO
#define TFT_MISO -1
#endif
////////////////////////////////////////////////////////////////////////////////////////
// ESP8266 specific SPI macros
////////////////////////////////////////////////////////////////////////////////////////
#if defined (TFT_SPI_OVERLAP)
#undef TFT_CS
#define SPI1U_WRITE (SPIUMOSI | SPIUSSE | SPIUCSSETUP | SPIUCSHOLD)
#define SPI1U_READ (SPIUMOSI | SPIUSSE | SPIUCSSETUP | SPIUCSHOLD | SPIUDUPLEX)
#else
#define SPI1U_WRITE (SPIUMOSI | SPIUSSE)
#define SPI1U_READ (SPIUMOSI | SPIUSSE | SPIUDUPLEX)
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Macros to write commands/pixel colour data to a SPI ILI948x TFT
////////////////////////////////////////////////////////////////////////////////////////
#if defined (SPI_18BIT_DRIVER) // SPI 18 bit colour
// Write 8 bits to TFT
#define tft_Write_8(C) spi.transfer(C)
// Convert 16 bit colour to 18 bit and write in 3 bytes
#define tft_Write_16(C) spi.transfer(((C) & 0xF800)>>8); \
spi.transfer(((C) & 0x07E0)>>3); \
spi.transfer(((C) & 0x001F)<<3)
// Convert swapped byte 16 bit colour to 18 bit and write in 3 bytes
#define tft_Write_16S(C) spi.transfer((C) & 0xF8); \
spi.transfer(((C) & 0xE000)>>11 | ((C) & 0x07)<<5); \
spi.transfer(((C) & 0x1F00)>>5)
// Write 32 bits to TFT
#define tft_Write_32(C) spi.write32(C)
// Write two address coordinates
#define tft_Write_32C(C,D) spi.write32((C)<<16 | (D))
// Write same value twice
#define tft_Write_32D(C) spi.write32((C)<<16 | (C))
////////////////////////////////////////////////////////////////////////////////////////
// Macros to write commands/pixel colour data to an Raspberry Pi TFT
////////////////////////////////////////////////////////////////////////////////////////
#elif defined (RPI_DISPLAY_TYPE)
// Command is 16 bits
#define CMD_BITS 16
// ESP8266 low level SPI writes for 8, 16 and 32 bit values
// to avoid the function call overhead
#define TFT_WRITE_BITS(D, B) \
SPI1U1 = ((B-1) << SPILMOSI); \
SPI1W0 = D; \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {}
#define tft_Write_8(C) TFT_WRITE_BITS((uint16_t)(C)<<8, CMD_BITS)
#define tft_Write_16(C) TFT_WRITE_BITS((C)>>8 | (C)<<8, 16)
#define tft_Write_16S(C) TFT_WRITE_BITS(C, 16)
#define tft_Write_32(C) TFT_WRITE_BITS(C, 32)
#define tft_Write_32C(C,D) SPI1U1 = ((64-1) << SPILMOSI); \
SPI1W0 = ((C)<<24) | (C); \
SPI1W1 = ((D)<<24) | (D); \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_32D(C) tft_Write_32C(C,C)
////////////////////////////////////////////////////////////////////////////////////////
// Macros for all other SPI displays
////////////////////////////////////////////////////////////////////////////////////////
#else
// Command is 8 bits
#define CMD_BITS 8
#define tft_Write_8(C) \
SPI1U1 = ((CMD_BITS-1) << SPILMOSI) | ((CMD_BITS-1) << SPILMISO); \
SPI1W0 = (C)<<(CMD_BITS - 8); \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_16(C) \
SPI1U1 = (15 << SPILMOSI) | (15 << SPILMISO); \
SPI1W0 = ((C)<<8 | (C)>>8); \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_16N(C) \
SPI1U1 = (15 << SPILMOSI) | (15 << SPILMISO); \
SPI1W0 = ((C)<<8 | (C)>>8); \
SPI1CMD |= SPIBUSY
#define tft_Write_16S(C) \
SPI1U1 = (15 << SPILMOSI) | (15 << SPILMISO); \
SPI1W0 = C; \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_32(C) \
SPI1U1 = (31 << SPILMOSI) | (31 << SPILMISO); \
SPI1W0 = C; \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_32C(C,D) \
SPI1U1 = (31 << SPILMOSI) | (31 << SPILMISO); \
SPI1W0 = ((D)>>8 | (D)<<8)<<16 | ((C)>>8 | (C)<<8); \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#define tft_Write_32D(C) \
SPI1U1 = (31 << SPILMOSI) | (31 << SPILMISO); \
SPI1W0 = ((C)>>8 | (C)<<8)<<16 | ((C)>>8 | (C)<<8); \
SPI1CMD |= SPIBUSY; \
while(SPI1CMD & SPIBUSY) {;}
#endif
#ifndef tft_Write_16N
#define tft_Write_16N tft_Write_16
#endif
////////////////////////////////////////////////////////////////////////////////////////
// Macros to read from display using SPI or software SPI
////////////////////////////////////////////////////////////////////////////////////////
#if defined (TFT_SDA_READ)
// Use a bit banged function call for ESP8266 and bi-directional SDA pin
#define TFT_eSPI_ENABLE_8_BIT_READ // Enable tft_Read_8(void);
#define SCLK_L GPOC=sclkpinmask
#define SCLK_H GPOS=sclkpinmask
#else
// Use a SPI read transfer
#define tft_Read_8() spi.transfer(0)
#endif
// Concatenate a byte sequence A,B,C,D to CDAB, P is a uint8_t pointer
#define DAT8TO32(P) ( (uint32_t)P[0]<<8 | P[1] | P[2]<<24 | P[3]<<16 )
#endif // Header end