#include "u8x8_nodemcu_hal.h" #include "platform.h" #include "driver/gpio.h" #include "driver/i2c.h" #include "driver/spi_master.h" #include "esp_rom_sys.h" #include "esp_heap_caps.h" #include uint8_t u8x8_gpio_and_delay_nodemcu(u8x8_t *u8x8, uint8_t msg, uint8_t arg_int, void *arg_ptr) { uint32_t temp; switch(msg) { case U8X8_MSG_GPIO_AND_DELAY_INIT: // called once during init phase of u8g2/u8x8 // can be used to setup pins for (int idx = 0; idx < U8X8_PIN_OUTPUT_CNT; idx++) { if (u8x8->pins[idx] != U8X8_PIN_NONE) { // configure pin as output gpio_config_t cfg; memset( (void *)&cfg, 0, sizeof( cfg ) ); cfg.pin_bit_mask = 1ULL << u8x8->pins[idx]; if (idx == U8X8_PIN_I2C_CLOCK || idx == U8X8_PIN_I2C_DATA) { cfg.mode = GPIO_MODE_OUTPUT_OD; cfg.pull_up_en = GPIO_PULLUP_ENABLE; } else { cfg.mode = GPIO_MODE_OUTPUT; cfg.pull_up_en = GPIO_PULLUP_DISABLE; } cfg.pull_down_en = GPIO_PULLDOWN_DISABLE; cfg.intr_type = GPIO_INTR_DISABLE; gpio_config( &cfg ); } } break; case U8X8_MSG_DELAY_NANO: // delay arg_int * 1 nano second esp_rom_delay_us( 1 ); break; case U8X8_MSG_DELAY_100NANO: // delay arg_int * 100 nano seconds temp = arg_int * 100; temp /= 1000; esp_rom_delay_us( temp > 0 ? temp : 1 ); break; case U8X8_MSG_DELAY_10MICRO: // delay arg_int * 10 micro seconds esp_rom_delay_us( arg_int * 10 ); break; case U8X8_MSG_DELAY_MILLI: // delay arg_int * 1 milli second esp_rom_delay_us( arg_int * 1000 ); break; case U8X8_MSG_DELAY_I2C: // arg_int is the I2C speed in 100KHz, e.g. 4 = 400 KHz temp = 5000 / arg_int; // arg_int=1: delay by 5us, arg_int = 4: delay by 1.25us temp /= 1000; esp_rom_delay_us( temp > 0 ? temp : 1 ); break; case U8X8_MSG_GPIO_D0: // D0 or SPI clock pin: Output level in arg_int //case U8X8_MSG_GPIO_SPI_CLOCK: break; case U8X8_MSG_GPIO_D1: // D1 or SPI data pin: Output level in arg_int //case U8X8_MSG_GPIO_SPI_DATA: break; case U8X8_MSG_GPIO_D2: // D2 pin: Output level in arg_int break; case U8X8_MSG_GPIO_D3: // D3 pin: Output level in arg_int break; case U8X8_MSG_GPIO_D4: // D4 pin: Output level in arg_int break; case U8X8_MSG_GPIO_D5: // D5 pin: Output level in arg_int break; case U8X8_MSG_GPIO_D6: // D6 pin: Output level in arg_int break; case U8X8_MSG_GPIO_D7: // D7 pin: Output level in arg_int break; case U8X8_MSG_GPIO_E: // E/WR pin: Output level in arg_int break; case U8X8_MSG_GPIO_CS: // CS (chip select) pin: Output level in arg_int gpio_set_level( u8x8_GetPinValue( u8x8, msg ), arg_int ); break; case U8X8_MSG_GPIO_DC: // DC (data/cmd, A0, register select) pin: Output level in arg_int gpio_set_level( u8x8_GetPinValue( u8x8, msg ), arg_int ); break; case U8X8_MSG_GPIO_RESET: // Reset pin: Output level in arg_int if (u8x8_GetPinValue( u8x8, msg ) != U8X8_PIN_NONE) gpio_set_level( u8x8_GetPinValue(u8x8, msg), arg_int ); break; case U8X8_MSG_GPIO_CS1: // CS1 (chip select) pin: Output level in arg_int break; case U8X8_MSG_GPIO_CS2: // CS2 (chip select) pin: Output level in arg_int break; case U8X8_MSG_GPIO_I2C_CLOCK: // arg_int=0: Output low at I2C clock pin // arg_int=1: Input dir with pullup high for I2C clock pin // for SW comm routine gpio_set_level( u8x8_GetPinValue( u8x8, msg ), arg_int ); break; case U8X8_MSG_GPIO_I2C_DATA: // arg_int=0: Output low at I2C data pin // arg_int=1: Input dir with pullup high for I2C data pin // for SW comm routine gpio_set_level( u8x8_GetPinValue( u8x8, msg ), arg_int ); break; case U8X8_MSG_GPIO_MENU_SELECT: case U8X8_MSG_GPIO_MENU_NEXT: case U8X8_MSG_GPIO_MENU_PREV: case U8X8_MSG_GPIO_MENU_HOME: u8x8_SetGPIOResult( u8x8, /* get menu select pin state */ 0 ); break; default: u8x8_SetGPIOResult( u8x8, 1 ); // default return value break; } return 1; } // static variables containing info about the i2c link // TODO: move to user space in u8x8_t once available typedef struct { uint8_t id; i2c_cmd_handle_t cmd; struct { uint8_t *data; size_t size, used; } buffer; } hal_i2c_t; uint8_t u8x8_byte_nodemcu_i2c(u8x8_t *u8x8, uint8_t msg, uint8_t arg_int, void *arg_ptr) { uint8_t *data; hal_i2c_t *hal = u8x8->user_ptr; switch(msg) { case U8X8_MSG_BYTE_SEND: if (hal->id == 0) { data = (uint8_t *)arg_ptr; while( arg_int > 0 ) { platform_i2c_send_byte( 0, *data, 0 ); data++; arg_int--; } } else { while (hal->buffer.size - hal->buffer.used < arg_int) { hal->buffer.size *= 2; if (!