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sggt/App/APP_WU/Src/apps_gather.c

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/*
* @Author: wujunchao wujunchao@wuxismart.com
* @Date: 2024-12-27 11:50:56
* @LastEditors: wujunchao wujunchao@wuxismart.com
* @LastEditTime: 2025-03-13 12:52:58
* @FilePath: \signal_generator\App\APP_WU\Src\apps_gather.c
* @Description: 这是默认设置,请设置`customMade`, 打开koroFileHeader查看配置 进行设置: https://github.com/OBKoro1/koro1FileHeader/wiki/%E9%85%8D%E7%BD%AE
*/
#include "apps_gather.h" //用于头文件打包汇总,函数声明和变量定义
// lv_conf.h { line:282->CPU&FPS; line:289->MEM used }
/**********test5**********/
MENU_DATA m5data; //界面参数初始化
PLOT_DATA pltdata; //chart绘图参数初始化
TABVIEW_DATA tabdata; //设置页面参数初始化
PHYSICAL_QUANTITY VOL[2]; //电压VOL[0]-V, VOL[1]-mV
PHYSICAL_QUANTITY CUR; //电流mA
PHYSICAL_QUANTITY RES; //电阻,Ω
PHYSICAL_QUANTITY FRE; //频率KHz
PHYSICAL_QUANTITY TC[3]; //热电偶TC[0]-K, TC[1]-S, TC[2]-N
PHYSICAL_QUANTITY RTD; //热电阻
//物理量内容初始化
void physical_quantity_init(void)
{
VOL[0].tag = SIG_VOLTAGE;
VOL[0].typ = VOLTAGE_V;
VOL[0].low = 0;
VOL[0].up = 30;
VOL[0].pv = 0;
VOL[1].tag = SIG_VOLTAGE;
VOL[1].typ = VOLTAGE_MV;
VOL[1].low = 0;
VOL[1].up = 500;
VOL[1].pv = 0;
CUR.tag = SIG_CURRENT;
CUR.typ = CURRENT_MA;
CUR.low = 0;
CUR.up = 24;
CUR.pv = 0;
RES.tag = SIG_RESISTANT;
RES.typ = RESISTANT_OHM;
RES.low = 0;
RES.up = 4000;
RES.pv = 0;
FRE.tag = SIG_FREQUENCE;
FRE.typ = FREQUENCE_KHZ;
FRE.low = 0;
FRE.up = 100;
FRE.pv = 0;
TC[0].tag = SIG_TC;
TC[0].typ = TC_K;
TC[0].low = -250;
TC[0].up = 1820;
TC[0].pv = 0;
TC[1].tag = SIG_TC;
TC[1].typ = TC_S;
TC[1].low = -250;
TC[1].up = 1820;
TC[1].pv = 0;
TC[2].tag = SIG_TC;
TC[2].typ = TC_N;
TC[2].low = -250;
TC[2].up = 1820;
TC[2].pv = 0;
RTD.tag = SIG_RTD;
RTD.typ = RTD_DC;
RTD.low = -200;
RTD.up = 850;
RTD.pv = 0;
}
void menu_data_init(void)
{
//general
m5data.scr_now = SCREEN_INIT; //初始界面为开机动画
m5data.tick_prv = -1; //前一时刻,用于计时
m5data.tick_cur = -1; //当前时刻,用于计时
m5data.menu_reset_flag = 0; //复位使能标志置1后复位复位完成后变回0
physical_quantity_init();
//screen_init
m5data.scr_init_flag = 0; //是否进行过初始化(开机动画)
m5data.scr_init_bar = 0; //进度条值0~100
m5data.scr_init_cnt = 0; //进度条计数(控制进度条动画)
//screen_main
// {
m5data.runtime_seconds = 0; //秒
m5data.runtime_minutes = 0; //分钟
m5data.runtime_hours = 0; //小时
memset(m5data.runtime_show, 0, 16); //存放显示时间的字符串
m5data.battery_cnt = 0; //电池计数
m5data.io_cursor = 3; //当前游标位置,[0000,000]:0~6
m5data.io_cursor_prv = 3; //前一时刻游标位置
m5data.twk_flag = 0; //0停止闪烁1开始闪烁
m5data.twk_flip = 0; //0显示1不显示
m5data.twk_cnt = 0; //闪烁计数
m5data.overflow_flag_low = 0; //向上溢出
m5data.overflow_flag_up = 0; //向下溢出
m5data.sign_flag_in = 0; //默认不显示符号
m5data.sign_flag_out = 0; //默认不显示符号
m5data.io_on2off = IO_OFF; //初始为关闭状态
m5data.io_mode = IO_OUTPUT; //默认工作模式0输入IN1输出OUT
for(uint8_t i = 0; i < 7; i++) //用于数值显示的数组初值为0
{
m5data.i_numbers[i] = 0; //输入值/测量值
m5data.o_numbers[i] = 0; //输出值/设定值
}
m5data.input_mode = VOL[0].tag; //输入功能初始为电压模式
m5data.input_mode_type = VOL[0].typ; //电压单位初始为V
m5data.output_mode = VOL[0].tag; //输出功能初始为电压模式
m5data.output_mode_type = VOL[0].typ; //电压单位初始为V
//chart组件显示int,绘图值
pltdata.y_pri_low = 0; //主轴的显示下限0通常不做修改
pltdata.y_pri_up = 100; //主轴的显示上限100通常不做修改
pltdata.y_scd_low = 0; //副轴的显示下限0通常不做修改
pltdata.y_scd_up = 100; //副轴的显示上限100通常不做修改
pltdata.y_pri_value = 0; //主轴的实时显示值0~100
pltdata.y_pri_value_prv = 0; //前一时刻的曲线绘图值
pltdata.y_scd_value = 0; //副轴的实时显示值0~100
pltdata.y_scd_value_prv = 0; //前一时刻的曲线绘图值
pltdata.y_scd_value_prv = 0; //前一时刻的实时显示值。
pltdata.pri_wait_tick = 0; //主轴等待滴答数
pltdata.scd_wait_tick = 0; //副轴等待滴答数
//chart组件显示int,实际值
pltdata.yreal_pri_low = VOL[0].low; //实际值的显示下限,主轴
pltdata.yreal_pri_up = VOL[0].up; //实际值的显示上限,主轴
pltdata.yreal_scd_low = VOL[0].low; //实际值的显示下限,副轴
pltdata.yreal_scd_up = VOL[0].up; //实际值的显示上限,副轴
pltdata.yreal_pri_value = VOL[0].pv; //主轴的实时值,即输出/设定值
pltdata.yreal_scd_value = VOL[0].pv; //副轴的实时值,即输入/测量值
pltdata.yreal_scd_value_prv = VOL[0].pv; //前一时刻的输入测量值
// }
//screen_setting
tabdata.tab_cursor = 0; //选项卡的游标(焦点)
tabdata.tab_cursor_prv = 0; //前一刻的选项卡游标
tabdata.tab_cursor_inner = 99; //某一选项卡内部的游标
tabdata.tab_cursor_inner_prv = 99; //前一刻的~
//暂定,用于组件测试
tabdata.content00 = VOLTAGE_V; //第0个选项卡的第0个内容
tabdata.content01[0] = VOL[0].up; //第0个选项卡的第1个内容
tabdata.content01[1] = VOL[1].up; //第0个选项卡的第1个内容
tabdata.content02[0] = VOL[0].low; //第0个选项卡的第2个内容
tabdata.content02[1] = VOL[1].low; //第0个选项卡的第2个内容
}
void menu_reset(void)
{
//界面复位
if(m5data.scr_now == SCREEN_INIT)
{
//如果正处于开机动画中,立即返回。
return;
}
//加载初始界面
setup_scr_screen_init(&guider_ui);
lv_scr_load(guider_ui.screen_init);
//释放内存
switch (m5data.scr_now)
{
case SCREEN_MAIN:
{
lv_obj_del(guider_ui.screen_main);
}
break;
case SCREEN_SETTING:
{
lv_obj_del(guider_ui.screen_setting);
}
break;
default:
break;
}
//参数复位内部会对m5data.scr_now进行更改因此放置于最后。
menu_data_init();
}
void menu_test5(void)
{
if(m5data.menu_reset_flag)
{
menu_reset(); //触发显示内容复位
m5data.menu_reset_flag = 0;
return;
}
if(m5data.scr_init_flag == 0)
{
scr_init_run(); //播放开机动画
}
else
{
switch (m5data.scr_now)
{
case SCREEN_MAIN:
{
scr_main_run(); //主界面显示
key_functions_main(); //主界面的按键功能
}
break;
case SCREEN_SETTING:
{
scr_setting_run(); //设置界面
key_functions_setting(); //设置界面的按键功能
}
break;
default:
break;
}
}
}
//KEY_MAIN
void key_functions_main(void)
{
uint8_t cursor_temp = 0; //临时游标,替代枚举变量进行加减运算
switch (key)
{
case KEY_OUT:
{
key = 0;
//交替按下 in 和 out 时,只改变输入/输出,连续按同一个键的时候才改变类型
if(m5data.io_mode == IO_INPUT)
{
m5data.io_mode = IO_OUTPUT;
m5data.output_mode = m5data.input_mode;
io_on2off_status(); //更新状态指示
}
else
{
cursor_temp = (uint8_t)m5data.output_mode;
cursor_temp = (cursor_temp >= 5)?(0):(cursor_temp + 1);
m5data.output_mode = (SIG_FUNCTIONS)cursor_temp;
}
switch (m5data.output_mode)
{
case SIG_VOLTAGE: //电压
{
