Merge branch 'develop' into notify-battery-level

# Conflicts:
#	src/displayapp/screens/BatteryInfo.cpp
This commit is contained in:
Jean-François Milants 2021-07-13 20:31:26 +02:00
commit 3e70554844
4 changed files with 50 additions and 37 deletions

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@ -53,6 +53,7 @@ As of now, here is the list of achievements of this project:
* Two (2048 clone game)
* Stopwatch (with all the necessary functions such as play, pause, lap, stop)
* Motion sensor and step counter (displays the number of steps and the state of the motion sensor in real-time)
* Metronome (vibrates to a given bpm with a customizable beats per bar)
- User settings:
* Display timeout
* Wake-up condition

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@ -27,7 +27,7 @@ CMake configures the project according to variables you specify the command line
**NRFJPROG**|Path to the NRFJProg executable. Used only if `USE_JLINK` is 1.|`-DNRFJPROG=/opt/nrfjprog/nrfjprog`
**GDB_CLIENT_BIN_PATH**|Path to arm-none-eabi-gdb executable. Used only if `USE_GDB_CLIENT` is 1.|`-DGDB_CLIENT_BIN_PATH=/home/jf/nrf52/gcc-arm-none-eabi-9-2019-q4-major/bin/arm-none-eabi-gdb`
**GDB_CLIENT_TARGET_REMOTE**|Target remote connection string. Used only if `USE_GDB_CLIENT` is 1.|`-DGDB_CLIENT_TARGET_REMOTE=/dev/ttyACM0`
**BUILD_DFU (\*\*)**|Build DFU files while building (needs [adafruit-nrfutil](https://github.com/adafruit/Adafruit_nRF52_nrfutil)).|`-BUILD_DFU=1`
**BUILD_DFU (\*\*)**|Build DFU files while building (needs [adafruit-nrfutil](https://github.com/adafruit/Adafruit_nRF52_nrfutil)).|`-DBUILD_DFU=1`
####(**) Note about **CMAKE_BUILD_TYPE**:
By default, this variable is set to *Release*. It compiles the code with size and speed optimizations. We use this value for all the binaries we publish when we [release](https://github.com/JF002/InfiniTime/releases) new versions of InfiniTime.

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@ -95,16 +95,16 @@ void BatteryInfo::UpdateScreen() {
if (batteryController.IsCharging() and batteryPercent < 100) {
lv_obj_set_style_local_bg_color(charging_bar, LV_BAR_PART_INDIC, LV_STATE_DEFAULT, LV_COLOR_RED);
lv_label_set_text_static(status, "Battery charging");
lv_label_set_text_static(status, "Charging");
} else if (batteryPercent == 100) {
lv_obj_set_style_local_bg_color(charging_bar, LV_BAR_PART_INDIC, LV_STATE_DEFAULT, LV_COLOR_BLUE);
lv_label_set_text_static(status, "Battery is fully charged");
lv_label_set_text_static(status, "Fully charged");
} else if (batteryPercent < 10) {
lv_obj_set_style_local_bg_color(charging_bar, LV_BAR_PART_INDIC, LV_STATE_DEFAULT, LV_COLOR_YELLOW);
lv_label_set_text_static(status, "Battery is low");
lv_label_set_text_static(status, "Battery low");
} else {
lv_obj_set_style_local_bg_color(charging_bar, LV_BAR_PART_INDIC, LV_STATE_DEFAULT, LV_COLOR_GREEN);
lv_label_set_text_static(status, "Battery discharging");
lv_label_set_text_static(status, "Discharging");
}
lv_label_set_text_fmt(percent, "%02i%%", batteryPercent);

