Tasmota/lib/IRremoteESP8266-2.7.3/test/ir_Daikin_test.cpp

3367 lines
114 KiB
C++

// Copyright 2017-2019 David Conran
#include "ir_Daikin.h"
#include "IRac.h"
#include "IRrecv.h"
#include "IRrecv_test.h"
#include "IRsend.h"
#include "IRsend_test.h"
#include "gtest/gtest.h"
// Tests for sendDaikin().
// Test sending typical data only.
TEST(TestSendDaikin, SendDataOnly) {
IRsendTest irsend(0);
irsend.begin();
uint8_t daikin_code[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x20, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x41, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0xE3};
irsend.reset();
irsend.sendDaikin(daikin_code);
EXPECT_EQ(
"f38000d50"
"m428s428m428s428m428s428m428s428m428s428"
"m428s29428"
"m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s1280m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s1280m428s428m428s1280m428s428m428s1280m428s1280"
"m428s29428"
"m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s1280m428s428m428s428"
"m428s29428"
"m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s428m428s428m428s428m428s428m428s1280m428s428"
"m428s428m428s1280m428s1280m428s1280m428s1280m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s428m428s428m428s428m428s1280m428s1280m428s1280"
"m428s29428",
irsend.outputStr());
}
// Test sending with repeats.
TEST(TestSendDaikin, SendWithRepeats) {
IRsendTest irsend(0);
irsend.begin();
irsend.reset();
uint8_t daikin_code[kDaikinStateLengthShort] = {
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x20, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x41, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0xE3};
irsend.reset();
irsend.sendDaikin(daikin_code, kDaikinStateLengthShort, 1);
EXPECT_EQ(
"f38000d50"
"m428s428m428s428m428s428m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s1280m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s1280m428s428m428s1280m428s428m428s1280m428s1280"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s1280m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s428m428s428m428s428m428s428m428s1280m428s428"
"m428s428m428s1280m428s1280m428s1280m428s1280m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s428m428s428m428s428m428s1280m428s1280m428s1280"
"m428s29428"
"m428s428m428s428m428s428m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s1280m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s1280m428s428m428s1280m428s428m428s1280m428s1280"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s1280m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s428m428s428m428s428m428s428m428s1280m428s428"
"m428s428m428s1280m428s1280m428s1280m428s1280m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s428m428s428m428s428m428s1280m428s1280m428s1280"
"m428s29428",
irsend.outputStr());
}
// Test sending atypical sizes.
TEST(TestSendDaikin, SendUnexpectedSizes) {
IRsendTest irsend(4);
irsend.begin();
uint8_t daikin_short_code[kDaikinStateLengthShort - 1] = {
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x20, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x41, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00};
irsend.reset();
irsend.sendDaikin(daikin_short_code, kDaikinStateLengthShort - 1);
ASSERT_EQ("", irsend.outputStr());
uint8_t daikin_long_code[kDaikinStateLengthShort + 1] = {
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x20, 0x11, 0xDA,
0x27, 0x00, 0x00, 0x41, 0x1E, 0x00, 0xB0, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0xE3, 0x11};
irsend.reset();
irsend.sendDaikin(daikin_long_code, kDaikinStateLengthShort + 1);
ASSERT_EQ(
"f38000d50"
"m428s428m428s428m428s428m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s1280m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s1280m428s428m428s1280m428s428m428s1280m428s1280"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s1280m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s428m428s428m428s428m428s428m428s1280m428s428"
"m428s428m428s1280m428s1280m428s1280m428s1280m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s428m428s428m428s428m428s1280m428s1280m428s1280"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s29428",
irsend.outputStr());
}
// Tests for IRDaikinESP class.
TEST(TestDaikinClass, Power) {
IRDaikinESP ac(0);
ac.begin();
ac.on();
EXPECT_TRUE(ac.getPower());
ac.off();
EXPECT_FALSE(ac.getPower());
ac.setPower(true);
EXPECT_TRUE(ac.getPower());
ac.setPower(false);
EXPECT_FALSE(ac.getPower());
}
TEST(TestDaikinClass, Temperature) {
IRDaikinESP ac(0);
ac.begin();
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
}
TEST(TestDaikinClass, OperatingMode) {
IRDaikinESP ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinCool);
EXPECT_EQ(kDaikinCool, ac.getMode());
ac.setMode(kDaikinHeat);
EXPECT_EQ(kDaikinHeat, ac.getMode());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikinFan, ac.getMode());
ac.setMode(kDaikinFan + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinAuto + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikinAuto, ac.getMode());
}
TEST(TestDaikinClass, VaneSwing) {
IRDaikinESP ac(0);
ac.begin();
ac.setSwingHorizontal(true);
ac.setSwingVertical(false);
ac.setSwingHorizontal(true);
EXPECT_TRUE(ac.getSwingHorizontal());
EXPECT_FALSE(ac.getSwingVertical());
ac.setSwingVertical(true);
EXPECT_TRUE(ac.getSwingHorizontal());
EXPECT_TRUE(ac.getSwingVertical());
ac.setSwingHorizontal(false);
EXPECT_FALSE(ac.getSwingHorizontal());
EXPECT_TRUE(ac.getSwingVertical());
ac.setSwingVertical(false);
EXPECT_FALSE(ac.getSwingHorizontal());
EXPECT_FALSE(ac.getSwingVertical());
}
TEST(TestDaikinClass, QuietMode) {
IRDaikinESP ac(0);
ac.begin();
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
ac.setQuiet(false);
EXPECT_FALSE(ac.getQuiet());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
// Setting Econo mode should NOT change out of quiet mode.
