Merge pull request '日常更新 2312161132' (#4) from define/firmware_violet_zf:master into master

Reviewed-on: http://git.isthmus.tk:441/btl143/firmware_violet_zf/pulls/4
2023-12-16 11:40:14 +08:00
parent b61d4b8aee 131d098cc1
commit cff7014f12
7 changed files with 400 additions and 356 deletions
--- a/Readme.md
+++ b/Readme.md
@@ -1,24 +1,24 @@
 # fireware_violet
-## 使用 VSCode + EIDE + GCC + OpenOCD 开发
+## 1 使用 VSCode + EIDE + GCC + OpenOCD 开发
-* 确保 VSCode 安装了 `EIDE` 插件
+### 1.1 前提要求
-* 将文件 `firmware_violet.code-workspace_eg` 重命名为 `firmware_violet.code-workspace`
+1. VSCode 安装了 `EIDE` 插件  
 2. 有 Python3 环境  
 3. 已有沁恒 risc-v 工具链 (MRS 集成开发环境自带)
-* 双击 `firmware_violet.code-workspace` 从工作区开启 VSCode
+### 1.2 在工作区目录下运行配置脚本
-* 工作区设置中修改 EIDE 插件设置，将 `EIDE.RISCV.InstallDirectory` 和 `EIDE.OpenOCD.ExePath` 两项设置更改为自己 MRS 下 ToolChains 中 GCC 和 OpenOCD 的路径
+```bash
 pyhton ./set_eide_env.py
 ```
-### eg.
+根据提示配置两个路径 (OpenOCD 和 riscv-gcc) 即可
-`EIDE.RISCV.InstallDirectory` - `D:\Program_Files_nospace\MounRiver\MounRiver_Studio\toolchain\RISC-V Embedded GCC`
+配置完成后请先关闭 VSCode，再重新双击 `violet_firmware_zf.code-workspace` 文件开启工作区 (否则当前工作区的 OpenOCD 路径配置不会马上生效)
-`EIDE.OpenOCD.ExePath` - `D:\Program_Files_nospace\MounRiver\MounRiver_Studio\toolchain\OpenOCD\bin\openocd.exe`
+## 2 常用快捷键
 然后就可以愉快的使用 VSCode 进行开发和下载了
 ## 常用快捷键：
 * 编译：`F7`
--- a/app/cw_servo.c
+++ b/app/cw_servo.c
@@ -0,0 +1,17 @@
 #include "zf_common_headfile.h"
 #include "cw_servo.h"
 void cw_servo_init(void)
 {
    pwm_init(SERVO_L_PWM_CHANNEL, 50, 1000);
    pwm_init(SERVO_R_PWM_CHANNEL, 50, 1000);
 }
 void cw_servo_set_angle(float servo_l_angle, float servo_r_angle)
 {
    uint32_t servo_l_duty_s = (uint32_t)(servo_l_angle * SERVO_L_DUTY_PER_ANGLE);
    uint32_t servo_r_duty_s = (uint32_t)(servo_r_angle * SERVO_R_DUTY_PER_ANGLE);
    pwm_set_duty(SERVO_L_PWM_CHANNEL, servo_l_duty_s);
    pwm_set_duty(SERVO_R_PWM_CHANNEL, servo_r_duty_s);
 }
--- a/app/cw_servo.h
+++ b/app/cw_servo.h
@@ -0,0 +1,20 @@
 #ifndef _CW_SERVO_H__
 #define _CW_SERVO_H__
 #include "zf_common_headfile.h"
 #define SERVO_L_PWM_CHANNEL    TIM2_PWM_MAP0_CH1_A0
 #define SERVO_R_PWM_CHANNEL    TIM2_PWM_MAP0_CH2_A1
 #define SERVO_MAX_ANGLE_RANGE  (90.0F)
 #define SERVO_L_DUTY_MAX       (1100.0F)
 #define SERVO_L_DUTY_MIN       (900.0F)
 #define SERVO_R_DUTY_MAX       (1100.0F)
 #define SERVO_R_DUTY_MIN       (900.0F)
 #define SERVO_L_DUTY_PER_ANGLE ((SERVO_L_DUTY_MAX - SERVO_L_DUTY_MIN) / SERVO_MAX_ANGLE_RANGE)
 #define SERVO_R_DUTY_PER_ANGLE ((SERVO_R_DUTY_MAX - SERVO_R_DUTY_MIN) / SERVO_MAX_ANGLE_RANGE)
 extern void cw_servo_init(void);
 extern void cw_servo_set_angle(float servo_l_angle, float servo_r_angle);
 #endif
--- a/app/main.c