m5data.output_mode_type = VOLTAGE_V;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_CURRENT: //电流
{
m5data.output_mode_type = CURRENT_MA;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_RESISTANT: //电阻
{
m5data.output_mode_type = RESISTANT_OHM;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_FREQUENCE: //频率
{
m5data.output_mode_type = FREQUENCE_KHZ;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_TC: //热电偶
{
m5data.output_mode_type = TC_K;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_RTD: //热电阻
{
m5data.output_mode_type = RTD_DC;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
default:
break;
}
}
break;
case KEY_UP:
{
key = 0;
if(m5data.io_mode == IO_INPUT)
{
return;
}
m5data.twk_flag = 1; // 上、下、左、右 任意一个键按下后,闪烁开始
m5data.twk_cnt = 0; //每次按下后闪烁计数清零
uint8_t step = 1; //up键步长默认为1
float32 step_real = 0; //实际值步长
float32 pv = 0, sv = 0, up = 0;
//根据当前游标位置计算步进值
step_real = step * my_power(10, (3 - m5data.io_cursor));
//按下up键后即将刷新的实际值
pv = get_output_value();
sv = pv + step_real;
up = pltdata.yreal_pri_up;
if( sv >= up )
{
//超过上限的情况下,直接显示上限
sv = up;
sv *= 1000;
set_output(sv);
}
else
{
//没超过上限的情况下仅考虑pv、0、sv三者的位置关系
if( pv >= 0 )
{
//一定为正数,直接调用以下函数,增加数值
change_nixie_cube_OUT(NIXIE_INCREASE, step);
}
else
{
if( sv < 0 )
{
//pv和sv都为负数的情况下仅调转方向减小数值
change_nixie_cube_OUT(NIXIE_DECREASE, step);
}
else
{
//跨越0后负号熄灭
//pv变为sv后跨越了0数值可能增大也可能减小因此直接赋值
sv *= 1000;
set_output(sv);
}
}
}
}
break;
case KEY_MENU:
{
key = 0;
//为保障安全,进入菜单页面后功能关闭,输入输出值清零
m5data.io_on2off = IO_OFF;
for(uint8_t i = 0; i < 6; i++) //用于数值显示的数组初值为0
{
m5data.i_numbers[i] = 0; //输入值/测量值
m5data.o_numbers[i] = 0; //输出值/设定值
}
m5data.twk_flag = 0; //闪烁中止
m5data.twk_cnt = 0; //闪烁计数清零
m5data.twk_flip = 0; //0显示1不显示
//加载菜单界面
setup_scr_screen_setting(&guider_ui);
lv_scr_load(guider_ui.screen_setting);
//切换至菜单后,清除主界面对象,释放内存
lv_obj_del(guider_ui.screen_main);
m5data.scr_now = SCREEN_SETTING; //当前界面为详细设置菜单
scr_setting_recover();
}
break;
case KEY_IN:
{
key = 0;
if(m5data.io_mode == IO_OUTPUT)
{
m5data.io_mode = IO_INPUT;
//继承之前的输出类型
m5data.input_mode = m5data.output_mode;
io_on2off_status(); //更新状态指示
}
else
{
//枚举类型不能直接运算于是使用临时变量cursor_temp
cursor_temp = (uint8_t)m5data.input_mode;
cursor_temp = (cursor_temp >= 5)?(0):(cursor_temp + 1);
m5data.input_mode = (SIG_FUNCTIONS)cursor_temp;
}
switch (m5data.input_mode)
{
case SIG_VOLTAGE: //电压
{
m5data.input_mode_type = VOLTAGE_V;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_CURRENT: //电流
{
m5data.input_mode_type = CURRENT_MA;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_RESISTANT: //电阻
{
m5data.input_mode_type = RESISTANT_OHM;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_FREQUENCE: //频率
{
m5data.input_mode_type = FREQUENCE_KHZ;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_TC: //热电偶
{
m5data.input_mode_type = TC_K;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_RTD: //热电阻
{
m5data.input_mode_type = RTD_DC;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
default:
break;
}
}
break;
case KEY_LEFT:
{
key = 0;
if(m5data.io_mode == IO_INPUT)
{
return;
}
m5data.twk_flag = 1; //上、下、左、右 任意一个键按下后,闪烁开始
m5data.twk_cnt = 0; //每次按下后闪烁计数清零
//避免游标移动的瞬间,前一刻的数值处于闪烁熄灭的状态,移动游标前重新显示一次当前数值
set_nixie_cube(IO_OUTPUT, m5data.io_cursor, m5data.o_numbers[m5data.io_cursor]);
m5data.io_cursor_prv = m5data.io_cursor;
m5data.io_cursor = (m5data.io_cursor <= 0)?(6):(m5data.io_cursor - 1);
set_cursor_position();
}
break;
case KEY_OK:
{
key = 0;
//主界面用OK键控制开关ON&OFF
if(m5data.io_on2off == IO_ON)
{
m5data.io_on2off = IO_OFF;
lv_label_set_text(guider_ui.screen_main_label_ONOFF, "OFF");
}
else
{
m5data.io_on2off = IO_ON;
lv_label_set_text(guider_ui.screen_main_label_ONOFF, "ON");
}
io_on2off_status(); //更新状态指示
}
break;
case KEY_RIGHT:
{
key = 0;
if(m5data.io_mode == IO_INPUT)
{
return;
}
m5data.twk_flag = 1; // 上、下、左、右 任意一个键按下后,闪烁开始
m5data.twk_cnt = 0; //每次按下后闪烁计数清零
//避免游标移动的瞬间,前一刻的数值处于闪烁熄灭的状态,移动游标前重新显示一次当前数值
set_nixie_cube(IO_OUTPUT, m5data.io_cursor, m5data.o_numbers[m5data.io_cursor]);
m5data.io_cursor_prv = m5data.io_cursor;
m5data.io_cursor = (m5data.io_cursor >= 6)?(0):(m5data.io_cursor + 1);
set_cursor_position();
}
break;
case KEY_SWITCH:
{
key = 0;
switch (m5data.io_mode) //输入、输出模式切换
{
case IO_OUTPUT:
{
switch (m5data.output_mode) //功能切换
{
case SIG_VOLTAGE:
{
cursor_temp = (uint8_t)m5data.output_mode_type;
cursor_temp = !cursor_temp;
m5data.output_mode_type = (SIG_FUNCTIONS_TYPE)cursor_temp;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_CURRENT:
{
m5data.output_mode_type = CURRENT_MA;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_RESISTANT: //电阻
{
m5data.output_mode_type = RESISTANT_OHM;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_FREQUENCE: //频率
{
m5data.output_mode_type = FREQUENCE_KHZ;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_TC: //热电偶
{
cursor_temp = (uint8_t)m5data.output_mode_type;
cursor_temp = (cursor_temp >= 7)?(5):(cursor_temp + 1);
m5data.output_mode_type = (SIG_FUNCTIONS_TYPE)cursor_temp;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_RTD: //热电阻
{
m5data.output_mode_type = RTD_DC;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
default:
break;
}
}
break;
case IO_INPUT:
{
switch (m5data.input_mode)
{
case SIG_VOLTAGE:
{
cursor_temp = (uint8_t)m5data.input_mode_type;
cursor_temp = !cursor_temp;
m5data.input_mode_type = (SIG_FUNCTIONS_TYPE)cursor_temp;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_CURRENT:
{
m5data.input_mode_type = CURRENT_MA;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_RESISTANT: //电阻
{
m5data.input_mode_type = RESISTANT_OHM;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_FREQUENCE: //频率
{
m5data.input_mode_type = FREQUENCE_KHZ;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
case SIG_TC: //热电偶
{
cursor_temp = (uint8_t)m5data.output_mode_type;