ac.setEcono(true);
EXPECT_TRUE(ac.getQuiet());
ac.setEcono(false);
EXPECT_TRUE(ac.getQuiet());
// But setting Powerful mode should exit out of quiet mode.
ac.setPowerful(true);
EXPECT_FALSE(ac.getQuiet());
}
TEST(TestDaikinClass, PowerfulMode) {
IRDaikinESP ac(0);
ac.begin();
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setPowerful(false);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
ac.setEcono(true);
EXPECT_FALSE(ac.getPowerful());
}
TEST(TestDaikinClass, EconoMode) {
IRDaikinESP ac(0);
ac.begin();
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
ac.setEcono(false);
EXPECT_FALSE(ac.getEcono());
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
// Setting Quiet mode should NOT change out of Econo mode.
ac.setQuiet(true);
EXPECT_TRUE(ac.getEcono());
ac.setQuiet(false);
EXPECT_TRUE(ac.getEcono());
// But setting Powerful mode should exit out of Econo mode.
ac.setPowerful(true);
EXPECT_FALSE(ac.getEcono());
}
TEST(TestDaikinClass, FanSpeed) {
IRDaikinESP ac(0);
ac.begin();
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
// Unexpected value should default to Auto.
ac.setFan(255);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax);
EXPECT_EQ(kDaikinFanMax, ac.getFan());
// Beyond Max should default to Auto.
ac.setFan(kDaikinFanMax + 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax - 1);
EXPECT_EQ(kDaikinFanMax - 1, ac.getFan());
ac.setFan(kDaikinFanMin);
EXPECT_EQ(kDaikinFanMin, ac.getFan());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(kDaikinFanMin + 1, ac.getFan());
// Beyond Min should default to Auto.
ac.setFan(kDaikinFanMin - 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(3);
EXPECT_EQ(3, ac.getFan());
ac.setFan(kDaikinFanAuto);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanQuiet);
EXPECT_EQ(kDaikinFanQuiet, ac.getFan());
}
TEST(TestDaikinClass, CurrentTime) {
IRDaikinESP ac(0);
ac.begin();
ac.setCurrentTime(0); // 00:00
EXPECT_EQ(0, ac.getCurrentTime());
ac.setCurrentTime(754); // 12:34
EXPECT_EQ(754, ac.getCurrentTime());
ac.setCurrentTime(1439); // 23:59
EXPECT_EQ(1439, ac.getCurrentTime());
}
TEST(TestDaikinClass, OnOffTimers) {
IRDaikinESP ac(0);
ac.begin();
// Both timers turned off.
ac.disableOnTimer();
ac.disableOffTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
// Turn on just the On Timer.
ac.enableOnTimer(123);
EXPECT_TRUE(ac.getOnTimerEnabled());
EXPECT_EQ(123, ac.getOnTime());
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
// Now turn on the Off Timer.
ac.enableOffTimer(754);
EXPECT_TRUE(ac.getOffTimerEnabled());
EXPECT_EQ(754, ac.getOffTime());
EXPECT_TRUE(ac.getOnTimerEnabled());
EXPECT_EQ(123, ac.getOnTime());
// Turn off the just the On Timer.
ac.disableOnTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_TRUE(ac.getOffTimerEnabled());
EXPECT_EQ(754, ac.getOffTime());
// Now turn off the Off Timer.
ac.disableOffTimer();
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
// Use some canary values around the timers to ensure no accidental
// bit flips happen. i.e. Neighbouring bytes in the state.
