/* * Copyright (c) 2020 NXP * Copyright (c) 2020 Mark Olsson * Copyright (c) 2020 Teslabs Engineering S.L. * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT goodix_gt911 #include #include #include #include #include LOG_MODULE_REGISTER(gt911, CONFIG_INPUT_LOG_LEVEL); /* GT911 used registers */ #define DEVICE_ID BSWAP_16(0x8140U) #define REG_STATUS BSWAP_16(0x814EU) #define REG_FIRST_POINT BSWAP_16(0x814FU) /* REG_TD_STATUS: Touch points. */ #define TOUCH_POINTS_MSK 0x0FU /* REG_TD_STATUS: Pressed. */ #define TOUCH_STATUS_MSK (1 << 7U) /* The GT911's config */ #define GT911_CONFIG_REG BSWAP_16(0x8047U) #define REG_CONFIG_VERSION GT911_CONFIG_REG #define REG_CONFIG_SIZE (186U) #define GT911_PRODUCT_ID (0x00313139U) /** GT911 configuration (DT). */ struct gt911_config { /** I2C bus. */ struct i2c_dt_spec bus; struct gpio_dt_spec rst_gpio; /** Interrupt GPIO information. */ struct gpio_dt_spec int_gpio; /* Alternate fallback I2C address */ uint8_t alt_addr; }; /** GT911 data. */ struct gt911_data { /** Device pointer. */ const struct device *dev; /** Work queue (for deferred read). */ struct k_work work; /** Actual device I2C address */ uint8_t actual_address; #ifdef CONFIG_INPUT_GT911_INTERRUPT /** Interrupt GPIO callback. */ struct gpio_callback int_gpio_cb; #else /** Timer (polling mode). */ struct k_timer timer; #endif }; /** gt911 point reg */ struct gt911_point_reg_t { uint8_t id; /*!< Track ID. */ uint8_t lowX; /*!< Low byte of x coordinate. */ uint8_t highX; /*!< High byte of x coordinate. */ uint8_t lowY; /*!< Low byte of y coordinate. */ uint8_t highY; /*!< High byte of x coordinate. */ uint8_t lowSize; /*!< Low byte of point size. */ uint8_t highSize; /*!< High byte of point size. */ uint8_t reserved; /*!< Reserved. */ }; /* * Device-specific wrappers around i2c_write_dt and i2c_write_read_dt. * These wrappers handle the case where the GT911 did not accept the requested * I2C address, and the alternate I2C address is used. */ static int gt911_i2c_write(const struct device *dev, const uint8_t *buf, uint32_t num_bytes) { const struct gt911_config *config = dev->config; struct gt911_data *data = dev->data; return i2c_write(config->bus.bus, buf, num_bytes, data->actual_address); } static int gt911_i2c_write_read(const struct device *dev, const void *write_buf, size_t num_write, void *read_buf, size_t num_read) { const struct gt911_config *config = dev->config; struct gt911_data *data = dev->data; return i2c_write_read(config->bus.bus, data->actual_address, write_buf, num_write, read_buf, num_read); } static int gt911_process(const struct device *dev) { int r; uint16_t reg_addr; uint8_t status; uint8_t points; struct gt911_point_reg_t pointRegs; uint16_t row, col; bool pressed; /* obtain number of touch points (NOTE: multi-touch ignored) */ reg_addr = REG_STATUS; r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), &status, sizeof(status)); if (r < 0) { return r; } points = status & TOUCH_POINTS_MSK; if (points != 0U && points != 1U && (0 != (status & TOUCH_STATUS_MSK))) { points = 1; } if (!