cursor_temp = (cursor_temp >= 7)?(5):(cursor_temp + 1);
m5data.output_mode_type = (SIG_FUNCTIONS_TYPE)cursor_temp;
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case SIG_RTD: //热电阻
{
m5data.input_mode_type = RTD_DC;
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
default:
break;
}
}
break;
default:
break;
}
}
break;
case KEY_SOURCE:
{
//电源开关靠硬件电路实现,此处可做预留
key = 0;
}
break;
case KEY_DOWN:
{
key = 0;
if(m5data.io_mode == IO_INPUT)
{
return;
}
m5data.twk_flag = 1; // 上、下、左、右 任意一个键按下后,闪烁开始
m5data.twk_cnt = 0; //每次按下后闪烁计数清零
uint8_t step = 1; //down键步长默认为1
float32 step_real = 0; //实际值步长
float32 pv = 0, sv = 0, low = 0;
//根据当前游标位置计算步进值
step_real = step * my_power(10, (3 - m5data.io_cursor));
//按下down键后即将刷新的实际值
pv = get_output_value();
sv = pv - step_real;
low = pltdata.yreal_pri_low;
if( sv <= low )
{
//超过下限的情况下,直接显示下限
sv = low;
sv *= 1000;
set_output(sv);
}
else
{
//没超过下限的情况下仅考虑pv、0、sv三者的位置关系
if( sv >= 0 )
{
//一定为正数,直接调用以下函数,减小数值
change_nixie_cube_OUT(NIXIE_DECREASE, step);
}
else
{
if( pv < 0 )
{
//pv和sv都为负数的情况下仅调转方向增大数值
change_nixie_cube_OUT(NIXIE_INCREASE, step);
}
else
{
//跨越0后负号点亮
//pv变为sv后跨越了0数值可能增大也可能减小因此直接赋值
sv *= 1000;
set_output(sv);
}
}
}
}
break;
case KEY_BACK: //闲置,预留
{
key = 0;
}
break;
default:
{
key = 0;
}
break;
}
}
void scr_init_run(void)
{
if( m5data.scr_init_cnt <= SCREEN_INIT_CNT_MAX ) //进度条变化次数,在头文件中设置
{
if( m5data.tick_prv == -1 )
{
m5data.tick_prv = xTaskGetTickCount(); //记录起始时刻
}else
{
m5data.tick_cur = xTaskGetTickCount(); //记录当前时刻
if(m5data.tick_cur < m5data.tick_prv) //防止溢出当前tick小于前一刻的tick
{
m5data.tick_prv = -1; //溢出后复位并返回
m5data.tick_cur = -1;
return;
}
if(m5data.tick_cur - m5data.tick_prv >= 1000) //tick间隔达到目标后执行功能
{
m5data.tick_prv = -1;
m5data.tick_cur = -1;
m5data.scr_init_bar = m5data.scr_init_cnt * ( 100/SCREEN_INIT_CNT_MAX );
lv_bar_set_value(guider_ui.screen_init_bar_1, m5data.scr_init_bar, LV_ANIM_OFF);
m5data.scr_init_cnt ++;
}
}
}
else
{
// //开机动画结束后,清除初始界面内部组件,保留对象,释放内存
// lv_obj_clean(guider_ui.screen_init);
//加载主界面
setup_scr_screen_main(&guider_ui);
lv_scr_load(guider_ui.screen_main);
//删除初始界面对象,释放剩余内存
lv_obj_del(guider_ui.screen_init);
m5data.scr_init_flag = 1; //开机动画结束,只执行一次
m5data.scr_now = SCREEN_MAIN; //开机动画结束后,默认进入主界面
}
}
void scr_main_run(void)
{
//运行时间显示
runtime_show(); //1000ms
//电池电量显示
battery_show(); //3000ms
//动态曲线绘制
plot_drawing(); //1500ms
//当前输入值/测量值显示已迁移至runtime_show(),两者共用 heart_1000ms_flag
//input_value_show(); //1000ms
//数值闪烁
num_twinkle(); //1000ms
}
void runtime_show(void)
{
if(heart_1000ms_flag)
{
heart_1000ms_flag = 0;
m5data.runtime_seconds ++;
if( m5data.runtime_seconds > 59) //秒溢出
{
m5data.runtime_minutes ++; //溢出后分钟进一
m5data.runtime_seconds = 0;
}
if(m5data.runtime_minutes > 59) //分钟溢出
{
m5data.runtime_hours ++; //溢出后小时进一
m5data.runtime_minutes = 0;
}
if(m5data.runtime_hours > 99) //小时溢出
{
m5data.runtime_seconds = 0; //溢出后全部归零
m5data.runtime_minutes = 0;
m5data.runtime_hours = 0;
}
// 000000该字符串的长度大于8因此runtime_show应该分配大于8的内存
sprintf(m5data.runtime_show, "%02d:%02d:%02d",m5data.runtime_hours, m5data.runtime_minutes, m5data.runtime_seconds);
lv_span_set_text(guider_ui.screen_main_spangroup_time_span, m5data.runtime_show);
input_value_show(); //显示当前测量值
}
}
void battery_show(void)
{
//用于测试显示功能每隔3秒切换一帧动画
if(battery_3000ms_flag)
{
battery_3000ms_flag = 0;
lv_img_set_src(guider_ui.screen_main_animimg_battery, screen_main_animimg_battery_imgs[m5data.battery_cnt]);
m5data.battery_cnt = (m5data.battery_cnt >= 5)?(0):( m5data.battery_cnt + 1);
}
}
//设置游标位置【0000.000】0~7
//中间有个小数点,小数点的显示宽度与数字不同,间隔与两个起点在头文件中设置
// 【】IO_CURSOR_INTERVAL【】IO_CURSOR_INTERVAL【】IO_CURSOR_INTERVAL【】.【】IO_CURSOR_INTERVAL【】IO_CURSOR_INTERVAL【】
// ↑ IO_CURSOR_START1 ↑ IO_CURSOR_START2
void set_cursor_position(void)
{
if(m5data.io_cursor <= 3)
{
lv_obj_set_pos(guider_ui.screen_main_img_cursor, IO_CURSOR_START1 + IO_CURSOR_INTERVAL * m5data.io_cursor, IO_CURSOR_Y);
}
else
{
lv_obj_set_pos(guider_ui.screen_main_img_cursor, IO_CURSOR_START2 + IO_CURSOR_INTERVAL * (m5data.io_cursor - 4), IO_CURSOR_Y);
}
}
//设置数码管符号位0->熄灭1->显示负号
void set_nixie_cube_sign(uint8_t on2off, uint8_t sg)
{
switch (on2off)
{
case IO_INPUT:
{
switch (sg)
{
case 0:
{
//熄灭负号
m5data.sign_flag_in = 0;
lv_img_set_src(guider_ui.screen_main_ani_in_sign, screen_main_ani_in_sign_imgs[0]);
}
break;
case 1:
{
//显示负号
m5data.sign_flag_in = 1;
lv_img_set_src(guider_ui.screen_main_ani_in_sign, screen_main_ani_in_sign_imgs[1]);
}
break;
default:
break;
}
}
break;
case IO_OUTPUT:
{
switch (sg)
{
case 0:
{
//熄灭负号
m5data.sign_flag_out = 0;
lv_img_set_src(guider_ui.screen_main_ani_out_sign, screen_main_ani_out_sign_imgs[0]);
}
break;
case 1:
{
//显示负号
m5data.sign_flag_out = 1;
lv_img_set_src(guider_ui.screen_main_ani_out_sign, screen_main_ani_out_sign_imgs[1]);
}
break;
default:
break;
}
}
break;
default:
break;
}
}
//设置数码管显示值io_slc-输入/输出pos-第几个数字(99代表全部)num->(可正可负)实际数值*1000
void set_nixie_cube(uint8_t io_slc, uint8_t pos, int32_t num)
{
switch (io_slc)
{
case IO_INPUT:
{
switch (pos)
{
case 99:
{
if( (num < 0)&&(m5data.sign_flag_in == 0) )
{
//出现负数并且没有显示负号时
set_nixie_cube_sign(IO_INPUT, 1);
}
else if(( (num >= 0)&&(m5data.sign_flag_in == 1) ))
{
//数值为非负数,但仍然显示负号时
set_nixie_cube_sign(IO_INPUT, 0);
}
num = (m5data.sign_flag_in)?(0 - num):(num);
int32_t temp = 0;
//显示当前测量值,从左往右 0->6
temp = (num/1000000 > 9)?(0):(num/1000000);
lv_img_set_src(guider_ui.screen_main_ani_in_0, screen_main_ani_in_0_imgs[temp]);
temp = (num/100000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_1, screen_main_ani_in_1_imgs[temp]);
temp = (num/10000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_2, screen_main_ani_in_2_imgs[temp]);
temp = (num/1000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_3, screen_main_ani_in_3_imgs[temp]);