+++ b/app/main.c
@@ -33,29 +33,32 @@
 * 2022-09-15        <20><>W            first version
 ********************************************************************************************************************/
 #include "zf_common_headfile.h"
 #include "cw_servo.h"
 #include "by_pt_button.h"
 #include "by_fan_control.h"
 uint8 mt9v03x_image_cp[MT9V03X_H][MT9V03X_W];
 uint16_t pwm_cnt = 0;
 int main(void)
 {
    clock_init(SYSTEM_CLOCK_120M); // <20><>ʼ<EFBFBD><CABC>оƬʱ<C6AC><CAB1> <20><><EFBFBD><EFBFBD>Ƶ<EFBFBD><C6B5>Ϊ 120MHz
    debug_init();                  // <20><><EFBFBD>ر<EFBFBD><D8B1><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ڳ<EFBFBD>ʼ<EFBFBD><CABC>MPU ʱ<><CAB1> <20><><EFBFBD>Դ<EFBFBD><D4B4><EFBFBD>
    // <20>˴<EFBFBD><CBB4><EFBFBD>д<EFBFBD>û<EFBFBD><C3BB><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ʼ<EFBFBD><CABC><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
    ips114_init();
    by_gpio_init();
    by_exit_init();
    by_pwm_init();
    cw_servo_init();
    // mt9v03x_init();
    // <20>˴<EFBFBD><CBB4><EFBFBD>д<EFBFBD>û<EFBFBD><C3BB><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ʼ<EFBFBD><CABC><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
-    while(1)
+    
-    {
+
    while (1) {
        // <20>˴<EFBFBD><CBB4><EFBFBD>д<EFBFBD><D0B4>Ҫѭ<D2AA><D1AD>ִ<EFBFBD>еĴ<D0B5><C4B4><EFBFBD>
        // <20>˴<EFBFBD><CBB4><EFBFBD>д<EFBFBD><D0B4>Ҫѭ<D2AA><D1AD>ִ<EFBFBD>еĴ<D0B5><C4B4><EFBFBD>
    }
 }
--- a/libraries/zf_common/zf_common_typedef.h
+++ b/libraries/zf_common/zf_common_typedef.h
@@ -50,14 +50,20 @@
 #if USE_ZF_TYPEDEF
 // <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
 // <20><><EFBFBD><EFBFBD>ʹ<EFBFBD><CAB9> stdint.h <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ͻ <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>Բü<D4B2>
 // <20><><EFBFBD>滰˵<E6BBB0><CBB5>ͦ<EFBFBD>ã<EFBFBD>uint32(aka unsigned int) <20><> uint32_t(aka unsigned long) <20><>һ<EFBFBD><D2BB>
 // <20><>Ȼ<EFBFBD><C8BB> 32 λ<><CEBB><EFBFBD>϶<EFBFBD><CFB6><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ֽڣ<D6BD><DAA3><EFBFBD><EFBFBD>Ǿ<EFBFBD>̬<EFBFBD><CCAC><EFBFBD><EFBFBD><EFBFBD>ܻ<EFBFBD><DCBB><EFBFBD><EFBFBD><EFBFBD>ʾ<EFBFBD><CABE><EFBFBD>ܲ<EFBFBD>ˬ<EFBFBD><CBAC><EFBFBD><EFBFBD><EFBFBD>¸ĵ<C2B8>
 // typedef unsigned int uint32;       // <20>޷<EFBFBD><DEB7><EFBFBD> 32 bits
 typedef unsigned char uint8;   // <20>޷<EFBFBD><DEB7><EFBFBD>  8 bits
-typedef unsigned short int  uint16;                                             // <20>޷<EFBFBD><DEB7><EFBFBD> 16 bits
+typedef unsigned short uint16; // <20>޷<EFBFBD><DEB7><EFBFBD> 16 bits
-typedef unsigned int        uint32;                                             // <20>޷<EFBFBD><DEB7><EFBFBD> 32 bits
