/* * SPDX-FileCopyrightText: 2023-2024 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "soc/soc_caps.h" #include "esp_check.h" #include "esp_lcd_mipi_dsi.h" #include "esp_clk_tree.h" #include "mipi_dsi_priv.h" static const char *TAG = "lcd.dsi.bus"; #define MIPI_DSI_DEFAULT_TIMEOUT_CLOCK_FREQ_MHZ 10 // TxClkEsc frequency must be configured between 2 and 20 MHz #define MIPI_DSI_DEFAULT_ESCAPE_CLOCK_FREQ_MHZ 10 esp_err_t esp_lcd_new_dsi_bus(const esp_lcd_dsi_bus_config_t *bus_config, esp_lcd_dsi_bus_handle_t *ret_bus) { esp_err_t ret = ESP_OK; ESP_RETURN_ON_FALSE(bus_config && ret_bus, ESP_ERR_INVALID_ARG, TAG, "invalid argument"); ESP_RETURN_ON_FALSE(bus_config->lane_bit_rate_mbps >= MIPI_DSI_LL_MIN_PHY_MBPS && bus_config->lane_bit_rate_mbps <= MIPI_DSI_LL_MAX_PHY_MBPS, ESP_ERR_INVALID_ARG, TAG, "invalid lane bit rate %"PRIu32, bus_config->lane_bit_rate_mbps); // we don't use an bus allocator here, because different DSI bus uses different PHY. // And each PHY has its own associated PINs, which is not changeable. // So user HAS TO specify the bus ID by themselves, according to their PCB design. int bus_id = bus_config->bus_id; ESP_RETURN_ON_FALSE(bus_id >= 0 && bus_id < MIPI_DSI_LL_NUM_BUS, ESP_ERR_INVALID_ARG, TAG, "invalid bus ID %d", bus_id); esp_lcd_dsi_bus_t *dsi_bus = heap_caps_calloc(1, sizeof(esp_lcd_dsi_bus_t), DSI_MEM_ALLOC_CAPS); ESP_RETURN_ON_FALSE(dsi_bus, ESP_ERR_NO_MEM, TAG, "no memory for DSI bus"); dsi_bus->bus_id = bus_id; // Enable the APB clock for accessing the DSI host and bridge registers DSI_RCC_ATOMIC() { mipi_dsi_ll_enable_bus_clock(bus_id, true); mipi_dsi_ll_reset_register(bus_id); } // if the clock source is not assigned, fallback to the default clock source mipi_dsi_phy_clock_source_t phy_clk_src = bus_config->phy_clk_src; if (phy_clk_src == 0) { phy_clk_src = MIPI_DSI_PHY_CLK_SRC_DEFAULT; } // enable the clock source for DSI PHY DSI_CLOCK_SRC_ATOMIC() { // set clock source for DSI PHY mipi_dsi_ll_set_phy_clock_source(bus_id, phy_clk_src); // the configuration clock is used for all modes except the shutdown mode mipi_dsi_ll_enable_phy_config_clock(bus_id, true); // enable the clock for generating the serial clock mipi_dsi_ll_enable_phy_reference_clock(bus_id, true); } // initialize HAL context mipi_dsi_hal_config_t hal_config = { .bus_id = bus_id, .lane_bit_rate_mbps = bus_config->lane_bit_rate_mbps, .num_data_lanes = bus_config->num_data_lanes, }; mipi_dsi_hal_init(&dsi_bus->hal, &hal_config); mipi_dsi_hal_context_t *hal = &dsi_bus->hal; // get the frequency of the PHY clock source uint32_t phy_clk_src_freq_hz = 0; ESP_GOTO_ON_ERROR(esp_clk_tree_src_get_freq_hz(phy_clk_src, ESP_CLK_TREE_SRC_FREQ_PRECISION_CACHED, &phy_clk_src_freq_hz), err, TAG, "get phy clock source frequency failed"); // configure the PHY PLL mipi_dsi_hal_configure_phy_pll(hal, phy_clk_src_freq_hz, bus_config->lane_bit_rate_mbps); // wait for PHY initialization done while (!mipi_dsi_phy_ll_is_pll_locked(hal->host)) { vTaskDelay(pdMS_TO_TICKS(1)); } while (!mipi_dsi_phy_ll_are_lanes_stopped(hal->host)) { vTaskDelay(pdMS_TO_TICKS(1)); } // initialize the DSI operation mode: command mode mipi_dsi_host_ll_enable_video_mode(hal->host, false); // place the clock lane in low power mode, we will switch to high speed mode later when DPI stream is ready mipi_dsi_host_ll_set_clock_lane_state(hal->host, MIPI_DSI_LL_CLOCK_LANE_STATE_LP); // Set the time that is required by the clock and data lanes to go from high-speed to low-power and from low-power to high-speed mipi_dsi_phy_ll_set_switch_time(hal->host, 50, 104, 46, 128); // enable CRC reception and ECC reception, error correction, and reporting mipi_dsi_host_ll_enable_rx_crc(hal->host, true); mipi_dsi_host_ll_enable_rx_ecc(hal->host, true); // enable sending the EoTp packet at the end of each transmission mipi_dsi_host_ll_enable_tx_eotp(hal->host, true, true); // Set the divider to get the Time Out clock, clock source is the high-speed byte clock mipi_dsi_host_ll_set_timeout_clock_division(hal->host, bus_config->lane_bit_rate_mbps / 8 / MIPI_DSI_DEFAULT_TIMEOUT_CLOCK_FREQ_MHZ); // Set the divider to get the TX Escape clock, clock source is the high-speed byte clock mipi_dsi_host_ll_set_escape_clock_division(hal->host, bus_config->lane_bit_rate_mbps / 8 / MIPI_DSI_DEFAULT_ESCAPE_CLOCK_FREQ_MHZ); // set the timeout intervals to zero, means to disable the timeout mechanism mipi_dsi_host_ll_set_timeout_count(hal->host, 0, 0, 0, 0, 0, 0, 0); // DSI host will wait indefinitely for a read response from the DSI device mipi_dsi_phy_ll_set_max_read_time(hal->host, 6000); // set how long the DSI host will wait before sending the next transmission mipi_dsi_phy_ll_set_stop_wait_time(hal->host, 0x3F); *ret_bus = dsi_bus; return ESP_OK; err: if (dsi_bus) { esp_lcd_del_dsi_bus(dsi_bus); } return ret; } esp_err_t esp_lcd_del_dsi_bus(esp_lcd_dsi_bus_handle_t bus) { ESP_RETURN_ON_FALSE(bus, ESP_ERR_INVALID_ARG, TAG, "invalid argument"); int bus_id = bus->bus_id; // disable the clock source for DSI PHY DSI_CLOCK_SRC_ATOMIC() { mipi_dsi_ll_enable_phy_reference_clock(bus_id, false); mipi_dsi_ll_enable_phy_config_clock(bus_id, false); } // disable the APB clock for accessing the DSI peripheral registers DSI_RCC_ATOMIC() { mipi_dsi_ll_enable_bus_clock(bus_id, false); } free(bus); return ESP_OK; }