temp = (num/100) % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_4, screen_main_ani_in_4_imgs[temp]);
temp = (num/10) % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_5, screen_main_ani_in_5_imgs[temp]);
temp = num % 10;
lv_img_set_src(guider_ui.screen_main_ani_in_6, screen_main_ani_in_6_imgs[temp]);
}
break;
default:
break;
}
}
break;
case IO_OUTPUT:
{
switch (pos)
{
case 0:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_0, screen_main_ani_out_0_imgs[num]);
}
break;
case 1:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_1, screen_main_ani_out_1_imgs[num]);
}
break;
case 2:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_2, screen_main_ani_out_2_imgs[num]);
}
break;
case 3:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_3, screen_main_ani_out_3_imgs[num]);
}
break;
case 4:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_4, screen_main_ani_out_4_imgs[num]);
}
break;
case 5:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_5, screen_main_ani_out_5_imgs[num]);
}
break;
case 6:
{
if(num > 10)
{
num = 10;
}
else if(num < 0)
{
num = 0;
}
lv_img_set_src(guider_ui.screen_main_ani_out_6, screen_main_ani_out_6_imgs[num]);
}
break;
case 99:
{
//负数转正数
num = ( num >= 0 )?(num):(0 - num);
if(num > 9999999)
{
num = 99999999;
}
else if(num < 0)
{
num = 0;
}
int32_t temp = 0;
//显示当前测量值,从左往右 0->6
temp = (num/1000000 > 9)?(0):(num/1000000);
lv_img_set_src(guider_ui.screen_main_ani_out_0, screen_main_ani_out_0_imgs[temp]);
temp = (num/100000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_1, screen_main_ani_out_1_imgs[temp]);
temp = (num/10000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_2, screen_main_ani_out_2_imgs[temp]);
temp = (num/1000) % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_3, screen_main_ani_out_3_imgs[temp]);
temp = (num/100) % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_4, screen_main_ani_out_4_imgs[temp]);
temp = (num/10) % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_5, screen_main_ani_out_5_imgs[temp]);
temp = num % 10;
lv_img_set_src(guider_ui.screen_main_ani_out_6, screen_main_ani_out_6_imgs[temp]);
}
break;
default:
break;
}
}
break;
default:
break;
}
}
//设置当前的输出值((可正可负)实际值*1000 -> 数组)
void set_output_value(int32_t pvo)
{
pvo = (pvo > 0)?(pvo):(0 - pvo);
//将实际值转换成6个独立数字
m5data.o_numbers[0] = (pvo/1000000 > 9)?(9):(pvo/1000000);
m5data.o_numbers[1] = (pvo/100000) % 10;
m5data.o_numbers[2] = (pvo/10000) % 10;
m5data.o_numbers[3] = (pvo/1000) % 10;
m5data.o_numbers[4] = (pvo/100) % 10;
m5data.o_numbers[5] = (pvo/10) % 10;
m5data.o_numbers[6] = pvo % 10;
}
//设置输出值:数字显示 + 符号 + 缓存sto实际值*1000
void set_output(int32_t sto)
{
//显示
set_nixie_cube(IO_OUTPUT, 99, sto);
//缓存
set_output_value(sto);
//符号
if( sto >= 0 )
{
set_nixie_cube_sign(IO_OUTPUT, 0);
}
else
{
set_nixie_cube_sign(IO_OUTPUT, 1);
}
}
//获取当前设定的输出值
float32 get_output_value(void)
{
float32 pvo = 0;
pvo = m5data.o_numbers[0]*1000 + m5data.o_numbers[1]*100 + 10*m5data.o_numbers[2] + \
m5data.o_numbers[3] + m5data.o_numbers[4]*(float32)0.1 + m5data.o_numbers[5]*(float32)0.01 + m5data.o_numbers[6]*(float32)0.001;
pvo = (m5data.sign_flag_out)?(0 - pvo):(pvo);
return pvo;
}
//改变数码管的显示与缓存值dir增加或减少(NIXIE_INCREASE & NIXIE_DECREASEval改变量通常为1
//该函数仅适用于改变前后符号相同的情况
void change_nixie_cube_OUT(uint8_t dir, uint8_t val)
{
switch (dir)
{
case NIXIE_INCREASE:
{
switch (m5data.io_cursor)
{
//达到9之后保持不变不作循环处理
case 0:
{
m5data.o_numbers[0] = (m5data.o_numbers[0] >= 9)?(9):(m5data.o_numbers[0] + val);
set_nixie_cube(IO_OUTPUT, 0, m5data.o_numbers[0]);
}
break;
//当前面第0个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 1:
{
if(m5data.o_numbers[1] >= 9)
{
if( m5data.o_numbers[0]!=9 )
{
m5data.o_numbers[1] = 0;
m5data.overflow_flag_up = 1;
}
else
{
m5data.o_numbers[1] = 9;
}
}else
{
m5data.o_numbers[1] += val;
}
set_nixie_cube(IO_OUTPUT, 1, m5data.o_numbers[1]);
}
break;
//当前面第0~1个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 2:
{
if(m5data.o_numbers[2] >= 9)
{
if( (m5data.o_numbers[0]!=9)||(m5data.o_numbers[1]!=9))
{
m5data.o_numbers[2] = 0;
m5data.overflow_flag_up = 2;
}
else
{
m5data.o_numbers[2] = 9;
}
}else
{
m5data.o_numbers[2] += val;
}
set_nixie_cube(IO_OUTPUT, 2, m5data.o_numbers[2]);
}
break;
//当前面第0~2个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 3:
{
if(m5data.o_numbers[3] >= 9)
{
if( (m5data.o_numbers[0]!=9)||(m5data.o_numbers[1]!=9)||(m5data.o_numbers[2]!=9))
{
m5data.o_numbers[3] = 0;
m5data.overflow_flag_up = 3;
}
else
{
m5data.o_numbers[3] = 9;
}
}else
{
m5data.o_numbers[3] += val;
}
set_nixie_cube(IO_OUTPUT, 3, m5data.o_numbers[3]);
}
break;
//当前面第0~3个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 4:
{
if(m5data.o_numbers[4] >= 9)
{
if( (m5data.o_numbers[0]!=9)||(m5data.o_numbers[1]!=9)||(m5data.o_numbers[2]!=9)||(m5data.o_numbers[3]!=9))
{
m5data.o_numbers[4] = 0;
m5data.overflow_flag_up = 4;
}
else
{
m5data.o_numbers[4] = 9;
}
}else
{
m5data.o_numbers[4] += val;
}
set_nixie_cube(IO_OUTPUT, 4, m5data.o_numbers[4]);
}
break;
//当前面第0~4个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 5:
{
if(m5data.o_numbers[5] >= 9)
{
if( (m5data.o_numbers[0]!=9)||(m5data.o_numbers[1]!=9)||(m5data.o_numbers[2]!=9)||(m5data.o_numbers[3]!=9)||(m5data.o_numbers[4]!=9))
{
m5data.o_numbers[5] = 0;
m5data.overflow_flag_up = 5;
}
else
{
m5data.o_numbers[5] = 9;
}
}else
{
m5data.o_numbers[5] += val;
}
set_nixie_cube(IO_OUTPUT, 5, m5data.o_numbers[5]);
}
break;
//当前面第0~5个数字不全为9时循环计数溢出标志置1否则保持9不变。
case 6:
{
if(m5data.o_numbers[6] >= 9)
{
if( (m5data.o_numbers[0]!=9)||(m5data.o_numbers[1]!=9)||(m5data.o_numbers[2]!=9)||(m5data.o_numbers[3]!=9)||(m5data.o_numbers[4]!=9)||(m5data.o_numbers[5]!=9))
{
m5data.o_numbers[6] = 0;
m5data.overflow_flag_up = 6;
}
else
{
m5data.o_numbers[6] = 9;
}
}else
{
m5data.o_numbers[6] += val;
}