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@ -5,27 +5,44 @@
#include "Symbols.h"
#include "NotificationIcon.h"
#include <cmath>
LV_IMG_DECLARE(bg_clock);
using namespace Pinetime::Applications::Screens;
#define HOUR_LENGTH 70
#define MINUTE_LENGTH 90
#define SECOND_LENGTH 110
#define PI 3.14159265358979323846
namespace {
// ##
static int16_t coordinate_x_relocate(int16_t x) {
return ((x) + LV_HOR_RES / 2);
constexpr auto HOUR_LENGTH = 70;
constexpr auto MINUTE_LENGTH = 90;
constexpr auto SECOND_LENGTH = 110;
// sin(90) = 1 so the value of _lv_trigo_sin(90) is the scaling factor
const auto LV_TRIG_SCALE = _lv_trigo_sin(90);
int16_t cosine(int16_t angle) {
return _lv_trigo_sin(angle + 90);
}
// ##
static int16_t coordinate_y_relocate(int16_t y) {
return (((y) -LV_HOR_RES / 2) < 0) ? (0 - ((y) -LV_HOR_RES / 2)) : ((y) -LV_HOR_RES / 2);
int16_t sine(int16_t angle) {
return _lv_trigo_sin(angle);
}
int16_t coordinate_x_relocate(int16_t x) {
return (x + LV_HOR_RES / 2);
}
int16_t coordinate_y_relocate(int16_t y) {
return std::abs(y - LV_HOR_RES / 2);
}
lv_point_t coordinate_relocate(int16_t radius, int16_t angle) {
return lv_point_t{
.x = coordinate_x_relocate(radius * static_cast<int32_t>(sine(angle)) / LV_TRIG_SCALE),
.y = coordinate_y_relocate(radius * static_cast<int32_t>(cosine(angle)) / LV_TRIG_SCALE)
};
}
} // namespace
WatchFaceAnalog::WatchFaceAnalog(Pinetime::Applications::DisplayApp* app,
Controllers::DateTime& dateTimeController,
Controllers::Battery& batteryController,
@ -123,15 +140,12 @@ void WatchFaceAnalog::UpdateClock() {
second = dateTimeController.Seconds();
if (sMinute != minute) {
minute_point[0].x = coordinate_x_relocate(30 * sin(minute * 6 * PI / 180));
minute_point[0].y = coordinate_y_relocate(30 * cos(minute * 6 * PI / 180));
minute_point[1].x = coordinate_x_relocate(MINUTE_LENGTH * sin(minute * 6 * PI / 180));
minute_point[1].y = coordinate_y_relocate(MINUTE_LENGTH * cos(minute * 6 * PI / 180));
auto const angle = minute * 6;
minute_point[0] = coordinate_relocate(30, angle);
minute_point[1] = coordinate_relocate(MINUTE_LENGTH, angle);
minute_point_trace[0].x = coordinate_x_relocate(5 * sin(minute * 6 * PI / 180));
minute_point_trace[0].y = coordinate_y_relocate(5 * cos(minute * 6 * PI / 180));
minute_point_trace[1].x = coordinate_x_relocate(31 * sin(minute * 6 * PI / 180));
minute_point_trace[1].y = coordinate_y_relocate(31 * cos(minute * 6 * PI / 180));
minute_point_trace[0] = coordinate_relocate(5, angle);
minute_point_trace[1] = coordinate_relocate(31, angle);
lv_line_set_points(minute_body, minute_point, 2);
lv_line_set_points(minute_body_trace, minute_point_trace, 2);
@ -140,15 +154,13 @@ void WatchFaceAnalog::UpdateClock() {
if (sHour != hour || sMinute != minute) {
sHour = hour;
sMinute = minute;
hour_point[0].x = coordinate_x_relocate(30 * sin((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point[0].y = coordinate_y_relocate(30 * cos((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point[1].x = coordinate_x_relocate(HOUR_LENGTH * sin((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point[1].y = coordinate_y_relocate(HOUR_LENGTH * cos((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
auto const angle = (hour * 30 + minute / 2);
hour_point_trace[0].x = coordinate_x_relocate(5 * sin((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point_trace[0].y = coordinate_y_relocate(5 * cos((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point_trace[1].x = coordinate_x_relocate(31 * sin((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point_trace[1].y = coordinate_y_relocate(31 * cos((((hour > 12 ? hour - 12 : hour) * 30) + (minute * 0.5)) * PI / 180));
hour_point[0] = coordinate_relocate(30, angle);
hour_point[1] = coordinate_relocate(HOUR_LENGTH, angle);
hour_point_trace[0] = coordinate_relocate(5, angle);
hour_point_trace[1] = coordinate_relocate(31, angle);
lv_line_set_points(hour_body, hour_point, 2);
lv_line_set_points(hour_body_trace, hour_point_trace, 2);
@ -156,10 +168,10 @@ void WatchFaceAnalog::UpdateClock() {
if (sSecond != second) {
sSecond = second;
second_point[0].x = coordinate_x_relocate(20 * sin((180 + second * 6) * PI / 180));
second_point[0].y = coordinate_y_relocate(20 * cos((180 + second * 6) * PI / 180));
second_point[1].x = coordinate_x_relocate(SECOND_LENGTH * sin(second * 6 * PI / 180));
second_point[1].y = coordinate_y_relocate(SECOND_LENGTH * cos(second * 6 * PI / 180));
auto const angle = second * 6;
second_point[0] = coordinate_relocate(-20, angle);
second_point[1] = coordinate_relocate(SECOND_LENGTH, angle);
lv_line_set_points(second_body, second_point, 2);
}
}