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LCD(Liquid Crystal Display)显示器的驱动,通过对显示器上电、初始化显示器驱动IC(Integrated Circuit)内部寄存器等操作,使其可以正常工作。
基于HDF(Hardware Driver Foundation)驱动框架构建的Display驱动模型,为LCD器件驱动开发提供了基础驱动框架,提升驱动开发效率。同时,便于开发的器件驱动实现跨OS、跨芯片平台迁移。基于HDF驱动框架的Display驱动模型如下所示。
图1 基于HDF驱动框架的Display驱动模型
Display驱动模型主要由平台驱动层、芯片平台适配层、LCD器件驱动层三部分组成。驱动模型基于HDF驱动框架开发,通过Platform层和OSAL层提供的接口,屏蔽内核形态的差异,使得器件驱动可以便利的迁移到不同OS及芯片平台。模型向上对接Display公共HAL层,支撑HDI(Hardware Device Interface)接口的实现,通过Display-HDI对图形服务提供各类驱动能力接口。
Display平台驱动层:通过HDF提供的IOService数据通道,与公共HAL层对接,集中接收并处理各类上层调用指令。
SoC平台驱动适配层:借助此SoC适配层,实现Display驱动和SoC侧驱动解耦,主要完成芯片平台相关的参数配置,并传递平台驱动层的调用到器件驱动层。
LCD器件驱动层:在器件驱动层中,主要实现和器件自身强相关的驱动适配接口,例如发送初始化序列、上下电、背光设置等。
基于Display驱动模型开发LCD驱动,可以借助平台提供的各种能力及接口,较大程度的降低器件驱动的开发周期和难度,提升开发效率。
LCD接口通常可分为MIPI DSI接口、TTL接口和LVDS接口,常用的是MIPI DSI接口和TTL接口,下面对常用的MIPI DSI接口和TTL接口作简要介绍。
MIPI DSI接口
图2 MIPI DSI接口
MIPI DSI接口是MIPI(Mobile Industry Processor Interface)联盟定义的显示接口,主要用于移动终端显示屏接口,接口数据传输遵循MIPI协议,MIPI DSI接口为数据接口,传输图像数据,通常情况下MIPI DSI接口的控制信息以MIPI包形式通过MIPI DSI接口发送到对端IC,不需要额外的外设接口。
TTL接口
图3 TTL接口
TTL(Transistor Transistor Logic)即晶体管-晶体管逻辑,TTL电平信号由TTL器件产生,TTL器件是数字集成电路的一大门类,它采用双极型工艺制造,具有高速度、低功耗和品种多等特点。
TTL接口是并行方式传输数据的接口,有数据信号、时钟信号和控制信号(行同步、帧同步、数据有效信号等),在控制信号控制下完成数据传输。通常TTL接口的LCD,内部寄存器读写需要额外的外设接口,比如SPI接口、I2C接口等。
Display驱动模型基于HDF驱动框架、Platform接口及OSAL接口开发,可以做到不区分OS(LiteOS、Linux)和芯片平台(Hi35xx、Hi38xx、V3S等),为LCD器件提供统一的驱动模型。开发步骤如下:
添加LCD驱动相关的设备描述配置。
在SoC平台驱动适配层中适配对应的芯片平台驱动。
添加器件驱动,并在驱动入口函数Init中注册Panel驱动数据,驱动数据接口主要包括如下接口:
根据需求实现HDF框架其他接口,比如Release接口。
根据需求使用HDF框架可创建其他设备节点,用于业务逻辑或者调试功能。
添加设备描述配置:
/* Display驱动相关的设备描述配置 */
display :: host {
hostName = "display_host";
/* Display平台驱动设备描述 */
device_hdf_disp :: device {
device0 :: deviceNode {
policy = 2;
priority = 200;
permission = 0660;
moduleName = "HDF_DISP";
serviceName = "hdf_disp";
}
}
/* SoC适配层驱动设备描述 */
device_hi35xx_disp :: device {
device0 :: deviceNode {
policy = 0;
priority = 199;
moduleName = "HI351XX_DISP";
}
}
/* LCD器件驱动设备描述 */
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";
}
}
}
SOC适配层驱动,以Hi35xx系列芯片为例,需要在本层驱动中适配MIPI等和芯片平台相关的配置,示例如下:
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);
/* config 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;
}
LCD器件驱动示例如下:
#define RESET_GPIO 5
#define MIPI_DSI0 0
#define BLK_PWM1 1
#define PWM_MAX_PERIOD 100000
/* backlight setting */
#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结构体结构体 */
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;
};
/* LCD屏的初始化序列 */
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;
/* 设置Reset Pin脚状态 */
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;
}
/* delay 20ms */
OsalMSleep(20);
return HDF_SUCCESS;
}
static int32_t SampleInit(void)
{
/* 获取MIPI DSI设备操作句柄 */
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;
/* LCD上电序列 */
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;
}
/* 使用mipi下发初始化序列 */
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;
}
}
/* 将mipi切换到HS模式 */
MipiDsiSetHsMode(g_mipiHandle);
return HDF_SUCCESS;
}
/* PanelInfo结构体变量 */
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 config info */
.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 },
};
/* 器件驱动需要适配的基础接口 */
static struct PanelData g_panelData = {
.info = &g_panelInfo,
.init = SampleInit,
.on = SampleOn,
.off = SampleOff,
.setBacklight = SampleSetBacklight,
};
/* 器件驱动入口函数 */
int32_t SampleEntryInit(struct HdfDeviceObject *object)
{
HDF_LOGI("%s: enter", __func__);
if (object == NULL) {
HDF_LOGE("%s: param is null!", __func__);
return HDF_FAILURE;
}
/* 器件驱动接口注册,ops提供给平台驱动调用 */
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);
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