set_nixie_cube(IO_OUTPUT, 6, m5data.o_numbers[6]);
}
break;
default:
break;
}
//发生向上溢出时,根据溢出的位置对实际数值进行处理
if(m5data.overflow_flag_up)
{
int32_t oftemp = 0;
//还原成实际数值
oftemp = 1000000*m5data.o_numbers[0] + 100000*m5data.o_numbers[1] + 10000*m5data.o_numbers[2] + \
1000*m5data.o_numbers[3] + 100*m5data.o_numbers[4] + 10*m5data.o_numbers[5] + m5data.o_numbers[6];
//根据溢出的位置对实际值进行计算
oftemp += my_power(10, ( 7 - m5data.overflow_flag_up) );
set_nixie_cube(IO_OUTPUT, 99, oftemp);
set_output_value(oftemp);
//溢出处理完成,标志清零
m5data.overflow_flag_up = 0;
}
}
break;
case NIXIE_DECREASE:
{
switch (m5data.io_cursor)
{
case 0:
{
if(m5data.o_numbers[0] <= 0)
{
m5data.o_numbers[0] = 0;
}
else
{
m5data.o_numbers[0] -= val;
}
set_nixie_cube(IO_OUTPUT, 0, m5data.o_numbers[0]);
}
break;
case 1:
{
if(m5data.o_numbers[1] <= 0)
{
if(m5data.o_numbers[0])
{
m5data.o_numbers[1] = 9;
m5data.overflow_flag_low = 1;
}
else
{
m5data.o_numbers[1] = 0;
}
}
else
{
m5data.o_numbers[1] -= val;
}
set_nixie_cube(IO_OUTPUT, 1, m5data.o_numbers[1]);
}
break;
case 2:
{
if(m5data.o_numbers[2] <= 0)
{
if(m5data.o_numbers[0]||m5data.o_numbers[1])
{
m5data.o_numbers[2] = 9;
m5data.overflow_flag_low = 2;
}
else
{
m5data.o_numbers[2] = 0;
}
}
else
{
m5data.o_numbers[2] -= val;
}
set_nixie_cube(IO_OUTPUT, 2, m5data.o_numbers[2]);
}
break;
case 3:
{
if(m5data.o_numbers[3] <= 0)
{
if(m5data.o_numbers[0]||m5data.o_numbers[1]||m5data.o_numbers[2])
{
m5data.o_numbers[3] = 9;
m5data.overflow_flag_low = 3;
}
else
{
m5data.o_numbers[3] = 0;
}
}
else
{
m5data.o_numbers[3] -= val;
}
set_nixie_cube(IO_OUTPUT, 3, m5data.o_numbers[3]);
}
break;
case 4:
{
if(m5data.o_numbers[4] <= 0)
{
if(m5data.o_numbers[0]||m5data.o_numbers[1]||m5data.o_numbers[2]||m5data.o_numbers[3])
{
m5data.o_numbers[4] = 9;
m5data.overflow_flag_low = 4;
}
else
{
m5data.o_numbers[4] = 0;
}
}
else
{
m5data.o_numbers[4] -= val;
}
set_nixie_cube(IO_OUTPUT, 4, m5data.o_numbers[4]);
}
break;
case 5:
{
if(m5data.o_numbers[5] <= 0)
{
if(m5data.o_numbers[0]||m5data.o_numbers[1]||m5data.o_numbers[2]||m5data.o_numbers[3]||m5data.o_numbers[4])
{
m5data.o_numbers[5] = 9;
m5data.overflow_flag_low = 5;
}
else
{
m5data.o_numbers[5] = 0;
}
}
else
{
m5data.o_numbers[5] -= val;
}
set_nixie_cube(IO_OUTPUT, 5, m5data.o_numbers[5]);
}
break;
case 6:
{
if(m5data.o_numbers[6] <= 0)
{
if(m5data.o_numbers[0]||m5data.o_numbers[1]||m5data.o_numbers[2]||m5data.o_numbers[3]||m5data.o_numbers[4]||m5data.o_numbers[5])
{
m5data.o_numbers[6] = 9;
m5data.overflow_flag_low = 6;
}
else
{
m5data.o_numbers[6] = 0;
}
}
else
{
m5data.o_numbers[6] -= val;
}
set_nixie_cube(IO_OUTPUT, 6, m5data.o_numbers[6]);
}
break;
default:
break;
}
//向下溢出处理
if(m5data.overflow_flag_low)
{
int32_t oftemp = 0;
oftemp = 1000000*m5data.o_numbers[0] + 100000*m5data.o_numbers[1] + 10000*m5data.o_numbers[2] + \
1000*m5data.o_numbers[3] + 100*m5data.o_numbers[4] + 10*m5data.o_numbers[5] + m5data.o_numbers[6];
oftemp -= my_power(10, ( 7 - m5data.overflow_flag_low) );
//更新数码管显示
set_nixie_cube(IO_OUTPUT, 99, oftemp);
//更新数码管数组
set_output_value(oftemp);
//溢出标志清零
m5data.overflow_flag_low = 0;
}
}
break;
default:
break;
}
}
//设置工作模式和工作模式类型
void set_working_mode(SIG_FUNCTIONS mode, SIG_FUNCTIONS_TYPE type)
{
//为保障安全,切换工作模式后:功能关闭,输入输出值清零
//{
//功能关闭
m5data.io_on2off = IO_OFF;
//数码管参数清零
for(uint8_t i = 0; i < 7; i++) //用于数值显示的数组初值为0
{
m5data.i_numbers[i] = 0; //输入值/测量值
}
set_nixie_cube(IO_INPUT, 99, 0);
set_output(0);
m5data.io_cursor = 3;
m5data.io_cursor_prv = 3;
set_cursor_position();
//闪烁参数清零
m5data.twk_flag = 0; //闪烁中止
m5data.twk_cnt = 0; //闪烁计数清零
m5data.twk_flip = 0; //0显示1不显示
//曲线绘图值清零
pltdata.yreal_scd_value = 0;
pltdata.yreal_scd_value_prv = 0;
//}
switch (mode)
{
//电压
case SIG_VOLTAGE:
{
lv_label_set_text(guider_ui.screen_main_label_Mode, "Volt");
switch (type)
{
case VOLTAGE_MV:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "mV");
pltdata.yreal_pri_up = VOL[1].up;
pltdata.yreal_scd_up = VOL[1].up;
pltdata.yreal_pri_low = VOL[1].low;
pltdata.yreal_scd_low = VOL[1].low;
}
break;
case VOLTAGE_V:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "V");
pltdata.yreal_pri_up = VOL[0].up;
pltdata.yreal_scd_up = VOL[0].up;
pltdata.yreal_pri_low = VOL[0].low;
pltdata.yreal_scd_low = VOL[0].low;
}
break;
default:
break;
}
}
break;
//电流
case SIG_CURRENT:
{
lv_label_set_text(guider_ui.screen_main_label_Mode, "Cur");
switch (type)
{
case CURRENT_MA:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "mA");
pltdata.yreal_pri_up = CUR.up;
pltdata.yreal_scd_up = CUR.up;
pltdata.yreal_pri_low = CUR.low;
pltdata.yreal_scd_low = CUR.low;
}
break;
default:
break;
}
}
break;
//电阻
case SIG_RESISTANT:
{
lv_label_set_text(guider_ui.screen_main_label_Mode, "Res");
switch (type)
{
case RESISTANT_OHM:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "Ω");
pltdata.yreal_pri_up = RES.up;
pltdata.yreal_scd_up = RES.up;
pltdata.yreal_pri_low = RES.low;
pltdata.yreal_scd_low = RES.low;
}
break;
default:
break;
}
}
break;
//频率
case SIG_FREQUENCE:
{
lv_label_set_text(guider_ui.screen_main_label_Mode, "Fre");
switch (type)
{
case FREQUENCE_KHZ:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "KHz");
pltdata.yreal_pri_up = FRE.up;
pltdata.yreal_scd_up = FRE.up;
pltdata.yreal_pri_low = FRE.low;
pltdata.yreal_scd_low = FRE.low;
}
break;
default:
break;
}
}
break;
//热电偶
case SIG_TC:
{
//-250~1820℃
lv_label_set_text(guider_ui.screen_main_label_Mode, "Tc");
switch (type)
{
case TC_K:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "K ℃");
pltdata.yreal_pri_up = TC[0].up;
pltdata.yreal_scd_up = TC[0].up;
pltdata.yreal_pri_low = TC[0].low;
pltdata.yreal_scd_low = TC[0].low;
}
break;
case TC_N:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "N ℃");
pltdata.yreal_pri_up = TC[1].up;
pltdata.yreal_scd_up = TC[1].up;