+
 typedef unsigned long uint32;      // <20>޷<EFBFBD><DEB7><EFBFBD> 32 bits
 typedef unsigned long long uint64; // <20>޷<EFBFBD><DEB7><EFBFBD> 64 bits
 typedef signed char int8;       // <20>з<EFBFBD><D0B7><EFBFBD>  8 bits
-typedef signed short int    int16;                                              // <20>з<EFBFBD><D0B7><EFBFBD> 16 bits
+typedef signed short int16;     // <20>з<EFBFBD><D0B7><EFBFBD> 16 bits
-typedef signed int          int32;                                              // <20>з<EFBFBD><D0B7><EFBFBD> 32 bits
+typedef signed long int32;       // <20>з<EFBFBD><D0B7><EFBFBD> 32 bits
 typedef signed long long int64; // <20>з<EFBFBD><D0B7><EFBFBD> 64 bits
 typedef volatile uint8 vuint8;   // <20>ױ<EFBFBD><D7B1><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD> <20>޷<EFBFBD><DEB7><EFBFBD>  8 bits
--- a/libraries/zf_device/zf_device_imu660ra.c
+++ b/libraries/zf_device/zf_device_imu660ra.c
@@ -63,9 +63,14 @@
 #include "zf_device_imu660ra.h"
-int16 imu660ra_gyro_x = 0, imu660ra_gyro_y = 0, imu660ra_gyro_z = 0;            // 三轴陀螺仪数据   gyro (陀螺仪)
+int16 imu660ra_gyro_x               = 0;
-int16 imu660ra_acc_x = 0, imu660ra_acc_y = 0, imu660ra_acc_z = 0;               // 三轴加速度计数据 acc  (accelerometer 加速度计)
+int16 imu660ra_gyro_y               = 0;
-float imu660ra_transition_factor[2] = {4096, 16.4};
+int16 imu660ra_gyro_z               = 0; // 三轴陀螺仪数据   gyro (陀螺仪)
 int16 imu660ra_acc_x                = 0;
 int16 imu660ra_acc_y                = 0;
 int16 imu660ra_acc_z                = 0; // 三轴加速度计数据 acc  (accelerometer 加速度计)
 float imu660ra_temperature          = 0;
 float imu660ra_transition_factor[2] = {4096, 16.4f};
 #if IMU660RA_USE_SOFT_IIC
 static soft_iic_info_struct imu660ra_iic_struct;
@@ -136,8 +141,7 @@ static void imu660ra_read_registers(uint8 reg, uint8 *data, uint32 len)
    IMU660RA_CS(0);
    spi_read_8bit_registers(IMU660RA_SPI, reg | IMU660RA_SPI_R, temp_data, len + 1);
    IMU660RA_CS(1);
-    for(int i = 0; i < len; i ++)
+    for (int i = 0; i < len; i++) {
    {
        *(data++) = temp_data[i + 1];
    }
 }
@@ -152,12 +156,11 @@ static void imu660ra_read_registers(uint8 reg, uint8 *data, uint32 len)
 //-------------------------------------------------------------------------------------------------------------------
 static uint8 imu660ra_self_check(void)
 {
-    uint8 dat = 0, return_state = 0;
+    uint8 dat            = 0;
    uint8 return_state   = 0;
    uint16 timeout_count = 0;
-    do
+    do {
-    {
+        if (timeout_count++ > IMU660RA_TIMEOUT_COUNT) {
        if(timeout_count ++ > IMU660RA_TIMEOUT_COUNT)
        {
            return_state = 1;
