# LCD ## Overview The Liquid Crystal Display (LCD) driver performs operations such as powering on the LCD and initializing the internal registers of the driver integrated circuits (ICs). The display driver model developed based on the Hardware Driver Foundation [(HDF)](../driver/driver-hdf-overview.md) provides a basic framework for LCD driver development, improves driver development efficiency, and facilitates porting of the driver across OSs and chip platforms. The figure below shows the HDF-based display driver model. **Figure 1** HDF-based display driver model ![image](figures/architecture-of-the-display-driver-model.png "Display Driver Model") The display driver model consists of the display common driver layer, SoC adapter layer, and LCD panel driver layer. The HDF-based display driver model shields the differences between kernel forms through platform and OSAL APIs so the LCD driver can be easily ported between different OSs and chip platforms. The display driver model connects to the display common Hardware Abstraction Layer (HAL), supports the implementation of the Hardware Device Interface (HDI), and provides various driver capability interfaces for graphics services through the Display-HDI. - Display common driver layer: connects to the display common HAL through the IOService data channel provided by the HDF to receive and process various upper-layer calls in a centralized manner. - SoC adapter layer: decouples the display driver from the SoC driver, configures parameters related to the chip platform, and passes the calls from the platform driver layer to the LCD driver layer. - LCD panel driver layer: provides LCD-related APIs for sending the initialization sequence, powering on/off, and setting the backlight. The display driver model leverages the capabilities and APIs provided by the platform to simplify the display driver development and improve the efficiency. ## Available APIs The LCD interfaces include the Mobile Industry Processor Interface (MIPI) Display Serial Interface (DSI), Transistor-Transistor Logic (TTL) interface, and Low Voltage Differential Signaling (LVDS) interface. The MIPI DSI and TTL interfaces are commonly used. Here is a brief introduction to them. - MIPI DSI **Figure 2** MIPI DSI ![](figures/mipi-dsi.png "MIPI DSI") The DSI is defined by the MIPI Alliance for the displays used in mobile devices. The MIPI DSI is used to transmit image data, in compliance with the MIPI protocol. Generally, control information is sent to the peer IC in the form of MIPI packets over the MIPI DSI, without the need of additional peripheral interfaces. - TTL interface **Figure 3** TTL interface ![](figures/ttl-interface.png "ttl-interface") TTL level signals are generated by TTL devices, which are a major type of digital integrated circuits. TTL devices are manufactured using the bipolar process and feature high speed, low power consumption, and diversified types. The TTL interface is used to transmit data in parallel mode under control signals. It transmits data signals, clock signals, and control signals (such as line synchronization signals, frame synchronization signals, and data validity signals). For the LCD with the TTL, additional peripheral interfaces, such as the Serial Peripheral Interface (SPI) and Inter-Integrated Circuit (I2C), are required for the read and write of the internal registers. ## How to Develop The HDF-based display driver model provides a unified driver model for LCDs regardless of the OS (LiteOS or Linux OS) and chip platform (Hi35xx, Hi38xx, or V3S). The development procedure is as follows: 1. Add the device configuration related to the LCD driver. 