pltdata.yreal_pri_low = TC[1].low;
pltdata.yreal_scd_low = TC[1].low;
}
break;
case TC_S:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "S ℃");
pltdata.yreal_pri_up = TC[2].up;
pltdata.yreal_scd_up = TC[2].up;
pltdata.yreal_pri_low = TC[2].low;
pltdata.yreal_scd_low = TC[2].low;
}
break;
default:
break;
}
}
break;
//热电阻
case SIG_RTD:
{
//-200~850℃
lv_label_set_text(guider_ui.screen_main_label_Mode, "RTD");
switch (type)
{
case RTD_DC:
{
lv_label_set_text(guider_ui.screen_main_label_unit, "");
pltdata.yreal_pri_up = RTD.up;
pltdata.yreal_scd_up = RTD.up;
pltdata.yreal_pri_low = RTD.low;
pltdata.yreal_scd_low = RTD.low;
}
break;
default:
break;
}
}
break;
default:
break;
}
//当前输入数值更新为新的上下限
pltdata.yreal_scd_value = pltdata.yreal_scd_low;
pltdata.yreal_scd_value_prv = pltdata.yreal_scd_low;
set_nixie_cube(IO_INPUT, 99, pltdata.yreal_scd_low*1000);
//当前输出数值更新为新的上下限
set_output(pltdata.yreal_pri_low*1000);
}
void input_value_show(void)
{
if( MY_ABS(pltdata.yreal_scd_value - pltdata.yreal_scd_value_prv) < (float32)0.01)
{
//变化值过小的情况下不更新显示内容
return;
}
else
{
//记录前一时刻的值,用于计算变化量
pltdata.yreal_scd_value_prv = pltdata.yreal_scd_value;
}
int32_t pvi = 0;
//输入显示限幅
if(pltdata.yreal_scd_value >= pltdata.yreal_scd_up)
{
pvi = pltdata.yreal_scd_up*1000;
}
else if (pltdata.yreal_scd_value <= pltdata.yreal_scd_low)
{
pvi = pltdata.yreal_scd_low*1000;
}
else
{
pvi = (int32_t)(pltdata.yreal_scd_value * 1000); //副轴用于绘制实时输入测量值
}
set_nixie_cube(IO_INPUT, 99, pvi);
}
void io_on2off_status(void)
{
switch (m5data.io_on2off)
{
case IO_ON:
{
switch (m5data.io_mode)
{
case IO_OUTPUT:
{
//输入变回黑色,输出变为绿色
lv_obj_set_style_text_color(guider_ui.screen_main_label_IN, lv_color_hex(0x000000), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_set_style_text_color(guider_ui.screen_main_label_OUT, lv_color_hex(0x06ff00), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case IO_INPUT:
{
//输出变回黑色,输入变为绿色
lv_obj_set_style_text_color(guider_ui.screen_main_label_IN, lv_color_hex(0x06ff00), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_set_style_text_color(guider_ui.screen_main_label_OUT, lv_color_hex(0x000000), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
default:
break;
}
}
break;
case IO_OFF:
{
switch (m5data.io_mode)
{
case IO_OUTPUT:
{
//输入变回黑色,输出变为红色
lv_obj_set_style_text_color(guider_ui.screen_main_label_IN, lv_color_hex(0x000000), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_set_style_text_color(guider_ui.screen_main_label_OUT, lv_color_hex(0xff0027), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case IO_INPUT:
{
//输出变回黑色,输入变为红色
lv_obj_set_style_text_color(guider_ui.screen_main_label_IN, lv_color_hex(0x06ff00), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_set_style_text_color(guider_ui.screen_main_label_OUT, lv_color_hex(0x000000), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
default:
break;
}
}
break;
default:
break;
}
}
//KEY_SETTING
void key_functions_setting(void)
{
switch (key)
{
case KEY_BACK:
{
key = 0;
//所有选项卡均未选中时,返回主界面,否则熄灭当前选中
if(tabdata.tab_cursor_inner == 99)
{
//下次进入设置页面时从选项卡0开始
tabdata.tab_cursor = 0;
//加载主界面
setup_scr_screen_main(&guider_ui);
lv_scr_load(guider_ui.screen_main);
//切换至菜单后,清除主界面对象,释放内存
lv_obj_del(guider_ui.screen_setting);
//当前界面为主界面
m5data.scr_now = SCREEN_MAIN;
//恢复之前显示的数据
scr_main_recover();
}
else
{
//某个选项卡被选中时,熄灭内部选中的内容
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
//熄灭当前内容
setting_items_check(99, tabdata.tab_cursor_inner, 1);
tabdata.tab_cursor_inner = 99;
tabdata.tab_cursor_inner_prv = 99;
}
break;
case ITEMS_1:
{
tabdata.tab_cursor_inner = 99;
tabdata.tab_cursor_inner_prv = 99;
}
break;
case ITEMS_2:
{
tabdata.tab_cursor_inner = 99;
tabdata.tab_cursor_inner_prv = 99;
}
break;
case ITEMS_3:
{
tabdata.tab_cursor_inner = 99;
tabdata.tab_cursor_inner_prv = 99;
}
break;
default:
break;
}
}
}
break;
case KEY_UP:
{
key = 0;
//内部游标为99时说明未选中任何一个选项卡此时的up和down用于切换选项卡
if(tabdata.tab_cursor_inner == 99)
{
tabdata.tab_cursor_prv = tabdata.tab_cursor;
tabdata.tab_cursor = (tabdata.tab_cursor <= 0)?(3):(tabdata.tab_cursor - 1);
setting_items_check(tabdata.tab_cursor, tabdata.tab_cursor_prv, 0);
}
else
{ //选中某一选项卡后,对选项卡内部的内容进行选择
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
switch (tabdata.tab_cursor_inner)
{
case CONTENT_0_0:
{
if(tabdata.content00 == VOLTAGE_V)
{
tabdata.content00 = VOLTAGE_MV;
}
else
{
tabdata.content00 = VOLTAGE_V;
}
//单位改变时,相关数值也要跟随
setting_update(ITEMS_0, CONTENT_0_0);
setting_update(ITEMS_0, CONTENT_0_1);
setting_update(ITEMS_0, CONTENT_0_2);
}
break;
case CONTENT_0_1:
{
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
tabdata.content01[1] = (tabdata.content01[1] >= VOL[1].up)?(tabdata.content02[1]):(tabdata.content01[1] + 1);
}
break;
case VOLTAGE_V:
{
tabdata.content01[0] = (tabdata.content01[0] >= VOL[0].up)?(tabdata.content02[0]):(tabdata.content01[0] + 1);
}
break;
default:
break;
}
setting_update(ITEMS_0, CONTENT_0_1);
}
break;
case CONTENT_0_2:
{
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
tabdata.content02[1] = (tabdata.content02[1] >= tabdata.content01[1])?(VOL[1].low):(tabdata.content02[1] + 1);
}
break;
case VOLTAGE_V:
{
tabdata.content02[0] = (tabdata.content02[0] >= tabdata.content01[0])?(VOL[0].low):(tabdata.content02[0] + 1);
}
break;
default:
break;
}
setting_update(ITEMS_0, CONTENT_0_2);
}
break;
default:
break;
}
}
break;
case ITEMS_1:
{
}
break;
case ITEMS_2:
{
}
break;
case ITEMS_3:
{
}
break;
default:
break;
}
}
}
break;
case KEY_DOWN:
{
key = 0;
if(tabdata.tab_cursor_inner == 99)
{
tabdata.tab_cursor_prv = tabdata.tab_cursor;
tabdata.tab_cursor = (tabdata.tab_cursor >= 3)?(0):(tabdata.tab_cursor + 1);
setting_items_check(tabdata.tab_cursor, tabdata.tab_cursor_prv, 0);
}
else
{
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