(status & TOUCH_STATUS_MSK)) { /* Status bit not set, ignore this event */ return 0; } /* need to clear the status */ uint8_t clear_buffer[3] = {(uint8_t)REG_STATUS, (uint8_t)(REG_STATUS >> 8), 0}; r = gt911_i2c_write(dev, clear_buffer, sizeof(clear_buffer)); if (r < 0) { return r; } /* obtain first point X, Y coordinates and event from: * REG_P1_XH, REG_P1_XL, REG_P1_YH, REG_P1_YL. */ reg_addr = REG_FIRST_POINT; r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), &pointRegs, sizeof(pointRegs)); if (r < 0) { return r; } pressed = (points == 1); row = ((pointRegs.highY) << 8U) | pointRegs.lowY; col = ((pointRegs.highX) << 8U) | pointRegs.lowX; LOG_DBG("pressed: %d, row: %d, col: %d", pressed, row, col); if (pressed) { input_report_abs(dev, INPUT_ABS_X, col, false, K_FOREVER); input_report_abs(dev, INPUT_ABS_Y, row, false, K_FOREVER); input_report_key(dev, INPUT_BTN_TOUCH, 1, true, K_FOREVER); } else { input_report_key(dev, INPUT_BTN_TOUCH, 0, true, K_FOREVER); } return 0; } static void gt911_work_handler(struct k_work *work) { struct gt911_data *data = CONTAINER_OF(work, struct gt911_data, work); gt911_process(data->dev); } #ifdef CONFIG_INPUT_GT911_INTERRUPT static void gt911_isr_handler(const struct device *dev, struct gpio_callback *cb, uint32_t pins) { struct gt911_data *data = CONTAINER_OF(cb, struct gt911_data, int_gpio_cb); k_work_submit(&data->work); } #else static void gt911_timer_handler(struct k_timer *timer) { struct gt911_data *data = CONTAINER_OF(timer, struct gt911_data, timer); k_work_submit(&data->work); } #endif static uint8_t gt911_get_firmware_checksum(const uint8_t *firmware) { uint8_t sum = 0; uint16_t i = 0; for (i = 0; i < REG_CONFIG_SIZE - 2U; i++) { sum += (*firmware); firmware++; } return (~sum + 1U); } static bool gt911_verify_firmware(const uint8_t *firmware) { return ((firmware[REG_CONFIG_VERSION - GT911_CONFIG_REG] != 0U) && (gt911_get_firmware_checksum(firmware) == firmware[REG_CONFIG_SIZE - 2U])); } static int gt911_init(const struct device *dev) { const struct gt911_config *config = dev->config; struct gt911_data *data = dev->data; if (!i2c_is_ready_dt(&config->bus)) { LOG_ERR("I2C controller device not ready"); return -ENODEV; } data->dev = dev; data->actual_address = config->bus.addr; k_work_init(&data->work, gt911_work_handler); int r; if (!gpio_is_ready_dt(&config->int_gpio)) { LOG_ERR("Interrupt GPIO controller device not ready"); return -ENODEV; } if (config->rst_gpio.port != NULL) { if (!gpio_is_ready_dt(&config->rst_gpio)) { LOG_ERR("Reset GPIO controller device not ready"); return -ENODEV; } r = gpio_pin_configure_dt(&config->rst_gpio, GPIO_OUTPUT_ACTIVE); if (r < 0) { LOG_ERR("Could not configure reset GPIO pin"); return r; } } if (config->alt_addr == 0x0) { /* * We need to configure the int-pin to 0, in order to enter the * AddressMode0. Keeping the INT pin low during the reset sequence * should result in the device selecting an I2C address of 0x5D. * Note we skip this step if an alternate I2C address is set, * and fall through to probing for the actual address. */ r = gpio_pin_configure_dt(&config->int_gpio, GPIO_OUTPUT_INACTIVE); if (r < 0) { LOG_ERR("Could not configure int GPIO pin"); return r; } } /* Delay at least 10 ms after power on before we configure gt911 */ k_sleep(K_MSEC(20)); if (config->rst_gpio.port != NULL) { /* reset the device and confgiure the addr mode0 */ gpio_pin_set_dt(&config->rst_gpio, 