// (Found some during testing on systems with different endian-ness)
// Tests here to make sure it never happens again.
ac.setSwingHorizontal(true);
ac.setPowerful(true);
ac.disableOffTimer();
ac.disableOnTimer();
ASSERT_TRUE(ac.getSwingHorizontal());
ASSERT_TRUE(ac.getPowerful());
ac.enableOnTimer(123);
ac.enableOffTimer(456);
ASSERT_TRUE(ac.getSwingHorizontal());
ASSERT_TRUE(ac.getPowerful());
ac.disableOffTimer();
ac.disableOnTimer();
ASSERT_TRUE(ac.getSwingHorizontal());
ASSERT_TRUE(ac.getPowerful());
ac.setSwingHorizontal(false);
ac.setPowerful(false);
ac.disableOffTimer();
ac.disableOnTimer();
ASSERT_FALSE(ac.getSwingHorizontal());
ASSERT_FALSE(ac.getPowerful());
ac.enableOnTimer(123);
ac.enableOffTimer(456);
ASSERT_FALSE(ac.getSwingHorizontal());
ASSERT_FALSE(ac.getPowerful());
ac.disableOffTimer();
ac.disableOnTimer();
ASSERT_FALSE(ac.getSwingHorizontal());
ASSERT_FALSE(ac.getPowerful());
}
TEST(TestDaikinClass, WeeklyTimerEnable) {
IRDaikinESP ac(0);
ac.begin();
// The Weekly Timer Enabled flag is stored in the same byte as Econo mode.
// Econo mode tests are there to make sure it isn't harmed and vice-versa.
ac.setEcono(false);
ac.setWeeklyTimerEnable(false);
ASSERT_FALSE(ac.getWeeklyTimerEnable());
EXPECT_FALSE(ac.getEcono());
ac.setWeeklyTimerEnable(true);
ASSERT_TRUE(ac.getWeeklyTimerEnable());
EXPECT_FALSE(ac.getEcono());
ac.setEcono(false);
ASSERT_TRUE(ac.getWeeklyTimerEnable());
EXPECT_FALSE(ac.getEcono());
ac.setEcono(true);
ASSERT_TRUE(ac.getWeeklyTimerEnable());
EXPECT_TRUE(ac.getEcono());
ac.setWeeklyTimerEnable(false);
ASSERT_FALSE(ac.getWeeklyTimerEnable());
EXPECT_TRUE(ac.getEcono());
// Tests with real data from:
// https://github.com/crankyoldgit/IRremoteESP8266/issues/704#issuecomment-493731421
uint8_t on[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7, 0x11, 0xDA, 0x27, 0x00,
0x42, 0xE3, 0x0B, 0x42, 0x11, 0xDA, 0x27, 0x00, 0x00, 0x68, 0x32, 0x00,
0x30, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x00, 0x00, 0x03};
uint8_t off[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7, 0x11, 0xDA, 0x27, 0x00,
0x42, 0xE3, 0x0B, 0x42, 0x11, 0xDA, 0x27, 0x00, 0x00, 0x68, 0x32, 0x00,
0x30, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x80, 0x00, 0x83};
ac.setRaw(on);
EXPECT_TRUE(ac.getWeeklyTimerEnable());
ac.setRaw(off);
EXPECT_FALSE(ac.getWeeklyTimerEnable());
}
// Test Mold mode.
TEST(TestDaikinClass, MoldSetting) {
IRDaikinESP ac(0);
ac.begin();
ac.setMold(false);
ASSERT_FALSE(ac.getMold());
ac.setMold(true);
ASSERT_TRUE(ac.getMold());
ac.setMold(false);
ASSERT_FALSE(ac.getMold());
}
// Test Comfort mode.
TEST(TestDaikinClass, ComfortSetting) {
IRDaikinESP ac(0);
ac.begin();
ac.setComfort(false);
ASSERT_FALSE(ac.getComfort());
ac.setComfort(true);
ASSERT_TRUE(ac.getComfort());
ac.setComfort(false);
ASSERT_FALSE(ac.getComfort());
}
// Test Sensor mode.
TEST(TestDaikinClass, SensorSetting) {
IRDaikinESP ac(0);
ac.begin();
ac.setSensor(false);
ASSERT_FALSE(ac.getSensor());
ac.setSensor(true);
ASSERT_TRUE(ac.getSensor());
ac.setSensor(false);
ASSERT_FALSE(ac.getSensor());
}
TEST(TestDaikinClass, SetAndGetRaw) {
IRDaikinESP ac(0);
uint8_t shortState[kDaikinStateLengthShort] = {
0x11, 0xDA, 0x27, 0x00, 0x42, 0x00, 0x00, 0x54, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x49, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x4F};
uint8_t longState[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0x00, 0x42, 0x00, 0x00, 0x54, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x49, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x4F};
uint8_t expectedState[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0x00, 0x42, 0x00, 0x00, 0x54, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x48, 0x2A, 0x00, 0xB0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC0, 0x00, 0x02, 0x5C};
EXPECT_STATE_EQ(longState, ac.getRaw(), kDaikinBits);
// toggle the power state.