(hal->buffer.data = (uint8_t *)realloc( hal->buffer.data, hal->buffer.size ))) return 0; } memcpy( hal->buffer.data + hal->buffer.used, arg_ptr, arg_int ); hal->buffer.used += arg_int; } break; case U8X8_MSG_BYTE_INIT: { // the user pointer initially contains the i2c id int id = (int)hal; if (!(hal = malloc( sizeof ( hal_i2c_t ) ))) return 0; hal->id = id; u8x8->user_ptr = hal; } break; case U8X8_MSG_BYTE_SET_DC: break; case U8X8_MSG_BYTE_START_TRANSFER: if (hal->id == 0) { platform_i2c_send_start( 0 ); platform_i2c_send_address( 0, u8x8_GetI2CAddress(u8x8), PLATFORM_I2C_DIRECTION_TRANSMITTER, 0 ); } else { hal->buffer.size = 256; if (!(hal->buffer.data = (uint8_t *)malloc( hal->buffer.size ))) return 0; hal->buffer.used = 0; hal->cmd = i2c_cmd_link_create(); i2c_master_start( hal->cmd ); i2c_master_write_byte( hal->cmd, u8x8_GetI2CAddress(u8x8) << 1 | I2C_MASTER_WRITE, false ); } break; case U8X8_MSG_BYTE_END_TRANSFER: if (hal->id == 0) { platform_i2c_send_stop( 0 ); } else { if (hal->buffer.used > 0) i2c_master_write( hal->cmd, hal->buffer.data, hal->buffer.used, false ); i2c_master_stop( hal->cmd ); i2c_master_cmd_begin(hal->id-1, hal->cmd, portMAX_DELAY ); if (hal->buffer.data) free( hal->buffer.data ); i2c_cmd_link_delete( hal->cmd ); } break; default: return 0; } return 1; } // static variables containing info about the spi link // TODO: move to user space in u8x8_t once available typedef struct { uint8_t host; spi_device_handle_t device; uint8_t last_dc; struct { uint8_t *data; size_t size, used; } buffer; } hal_spi_t; static void flush_buffer_spi( hal_spi_t *hal ) { if (hal->buffer.used > 0) { spi_transaction_t trans; memset( &trans, 0, sizeof( trans ) ); trans.length = hal->buffer.used * 8; trans.tx_buffer = hal->buffer.data; spi_device_transmit( hal->device, &trans ); hal->buffer.used = 0; } } uint8_t u8x8_byte_nodemcu_spi(u8x8_t *u8x8, uint8_t msg, uint8_t arg_int, void *arg_ptr) { hal_spi_t *hal = u8x8->user_ptr; switch(msg) { case U8X8_MSG_BYTE_INIT: { /* disable chipselect */ u8x8_gpio_SetCS( u8x8, u8x8->display_info->chip_disable_level ); // the user pointer initially contains the spi host id int host = (int)hal; if (!(hal = malloc( sizeof ( hal_spi_t ) ))) return 0; hal->host = host; u8x8->user_ptr = hal; // set up the spi device spi_device_interface_config_t config; memset( &config, 0, sizeof( config ) ); config.spics_io_num = -1; // CS is controlled by u8x8 gpio mechanism config.mode = u8x8_GetSPIClockPhase( u8x8 ) | (u8x8_GetSPIClockPolarity( u8x8 ) << 1); config.clock_speed_hz = u8x8->display_info->sck_clock_hz; config.queue_size = 1; spi_bus_add_device( hal->host, &config, &(hal->device) ); hal->last_dc = 0; } break; case U8X8_MSG_BYTE_SET_DC: if (hal->last_dc != arg_int) flush_buffer_spi( hal ); u8x8_gpio_SetDC( u8x8, arg_int ); hal->last_dc = arg_int; break; case U8X8_MSG_BYTE_START_TRANSFER: hal->buffer.size = 256; if (!(hal->buffer.data = (uint8_t *)heap_caps_malloc( hal->buffer.size, MALLOC_CAP_DMA ))) return 0; hal->buffer.used = 0; u8x8_gpio_SetCS( u8x8, u8x8->display_info->chip_enable_level ); break; case U8X8_MSG_BYTE_SEND: while (hal->buffer.size - hal->buffer.used < arg_int) { hal->buffer.size *= 2; uint8_t *tmp; if (!(tmp = (uint8_t *)heap_caps_malloc( hal->buffer.size, MALLOC_CAP_DMA ))) { heap_caps_free( hal->buffer.data ); hal->buffer.data = NULL; return 0; } memcpy( tmp, hal->buffer.data, hal->buffer.used ); heap_caps_free( hal->buffer.data ); hal->buffer.data = tmp; } memcpy( hal->buffer.data + hal->buffer.used, arg_ptr, arg_int ); hal->buffer.used += arg_int; break; case U8X8_MSG_BYTE_END_TRANSFER: flush_buffer_spi( hal ); u8x8_gpio_SetCS( u8x8, u8x8->display_info->chip_disable_level ); if (hal->buffer.data) heap_caps_free( hal->buffer.data ); break; default: return 0; } return 1; }