1); /* hold down at least 1us, 1ms here */ k_sleep(K_MSEC(1)); gpio_pin_set_dt(&config->rst_gpio, 0); /* hold down at least 5ms. This is the point the INT pin must be low. */ k_sleep(K_MSEC(5)); } /* hold down 50ms to make sure the address available */ k_sleep(K_MSEC(50)); r = gpio_pin_configure_dt(&config->int_gpio, GPIO_INPUT); if (r < 0) { LOG_ERR("Could not configure interrupt GPIO pin"); return r; } #ifdef CONFIG_INPUT_GT911_INTERRUPT r = gpio_pin_interrupt_configure_dt(&config->int_gpio, GPIO_INT_EDGE_TO_ACTIVE); if (r < 0) { LOG_ERR("Could not configure interrupt GPIO interrupt."); return r; } gpio_init_callback(&data->int_gpio_cb, gt911_isr_handler, BIT(config->int_gpio.pin)); #else k_timer_init(&data->timer, gt911_timer_handler, NULL); #endif /* check the Device ID first: '911' */ uint32_t reg_id = 0; uint16_t reg_addr = DEVICE_ID; if (config->alt_addr != 0x0) { /* * The level of the INT pin during reset is used by the GT911 * to select the I2C address mode. If an alternate I2C address * is set, we should probe the GT911 to determine which address * it actually selected. This is useful for boards that do not * route the INT pin, or can only read it as an input (IE when * using a level shifter). */ r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), ®_id, sizeof(reg_id)); if (r < 0) { /* Try alternate address */ data->actual_address = config->alt_addr; r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), ®_id, sizeof(reg_id)); LOG_INF("Device did not accept I2C address, " "updated to 0x%02X", data->actual_address); } } else { r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), ®_id, sizeof(reg_id)); } if (r < 0) { LOG_ERR("Device did not respond to I2C request"); return r; } if (reg_id != GT911_PRODUCT_ID) { LOG_ERR("The Device ID is not correct"); return -ENODEV; } /* need to setup the firmware first: read and write */ uint8_t gt911Config[REG_CONFIG_SIZE + 2] = { (uint8_t)GT911_CONFIG_REG, (uint8_t)(GT911_CONFIG_REG >> 8) }; reg_addr = GT911_CONFIG_REG; r = gt911_i2c_write_read(dev, ®_addr, sizeof(reg_addr), gt911Config + 2, REG_CONFIG_SIZE); if (r < 0) { return r; } if (!gt911_verify_firmware(gt911Config + 2)) { return -ENODEV; } gt911Config[REG_CONFIG_SIZE] = gt911_get_firmware_checksum(gt911Config + 2); gt911Config[REG_CONFIG_SIZE + 1] = 1; r = gt911_i2c_write(dev, gt911Config, sizeof(gt911Config)); if (r < 0) { return r; } #ifdef CONFIG_INPUT_GT911_INTERRUPT r = gpio_add_callback(config->int_gpio.port, &data->int_gpio_cb); if (r < 0) { LOG_ERR("Could not set gpio callback"); return r; } #else k_timer_start(&data->timer, K_MSEC(CONFIG_INPUT_GT911_PERIOD_MS), K_MSEC(CONFIG_INPUT_GT911_PERIOD_MS)); #endif return 0; } #define GT911_INIT(index) \ static const struct gt911_config gt911_config_##index = { \ .bus = I2C_DT_SPEC_INST_GET(index), \ .rst_gpio = GPIO_DT_SPEC_INST_GET_OR(index, reset_gpios, {0}), \ .int_gpio = GPIO_DT_SPEC_INST_GET(index, irq_gpios), \ .alt_addr = DT_INST_PROP_OR(index, alt_addr, 0), \ }; \ static struct gt911_data gt911_data_##index; \ DEVICE_DT_INST_DEFINE(index, gt911_init, NULL, \ >911_data_##index, >911_config_##index, \ POST_KERNEL, CONFIG_INPUT_INIT_PRIORITY, \ NULL); DT_INST_FOREACH_STATUS_OKAY(GT911_INIT)