}
break;
case ITEMS_1:
{
}
break;
case ITEMS_2:
{
}
break;
case ITEMS_3:
{
}
break;
default:
break;
}
}
}
break;
case KEY_OK:
{
key = 0;
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
if(tabdata.tab_cursor_inner == 99)
{
tabdata.tab_cursor_inner = 0;
tabdata.tab_cursor_inner_prv = 0;
setting_items_check(tabdata.tab_cursor_inner, 99, 1);
}
else
{
}
}
break;
case ITEMS_1:
{
tabdata.tab_cursor_inner = 0;
}
break;
case ITEMS_2:
{
tabdata.tab_cursor_inner = 0;
}
break;
case ITEMS_3:
{
tabdata.tab_cursor_inner = 0;
}
break;
default:
break;
}
}
break;
case KEY_LEFT:
{
key = 0;
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
tabdata.tab_cursor_inner_prv = tabdata.tab_cursor_inner;
tabdata.tab_cursor_inner = (tabdata.tab_cursor_inner <= 0)?(2):(tabdata.tab_cursor_inner - 1);
setting_items_check(tabdata.tab_cursor_inner, tabdata.tab_cursor_inner_prv, 1);
}
break;
case ITEMS_1:
{}
break;
case ITEMS_2:
{}
break;
case ITEMS_3:
{
}
break;
default:
break;
}
}
break;
case KEY_RIGHT:
{
key = 0;
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
tabdata.tab_cursor_inner_prv = tabdata.tab_cursor_inner;
tabdata.tab_cursor_inner = (tabdata.tab_cursor_inner >= 2)?(0):(tabdata.tab_cursor_inner + 1);
setting_items_check(tabdata.tab_cursor_inner, tabdata.tab_cursor_inner_prv, 1);
}
break;
case ITEMS_1:
{}
break;
case ITEMS_2:
{}
break;
case ITEMS_3:
{
}
break;
default:
break;
}
}
break;
default:
{
key = 0;
}
break;
}
}
void setting_items_check(uint8_t cursor, uint8_t cursor_prv, uint8_t tab_cont)
{
//需要操作的是内容还是选项卡
if(tab_cont)
{
//操作内容
switch (tabdata.tab_cursor)
{
case ITEMS_0:
{
switch (cursor) //点亮cursor
{
case 0:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_01, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case 1:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_03, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case 2:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_05, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
default:
break;
}
switch (cursor_prv) //熄灭cursor_prv
{
case 0:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_01, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case 1:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_03, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case 2:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_05, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
default:
break;
}
}
break;
case ITEMS_1:
{
}
break;
case ITEMS_2:
{
}
break;
case ITEMS_3:
{
}
break;
default:
break;
}
}
else
{
//操作选项卡
switch (cursor) //点亮当前选中目标
{
case ITEMS_0:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s0, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_clear_flag(guider_ui.screen_setting_label_01, LV_OBJ_FLAG_HIDDEN);
lv_obj_clear_flag(guider_ui.screen_setting_label_03, LV_OBJ_FLAG_HIDDEN);
lv_obj_clear_flag(guider_ui.screen_setting_label_05, LV_OBJ_FLAG_HIDDEN);
}
break;
case ITEMS_1:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s1, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_add_flag(guider_ui.screen_setting_label_01, LV_OBJ_FLAG_HIDDEN);
}
break;
case ITEMS_2:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s2, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_add_flag(guider_ui.screen_setting_label_03, LV_OBJ_FLAG_HIDDEN);
}
break;
case ITEMS_3:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s3, lv_color_hex(0xcbefff), LV_PART_MAIN|LV_STATE_DEFAULT);
lv_obj_add_flag(guider_ui.screen_setting_label_05, LV_OBJ_FLAG_HIDDEN);
}
break;
default:
break;
}
switch (cursor_prv) //熄灭前一时刻的目标
{
case ITEMS_0:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s0, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case ITEMS_1:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s1, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case ITEMS_2:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s2, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
case ITEMS_3:
{
lv_obj_set_style_bg_color(guider_ui.screen_setting_label_s3, lv_color_hex(0xffffff), LV_PART_MAIN|LV_STATE_DEFAULT);
}
break;
default:
break;
}
}
}
void setting_update(uint8_t ite, uint8_t con)
{
char str_temp[10];
switch (ite)
{
case ITEMS_0:
{
switch (con)
{
case CONTENT_0_0:
{
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
lv_label_set_text(guider_ui.screen_setting_label_01, "mV");
}
break;
case VOLTAGE_V:
{
lv_label_set_text(guider_ui.screen_setting_label_01, "V");
}
break;
default:
break;
}
}
break;
case CONTENT_0_1:
{
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
sprintf(str_temp,"%d",tabdata.content01[1]);
lv_label_set_text(guider_ui.screen_setting_label_03, str_temp);
VOL[1].up = tabdata.content01[1];
}
break;
case VOLTAGE_V:
{
sprintf(str_temp,"%d",tabdata.content01[0]);
lv_label_set_text(guider_ui.screen_setting_label_03, str_temp);
VOL[0].up = tabdata.content01[0];
}
break;
default:
break;
}
}
break;
case CONTENT_0_2:
{
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
sprintf(str_temp,"%d",tabdata.content02[1]);
lv_label_set_text(guider_ui.screen_setting_label_05, str_temp);
VOL[1].low = tabdata.content02[1];
}
break;
case VOLTAGE_V:
{
sprintf(str_temp,"%d",tabdata.content02[0]);
lv_label_set_text(guider_ui.screen_setting_label_05, str_temp);
VOL[0].low = tabdata.content02[0];
}
break;
default:
break;
}
}
break;
default:
break;
}
}
break;
case ITEMS_1:
{}
break;
case ITEMS_2:
{}
break;
case ITEMS_3:
{}
break;
default:
break;
}
}
void scr_main_recover(void)
{
// 运行时间 和 电池电量 在主界面的函数中已存在,无需额外恢复
// 曲线需要在 setup_scr_screen_main.c 中修改
io_on2off_status(); //IN&OUT, ON&OFF
//输入&输出、工作模式&类型
switch (m5data.io_mode) //输入、输出模式切换
{
case IO_OUTPUT:
{
set_working_mode(m5data.output_mode, m5data.output_mode_type);
}
break;
case IO_INPUT:
{