            break;
        }
@@ -202,6 +205,14 @@ void imu660ra_get_gyro (void)
    imu660ra_gyro_z = (int16)(((uint16)dat[5] << 8 | dat[4]));
 }
 void imu660ra_get_temperature(void)
 {
    uint8_t dat[2];
    imu660ra_read_registers(IMU660RA_TEMP_ADDRESS, dat, 2);
    imu660ra_temperature = (int16_t)((uint16_t)dat[1] << 8 | dat[0]);
    imu660ra_temperature = imu660ra_temperature / 512.0f + 23.0f;
 }
 //-------------------------------------------------------------------------------------------------------------------
 // 函数简介     初始化 IMU660RA
 // 参数说明     void
@@ -255,36 +266,29 @@ uint8 imu660ra_init (void)
        // 设置为 0x01 加速度计量程为 ±4  g   获取到的加速度计数据除以 8192   可以转化为带物理单位的数据 单位 g(m/s^2)
        // 设置为 0x02 加速度计量程为 ±8  g   获取到的加速度计数据除以 4096   可以转化为带物理单位的数据 单位 g(m/s^2)
        // 设置为 0x03 加速度计量程为 ±16 g   获取到的加速度计数据除以 2048   可以转化为带物理单位的数据 单位 g(m/s^2)
-        switch(IMU660RA_ACC_SAMPLE_DEFAULT)
+        switch (IMU660RA_ACC_SAMPLE_DEFAULT) {
-        {
+            default: {
            default:
            {
                zf_log(0, "IMU660RA_ACC_SAMPLE_DEFAULT set error.");
                return_state = 1;
            } break;
-            case IMU660RA_ACC_SAMPLE_SGN_2G:
+            case IMU660RA_ACC_SAMPLE_SGN_2G: {
            {
                imu660ra_write_register(IMU660RA_ACC_RANGE, 0x00);
                imu660ra_transition_factor[0] = 16384;
            } break;
-            case IMU660RA_ACC_SAMPLE_SGN_4G:
+            case IMU660RA_ACC_SAMPLE_SGN_4G: {
            {
                imu660ra_write_register(IMU660RA_ACC_RANGE, 0x01);
                imu660ra_transition_factor[0] = 8192;
            } break;
-            case IMU660RA_ACC_SAMPLE_SGN_8G:
+            case IMU660RA_ACC_SAMPLE_SGN_8G: {
            {
                imu660ra_write_register(IMU660RA_ACC_RANGE, 0x02);
                imu660ra_transition_factor[0] = 4096;
            } break;
-            case IMU660RA_ACC_SAMPLE_SGN_16G:
+            case IMU660RA_ACC_SAMPLE_SGN_16G: {
            {
                imu660ra_write_register(IMU660RA_ACC_RANGE, 0x03);
                imu660ra_transition_factor[0] = 2048;
            } break;
        }
-        if(1 == return_state)
+        if (1 == return_state) {
        {
            break;
        }
@@ -294,45 +298,35 @@ uint8 imu660ra_init (void)
        // 设置为 0x02 陀螺仪量程为 ±500  dps    获取到的陀螺仪数据除以 65.6    可以转化为带物理单位的数据 单位为 °/s
        // 设置为 0x01 陀螺仪量程为 ±1000 dps    获取到的陀螺仪数据除以 32.8    可以转化为带物理单位的数据 单位为 °/s
        // 设置为 0x00 陀螺仪量程为 ±2000 dps    获取到的陀螺仪数据除以 16.4    可以转化为带物理单位的数据 单位为 °/s
-        switch(IMU660RA_GYRO_SAMPLE_DEFAULT)
+        switch (IMU660RA_GYRO_SAMPLE_DEFAULT) {
-        {