2. Adapt the driver to the chip at the SoC adapter layer. 3. Add the LCD panel driver and register the panel driver functions in the driver entry function **Init**. The functions provide capabilities for: - Powering on/off the LCD device Based on the LCD hardware connection, use the GPIO APIs provided by the platform to perform operations on the LCD pins, such as the reset pin and IOVCC pin. For details about the power-on sequence, see the SPEC provided by the LCD supplier. - Sending the initialization sequence Based on the LCD hardware interfaces, use the I2C, SPI, and MIPI interfaces provided by the platform to download the LCD initialization sequence. For details, see the SPEC provided by the LCD supplier. 4. Implement other HDF APIs as required, for example, **Release()**. 5. Use the HDF to create other device nodes for implementing service logic or debugging as required. ## Development Example Add the device configuration. ``` /* Configuration of the devices related to the display driver */ display :: host { hostName = "display_host"; /* Configuration of the HDF display driver */ device_hdf_disp :: device { device0 :: deviceNode { policy = 2; priority = 200; permission = 0660; moduleName = "HDF_DISP"; serviceName = "hdf_disp"; } } /* Configuration of the driver device at the SoC adapter layer */ device_hi35xx_disp :: device { device0 :: deviceNode { policy = 0; priority = 199; moduleName = "HI351XX_DISP"; } } /* Configuration of the LCD driver */ device_lcd :: device { device0 :: deviceNode { policy = 0; priority = 100; preload = 0; moduleName = "LCD_Sample"; } device1 :: deviceNode { policy = 0; priority = 100; preload = 2; moduleName = "LCD_SampleXX"; } } } ``` Adapt the driver to the chip at the SoC adapter layer. The following example shows how to adapt the MIPI device to the Hi35xx series chips at the SoC adapter layer: ``` static int32_t MipiDsiInit(struct PanelInfo *info) { int32_t ret; struct DevHandle *mipiHandle = NULL; struct MipiCfg cfg; mipiHandle = MipiDsiOpen(0); if (mipiHandle == NULL) { HDF_LOGE("%s: MipiDsiOpen failure", __func__); return HDF_FAILURE; } cfg.lane = info->mipi.lane; cfg.mode = info->mipi.mode; cfg.format = info->mipi.format; cfg.burstMode = info->mipi.burstMode; cfg.timing.xPixels = info->width; cfg.timing.hsaPixels = info->hsw; cfg.timing.hbpPixels = info->hbp; cfg.timing.hlinePixels = info->width + info->hbp + info->hfp + info->hsw; cfg.timing.vsaLines = info->vsw; cfg.timing.vbpLines = info->vbp; cfg.timing.vfpLines = info->vfp; cfg.timing.ylines = info->height; /* 0 : no care */ cfg.timing.edpiCmdSize = 0; cfg.pixelClk = CalcPixelClk(info); cfg.phyDataRate = CalcDataRate(info); /* Configure the MIPI device. */ ret = MipiDsiSetCfg(mipiHandle, &cfg); if (ret != HDF_SUCCESS) { HDF_LOGE("%s:MipiDsiSetCfg failure", __func__); } MipiDsiClose(mipiHandle); HDF_LOGI("%s:pixelClk = %d, phyDataRate = %d\n", __func__, cfg.pixelClk, cfg.phyDataRate); return ret; } ``` Develop an LCD driver. The sample code is as follows: ``` #define RESET_GPIO 5 #define MIPI_DSI0 0 #define BLK_PWM1 1 #define PWM_MAX_PERIOD 100000 /* Set the backlight. */ #define MIN_LEVEL 0 #define MAX_LEVEL 255 #define DEFAULT_LEVEL 100 #define WIDTH 480 #define HEIGHT 960 #define HORIZONTAL_BACK_PORCH 20 #define HORIZONTAL_FRONT_PORCH 20 #define HORIZONTAL_SYNC_WIDTH 10 #define VERTICAL_BACK_PORCH 14 #define VERTICAL_FRONT_PORCH 16 #define VERTICAL_SYNC_WIDTH 2 #define FRAME_RATE 60 /* PanelInfo structure */ struct PanelInfo { uint32_t width; uint32_t height; uint32_t hbp; uint32_t hfp; uint32_t hsw; uint32_t vbp; uint32_t vfp; uint32_t vsw; uint32_t frameRate; enum LcdIntfType intfType; enum IntfSync intfSync; struct MipiDsiDesc mipi; struct BlkDesc blk; struct PwmCfg pwm; }; /* Initialization sequence of the LCD panel */ static uint8_t g_payLoad0[] = { 0xF0, 0x5A, 0x5A }; static uint8_t g_payLoad1[] = { 0xF1, 0xA5, 0xA5 }; static uint8_t g_payLoad2[] = { 0xB3, 0x03, 0x03, 0x03, 0x07, 0x05, 0x0D, 0x0F, 0x11, 0x13, 0x09, 0x0B }; static uint8_t g_payLoad3[] = { 0xB4, 0x03, 0x03, 0x03, 0x06, 0x04, 0x0C, 0x0E, 0x10, 0x12, 0x08, 0x0A }; static uint8_t g_payLoad4[] = { 0xB0, 0x54, 0x32, 0x23, 0x45, 0x44, 0x44, 0x44, 0x44, 0x60, 0x00, 0x60, 0x1C }; static uint8_t g_payLoad5[] = { 0xB1, 0x32, 0x84, 0x02, 0x87, 0x12, 0x00, 0x50, 0x1C }; static uint8_t g_payLoad6[] = { 0xB2, 0x73, 0x09, 0x08 }; static uint8_t g_payLoad7[] = { 0xB6, 0x5C, 0x5C, 0x05 }; static uint8_t g_payLoad8[] = { 0xB8, 0x23, 0x41, 0x32, 0x30, 0x03 }; static uint8_t g_payLoad9[] = { 0xBC, 0xD2, 0x0E, 0x63, 0x63, 0x5A, 0x32, 0x22, 0x14, 0x22, 0x03 }; static uint8_t g_payLoad10[] = { 0xb7, 0x41 }; static uint8_t g_payLoad11[] = { 0xC1, 0x0c, 0x10, 0x04, 0x0c, 0x10, 0x04 }; static uint8_t g_payLoad12[] = { 0xC2, 0x10, 0xE0 }; static uint8_t g_payLoad13[] = { 0xC3, 0x22, 0x11 }; static uint8_t g_payLoad14[] = { 0xD0, 0x07, 0xFF }; static uint8_t g_payLoad15[] = { 0xD2, 0x63, 0x0B, 0x08, 0x88 }; static uint8_t g_payLoad16[] = { 0xC6, 0x08, 0x15, 0xFF, 0x10, 0x16, 0x80, 0x60 }; static uint8_t g_payLoad17[] = { 0xc7, 0x04 }; static uint8_t g_payLoad18[] = { 0xC8, 0x7C, 0x50, 0x3B, 0x2C, 0x25, 0x16, 0x1C, 0x08, 0x27, 0x2B, 0x2F, 0x52, 0x43, 0x4C, 0x40, 0x3D, 0x30, 0x1E, 0x06, 0x7C, 0x50, 0x3B, 0x2C, 0x25, 0x16, 0x1C, 0x08, 0x27, 0x2B, 0x2F, 0x52, 0x43, 0x4C, 0x40, 0x3D, 0x30, 0x1E, 0x06 }; static uint8_t g_payLoad19[] = { 0x11 }; static uint8_t g_payLoad20[] = { 0x29 }; struct DsiCmdDesc g_OnCmd[] = { { 0x29, 0, sizeof(g_payLoad0), g_payLoad0 }, { 0x29, 0, sizeof(g_payLoad1), g_payLoad1 }, { 0x29, 0, sizeof(g_payLoad2), g_payLoad2 }, { 0x29, 0, sizeof(g_payLoad3), g_payLoad3 }, { 0x29, 0, sizeof(g_payLoad4), g_payLoad4 }, { 0x29, 0, sizeof(g_payLoad5), g_payLoad5 }, { 0x29, 0, sizeof(g_payLoad6), g_payLoad6 }, { 0x29, 0, sizeof(g_payLoad7), g_payLoad7 }, { 0x29, 0, sizeof(g_payLoad8), g_payLoad8 }, { 0x29, 0, sizeof(g_payLoad9), g_payLoad9 }, { 0x23, 0, sizeof(g_payLoad10), g_payLoad10 }, { 0x29, 0, sizeof(g_payLoad11), g_payLoad11 }, { 0x29, 0, sizeof(g_payLoad12), g_payLoad12 }, { 0x29, 0, sizeof(g_payLoad13), g_payLoad13 }, { 0x29, 0, sizeof(g_payLoad14), g_payLoad14 }, { 0x29, 0, sizeof(g_payLoad15), g_payLoad15 }, { 0x29, 0, sizeof(g_payLoad16), g_payLoad16 }, { 0x23, 0, sizeof(g_payLoad17), g_payLoad17 }, { 0x29, 1, sizeof(g_payLoad18), g_payLoad18 }, { 0x05, 120, sizeof(g_payLoad19), g_payLoad19 }, { 0x05, 120, sizeof(g_payLoad20), g_payLoad20 }, }; static DevHandle g_mipiHandle = NULL; static DevHandle g_pwmHandle = NULL; /* Set the status of the reset pin. */ static int32_t LcdResetOn(void) { int32_t ret; ret = GpioSetDir(RESET_GPIO, GPIO_DIR_OUT); if (ret != HDF_SUCCESS) { HDF_LOGE("GpioSetDir failure, ret:%d", ret); return HDF_FAILURE; } ret = GpioWrite(RESET_GPIO, GPIO_VAL_HIGH); if (ret != HDF_SUCCESS) { HDF_LOGE("GpioWrite failure, ret:%d", ret); return HDF_FAILURE; } /* Set the delay to 20 ms. */ OsalMSleep(20); return HDF_SUCCESS; } static int32_t SampleInit(void) { /* Open the MIPI DSI device handle. */ g_mipiHandle = MipiDsiOpen(MIPI_DSI0); if (g_mipiHandle == NULL) { HDF_LOGE("%s: MipiDsiOpen failure", __func__); return HDF_FAILURE; } return HDF_SUCCESS; } static int32_t SampleOn(void) { int32_t ret; /* Power on the LCD. */ ret = LcdResetOn(); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: LcdResetOn failure", __func__); return HDF_FAILURE; } if (g_mipiHandle == NULL) { HDF_LOGE("%s: g_mipiHandle is null", __func__); return HDF_FAILURE; } /* Send the initialization sequence via MIPI. */ int32_t count = sizeof(g_OnCmd) / sizeof(g_OnCmd[0]); int32_t i; for (i = 0; i < count; i++) { ret = MipiDsiTx(g_mipiHandle, &(g_OnCmd[i])); if (ret != HDF_SUCCESS) { HDF_LOGE("MipiDsiTx failure"); return HDF_FAILURE; } } /* Set MIPI to the high speed (HS) mode. */ MipiDsiSetHsMode(g_mipiHandle); return HDF_SUCCESS; } /* PanelInfo structure variables */ static struct PanelInfo g_panelInfo = { .width = WIDTH, /* width */ .height = HEIGHT, /* height */ .hbp = HORIZONTAL_BACK_PORCH, /* horizontal back porch */ .hfp = HORIZONTAL_FRONT_PORCH, /* horizontal front porch */ .hsw = HORIZONTAL_SYNC_WIDTH, /* horizontal sync width */ .vbp = VERTICAL_BACK_PORCH, /* vertical back porch */ .vfp = VERTICAL_FRONT_PORCH, /* vertical front porch */ .vsw = VERTICAL_SYNC_WIDTH, /* vertical sync width */ .frameRate = FRAME_RATE, /* frame rate */ .intfType = MIPI_DSI, /* panel interface type */ .intfSync = OUTPUT_USER, /* output timing type */ /* MIPI configuration */ .mipi = { DSI_2_LANES, DSI_VIDEO_MODE, VIDEO_BURST_MODE, FORMAT_RGB_24_BIT }, /* backlight config info */ .blk = { BLK_PWM, MIN_LEVEL, MAX_LEVEL, DEFAULT_LEVEL }, .pwm = { BLK_PWM1, PWM_MAX_PERIOD }, }; /* Basic APIs that need to be adapted for the chip driver */ static struct PanelData g_panelData = { .info = &g_panelInfo, .init = SampleInit, .on = SampleOn, .off = SampleOff, .setBacklight = SampleSetBacklight, }; /* Entry function of the chip driver */ int32_t SampleEntryInit(struct HdfDeviceObject *object) { HDF_LOGI("%s: enter", __func__); if (object == NULL) { HDF_LOGE("%s: param is null!", __func__); return HDF_FAILURE; } /* Register the device driver APIs with the platform driver. */ if (PanelDataRegister(&g_panelData) != HDF_SUCCESS) { HDF_LOGE("%s: PanelDataRegister error!", __func__); return HDF_FAILURE; } return HDF_SUCCESS; } struct HdfDriverEntry g_sampleDevEntry = { .moduleVersion = 1, .moduleName = "LCD_SAMPLE", .Init = SampleEntryInit, }; HDF_INIT(g_sampleDevEntry); ```