set_working_mode(m5data.input_mode, m5data.input_mode_type);
}
break;
default:
break;
}
}
void num_twinkle(void) //数值闪烁
{
if(m5data.twk_flag == 0)
{
//不需要闪烁的情况下直接返回
return;
}
else
{
if(twk_1000ms_flag)
{
twk_1000ms_flag = 0;
//闪烁开始
switch (m5data.io_cursor) //闪烁指定位置
{
case 0:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 0, m5data.o_numbers[0]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 0, 10);
m5data.twk_flip = 1;
}
}
break;
case 1:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 1, m5data.o_numbers[1]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 1, 10);
m5data.twk_flip = 1;
}
}
break;
case 2:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 2, m5data.o_numbers[2]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 2, 10);
m5data.twk_flip = 1;
}
}
break;
case 3:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT,3, m5data.o_numbers[3]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 3, 10);
m5data.twk_flip = 1;
}
}
break;
case 4:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 4, m5data.o_numbers[4]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 4, 10);
m5data.twk_flip = 1;
}
}
break;
case 5:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 5, m5data.o_numbers[5]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 5, 10);
m5data.twk_flip = 1;
}
}
break;
case 6:
{
if(m5data.twk_flip)
{
set_nixie_cube(IO_OUTPUT, 6, m5data.o_numbers[6]);
m5data.twk_flip = 0;
}else
{
set_nixie_cube(IO_OUTPUT, 6, 10);
m5data.twk_flip = 1;
}
}
break;
default:
break;
}
m5data.twk_cnt++;
}
}
if(m5data.twk_cnt > TWINKLE_CNT_MAX) // TWINKLE_CNT_MAX秒无动作上、下、左、右无按下后停止闪烁
{
m5data.twk_cnt = 0;
m5data.twk_flip = 0;
m5data.twk_flag = 0;
m5data.io_cursor_prv = m5data.io_cursor;
switch (m5data.io_cursor) //防止空白残留
{
case 0:
{
set_nixie_cube(IO_OUTPUT, 0, m5data.o_numbers[0]);
}
break;
case 1:
{
set_nixie_cube(IO_OUTPUT, 1, m5data.o_numbers[1]);
}
break;
case 2:
{
set_nixie_cube(IO_OUTPUT, 2, m5data.o_numbers[2]);
}
break;
case 3:
{
set_nixie_cube(IO_OUTPUT, 3, m5data.o_numbers[3]);
}
break;
case 4:
{
set_nixie_cube(IO_OUTPUT, 4, m5data.o_numbers[4]);
}
break;
case 5:
{
set_nixie_cube(IO_OUTPUT, 5, m5data.o_numbers[5]);
}
break;
case 6:
{
set_nixie_cube(IO_OUTPUT, 6, m5data.o_numbers[6]);
}
break;
default:
break;
}
}
}
//实时曲线绘制
//将实际值线性转换成绘图值
void plot_drawing(void)
{
if(plot_1500ms_flag)
{
plot_1500ms_flag = 0;
//输出曲线
//{
//将独立数字转换成实际值
pltdata.yreal_pri_value = get_output_value();
//改变之前先记录前一时刻的绘图值
pltdata.y_pri_value_prv = pltdata.y_pri_value;
//将实际值线性转换成chart组件上的绘图值pltdata.y_pri_low~up一般0~100
pltdata.y_pri_value = ( pltdata.y_pri_up - pltdata.y_pri_low ) * \
( pltdata.yreal_pri_value - pltdata.yreal_pri_low ) / ( pltdata.yreal_pri_up - pltdata.yreal_pri_low );
if( MY_ABS(pltdata.y_pri_value - pltdata.y_pri_value_prv) < 1 )
{
//变化幅度小的情况下不更新显示值
//等待一段时间后不再更新
if(pltdata.pri_wait_tick < PLOT_WAIT_TICK_MAX)
{
pltdata.pri_wait_tick++;
//数值限幅
if(pltdata.y_pri_value >= pltdata.y_pri_up) pltdata.y_pri_value = pltdata.y_pri_up;
if(pltdata.y_pri_value <= pltdata.y_pri_low) pltdata.y_pri_value = pltdata.y_pri_low;
lv_chart_set_next_value(guider_ui.screen_main_chart_1, guider_ui.screen_main_chart_1_0, pltdata.y_pri_value);
}
}
else
{
//变化幅度较大时,等待计数清零
pltdata.pri_wait_tick = 0;
//数值限幅
if(pltdata.y_pri_value >= pltdata.y_pri_up) pltdata.y_pri_value = pltdata.y_pri_up;
if(pltdata.y_pri_value <= pltdata.y_pri_low) pltdata.y_pri_value = pltdata.y_pri_low;
lv_chart_set_next_value(guider_ui.screen_main_chart_1, guider_ui.screen_main_chart_1_0, pltdata.y_pri_value);
}
//}
//输入曲线
//{
//改变之前先记录前一时刻的绘图值
pltdata.y_scd_value_prv = pltdata.y_scd_value;
//将实际值线性转换成chart组件上的绘图值pltdata.y_pri_low~up一般0~100
pltdata.y_scd_value = ( pltdata.y_scd_up - pltdata.y_scd_low ) * \
( pltdata.yreal_scd_value - pltdata.yreal_scd_low ) / ( pltdata.yreal_scd_up - pltdata.yreal_scd_low );
if( MY_ABS(pltdata.y_scd_value - pltdata.y_scd_value_prv) < 1 )
{
//变化幅度小的情况下不更新显示值
//等待一段时间后不再更新
if(pltdata.scd_wait_tick < PLOT_WAIT_TICK_MAX)
{
pltdata.scd_wait_tick++;
//数值限幅
if(pltdata.y_scd_value >= pltdata.y_scd_up) pltdata.y_scd_value = pltdata.y_scd_up;
if(pltdata.y_scd_value <= pltdata.y_scd_low) pltdata.y_scd_value = pltdata.y_scd_low;
lv_chart_set_next_value(guider_ui.screen_main_chart_1, guider_ui.screen_main_chart_1_1, pltdata.y_scd_value);
}
}
else
{
pltdata.scd_wait_tick = 0;
//数值限幅
if(pltdata.y_scd_value >= pltdata.y_scd_up) pltdata.y_scd_value = pltdata.y_scd_up;
if(pltdata.y_scd_value <= pltdata.y_scd_low) pltdata.y_scd_value = pltdata.y_scd_low;
lv_chart_set_next_value(guider_ui.screen_main_chart_1, guider_ui.screen_main_chart_1_1, pltdata.y_scd_value);
}
//}
}
}
void scr_setting_recover(void)
{
//在这里恢复选项卡0的显示内容
//ITEMS_0
char str_temp[10];
switch (tabdata.content00)
{
case VOLTAGE_MV:
{
lv_label_set_text(guider_ui.screen_setting_label_01, "mV");
sprintf(str_temp,"%d",tabdata.content01[1]);
lv_label_set_text(guider_ui.screen_setting_label_03, str_temp);
sprintf(str_temp,"%d",tabdata.content02[1]);
lv_label_set_text(guider_ui.screen_setting_label_05, str_temp);
}
break;
case VOLTAGE_V:
{
lv_label_set_text(guider_ui.screen_setting_label_01, "V");
sprintf(str_temp,"%d",tabdata.content01[0]);
lv_label_set_text(guider_ui.screen_setting_label_03, str_temp);
sprintf(str_temp,"%d",tabdata.content02[0]);
lv_label_set_text(guider_ui.screen_setting_label_05, str_temp);
}
break;
default:
break;
}
}
//计算a的b次方
float32 my_power(int a, int b)
{
if(a == 0)
{
return 0;
}
if(b == 0)
{
return 1;
}
float32 result = 1;
if( b > 0 )
{
for(uint8_t i = 0; i < b; i++)
{
result *= a;
}
}
else
{
for(uint8_t i = 0; i < b; i++)
{
result /= (float32)a;
}
}
return result;
}
void scr_setting_run(void) //详细设置界面
{
}
/**********test5**********/
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