+            default: {
            default:
            {
                zf_log(0, "IMU660RA_GYRO_SAMPLE_DEFAULT set error.");
                return_state = 1;
            } break;
-            case IMU660RA_GYRO_SAMPLE_SGN_125DPS:
+            case IMU660RA_GYRO_SAMPLE_SGN_125DPS: {
            {
                imu660ra_write_register(IMU660RA_GYR_RANGE, 0x04);
                imu660ra_transition_factor[1] = 262.4;
            } break;
-            case IMU660RA_GYRO_SAMPLE_SGN_250DPS:
+            case IMU660RA_GYRO_SAMPLE_SGN_250DPS: {
            {
                imu660ra_write_register(IMU660RA_GYR_RANGE, 0x03);
                imu660ra_transition_factor[1] = 131.2;
            } break;
-            case IMU660RA_GYRO_SAMPLE_SGN_500DPS:
+            case IMU660RA_GYRO_SAMPLE_SGN_500DPS: {
            {
                imu660ra_write_register(IMU660RA_GYR_RANGE, 0x02);
                imu660ra_transition_factor[1] = 65.6;
            } break;
-            case IMU660RA_GYRO_SAMPLE_SGN_1000DPS:
+            case IMU660RA_GYRO_SAMPLE_SGN_1000DPS: {
            {
                imu660ra_write_register(IMU660RA_GYR_RANGE, 0x01);
                imu660ra_transition_factor[1] = 32.8;
            } break;
-            case IMU660RA_GYRO_SAMPLE_SGN_2000DPS:
+            case IMU660RA_GYRO_SAMPLE_SGN_2000DPS: {
            {
                imu660ra_write_register(IMU660RA_GYR_RANGE, 0x00);
                imu660ra_transition_factor[1] = 16.4;
            } break;
        }
-        if(1 == return_state)
+        if (1 == return_state) {
        {
            break;
        }
    } while (0);
    return return_state;
 }
--- a/libraries/zf_device/zf_device_imu660ra.h
+++ b/libraries/zf_device/zf_device_imu660ra.h
@@ -58,12 +58,12 @@
 #include "zf_common_typedef.h"
-#define IMU660RA_USE_SOFT_IIC       (0)                                         // 默认使用硬件 SPI 方式驱动
+#define IMU660RA_USE_SOFT_IIC (1) // 默认使用硬件 SPI 方式驱动
 #if IMU660RA_USE_SOFT_IIC         // 这两段 颜色正常的才是正确的 颜色灰的就是没有用的
 //====================================================软件 IIC 驱动====================================================
 #define IMU660RA_SOFT_IIC_DELAY (10)  // 软件 IIC 的时钟延时周期 数值越小 IIC 通信速率越快
-#define IMU660RA_SCL_PIN            (B13)                                       // 软件 IIC SCL 引脚 连接 IMU660RA 的 SCL 引脚
+#define IMU660RA_SCL_PIN        (B3) // 软件 IIC SCL 引脚 连接 IMU660RA 的 SCL 引脚
-#define IMU660RA_SDA_PIN            (B15)                                       // 软件 IIC SDA 引脚 连接 IMU660RA 的 SDA 引脚
+#define IMU660RA_SDA_PIN        (B5) // 软件 IIC SDA 引脚 连接 IMU660RA 的 SDA 引脚
 //====================================================软件 IIC 驱动====================================================
 #else
@@ -79,16 +79,14 @@
 #define IMU660RA_CS_PIN (C10) // CS 片选引脚
 #define IMU660RA_CS(x)  ((x) ? (gpio_high(IMU660RA_CS_PIN)) : (gpio_low(IMU660RA_CS_PIN)))
-typedef enum
+typedef enum {
 {
    IMU660RA_ACC_SAMPLE_SGN_2G,  // 加速度计量程 ±2G  (ACC = Accelerometer 加速度计) (SGN = signum 带符号数 表示正负范围) (G = g 重力加速度 g≈9.80 m/s^2)
    IMU660RA_ACC_SAMPLE_SGN_4G,  // 加速度计量程 ±4G  (ACC = Accelerometer 加速度计) (SGN = signum 带符号数 表示正负范围) (G = g 重力加速度 g≈9.80 m/s^2)
    IMU660RA_ACC_SAMPLE_SGN_8G,  // 加速度计量程 ±8G  (ACC = Accelerometer 加速度计) (SGN = signum 带符号数 表示正负范围) (G = g 重力加速度 g≈9.80 m/s^2)
    IMU660RA_ACC_SAMPLE_SGN_16G, // 加速度计量程 ±16G (ACC = Accelerometer 加速度计) (SGN = signum 带符号数 表示正负范围) (G = g 重力加速度 g≈9.80 m/s^2)
 } imu660ra_acc_sample_config;
-typedef enum
+typedef enum {
 {
    IMU660RA_GYRO_SAMPLE_SGN_125DPS,  // 陀螺仪量程 ±125DPS  (GYRO = Gyroscope 陀螺仪) (SGN = signum 带符号数 表示正负范围) (DPS = Degree Per Second 角速度单位 °/S)
    IMU660RA_GYRO_SAMPLE_SGN_250DPS,  // 陀螺仪量程 ±250DPS  (GYRO = Gyroscope 陀螺仪) (SGN = signum 带符号数 表示正负范围) (DPS = Degree Per Second 角速度单位 °/S)
    IMU660RA_GYRO_SAMPLE_SGN_500DPS,  // 陀螺仪量程 ±500DPS  (GYRO = Gyroscope 陀螺仪) (SGN = signum 带符号数 表示正负范围) (DPS = Degree Per Second 角速度单位 °/S)
@@ -112,6 +110,7 @@ typedef enum
 #define IMU660RA_INIT_CTRL    (0x59)
 #define IMU660RA_INIT_DATA    (0x5E)
 #define IMU660RA_INT_STA      (0x21)
 #define IMU660RA_TEMP_ADDRESS (0x22)
 #define IMU660RA_ACC_ADDRESS  (0x0C)
 #define IMU660RA_GYRO_ADDRESS (0x12)
 #define IMU660RA_ACC_CONF     (0x40)
@@ -120,12 +119,18 @@ typedef enum
 #define IMU660RA_GYR_RANGE    (0x43)
 //================================================定义 IMU660RA 内部地址================================================
-extern int16 imu660ra_gyro_x, imu660ra_gyro_y, imu660ra_gyro_z;                 // 三轴陀螺仪数据      gyro (陀螺仪)
+extern int16 imu660ra_gyro_x;
-extern int16 imu660ra_acc_x, imu660ra_acc_y, imu660ra_acc_z;                    // 三轴加速度计数据     acc (accelerometer 加速度计)
+extern int16 imu660ra_gyro_y;
 extern int16 imu660ra_gyro_z; // 三轴陀螺仪数据      gyro (陀螺仪)
 extern int16 imu660ra_acc_x;
 extern int16 imu660ra_acc_y;
 extern int16 imu660ra_acc_z; // 三轴加速度计数据     acc (accelerometer 加速度计)
 extern float imu660ra_temperature;
 extern float imu660ra_transition_factor[2];
 void imu660ra_get_acc(void);  // 获取 IMU660RA 加速度计数据
 void imu660ra_get_gyro(void); // 获取 IMU660RA 陀螺仪数据
 void imu660ra_get_temperature(void);
 //-------------------------------------------------------------------------------------------------------------------
 // 函数简介     将 IMU660RA 加速度计数据转换为实际物理数据
@@ -148,4 +153,3 @@ void  imu660ra_get_gyro             (void);
 uint8 imu660ra_init(void); // 初始化 IMU660RA
 #endif