ac.setPower(!ac.getPower());
ac.setTemp(21);
ac.setMold(true);
EXPECT_STATE_EQ(expectedState, ac.getRaw(), kDaikinBits);
ac.setRaw(longState);
EXPECT_STATE_EQ(longState, ac.getRaw(), kDaikinBits);
ac.setRaw(shortState, kDaikinStateLengthShort);
EXPECT_STATE_EQ(longState, ac.getRaw(), kDaikinBits);
}
TEST(TestDaikinClass, ChecksumValidation) {
uint8_t daikin_code[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x02, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x41, 0x1E, 0x00, 0xB0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0xE1};
EXPECT_TRUE(IRDaikinESP::validChecksum(daikin_code));
// Change the array so the checksum is invalid.
daikin_code[0] ^= 0xFF;
EXPECT_FALSE(IRDaikinESP::validChecksum(daikin_code));
// Restore the previous change, and change another byte.
daikin_code[0] ^= 0xFF;
daikin_code[4] ^= 0xFF;
EXPECT_FALSE(IRDaikinESP::validChecksum(daikin_code));
daikin_code[4] ^= 0xFF;
// Change something in the 2nd block.
daikin_code[10] ^= 0xFF;
EXPECT_FALSE(IRDaikinESP::validChecksum(daikin_code));
daikin_code[10] ^= 0xFF;
EXPECT_TRUE(IRDaikinESP::validChecksum(daikin_code));
// Change something in the 3rd block.
daikin_code[20] ^= 0xFF;
EXPECT_FALSE(IRDaikinESP::validChecksum(daikin_code));
daikin_code[20] ^= 0xFF;
EXPECT_TRUE(IRDaikinESP::validChecksum(daikin_code));
}
// Test human readable output.
TEST(TestDaikinClass, HumanReadable) {
IRDaikinESP ac(0);
EXPECT_EQ(
"Power: On, Mode: 4 (Heat), Temp: 15C, Fan: 11 (Quiet), "
"Powerful: Off, Quiet: Off, Sensor: Off, Mould: Off, "
"Comfort: Off, Swing(H): Off, Swing(V): Off, "
"Clock: 00:00, Day: 0 (UNKNOWN), On Timer: Off, "
"Off Timer: Off, Weekly Timer: On",
ac.toString());
ac.setMode(kDaikinAuto);
ac.setTemp(25);
ac.setFan(kDaikinFanAuto);
ac.setQuiet(true);
ac.setSensor(true);
ac.setMold(true);
ac.setSwingVertical(true);
ac.setSwingHorizontal(true);
ac.setCurrentTime(9 * 60 + 15);
ac.setCurrentDay(4);
ac.enableOnTimer(8 * 60 + 0);
ac.enableOffTimer(17 * 60 + 30);
ac.setComfort(true);
ac.setWeeklyTimerEnable(false);
ac.off();
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 25C, Fan: 10 (Auto), "
"Powerful: Off, Quiet: On, Sensor: On, Mould: On, Comfort: On, "
"Swing(H): On, Swing(V): On, "
"Clock: 09:15, Day: 4 (Wed), On Timer: 08:00, Off Timer: 17:30, "
"Weekly Timer: Off",
ac.toString());
}
// Test general message construction after tweaking some settings.
TEST(TestDaikinClass, MessageConstuction) {
IRDaikinESP ac(0);
IRsendTest irsend(4);
ac.begin();
irsend.begin();
ac.setFan(kDaikinFanMin);
ac.setMode(kDaikinCool);
ac.setTemp(27);
ac.setSwingVertical(false);
ac.setSwingHorizontal(true);
ac.setQuiet(false);
ac.setPower(true);
// Check everything for kicks.
EXPECT_EQ(kDaikinFanMin, ac.getFan());
EXPECT_EQ(kDaikinCool, ac.getMode());
EXPECT_EQ(27, ac.getTemp());
EXPECT_FALSE(ac.getSwingVertical());
EXPECT_TRUE(ac.getSwingHorizontal());
EXPECT_FALSE(ac.getQuiet());
EXPECT_TRUE(ac.getPower());
irsend.reset();
irsend.sendDaikin(ac.getRaw());
EXPECT_EQ(
"f38000d50"
"m428s428m428s428m428s428m428s428m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s1280m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s1280m428s1280m428s428m428s1280m428s428m428s1280m428s1280"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s428m428s428m428s428m428s1280m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s1280m428s428m428s1280m428s428m428s1280m428s428"
"m428s29428m3650s1623"
"m428s1280m428s428m428s428m428s428m428s1280m428s428m428s428m428s428"
"m428s428m428s1280m428s428m428s1280m428s1280m428s428m428s1280m428s1280"
"m428s1280m428s1280m428s1280m428s428m428s428m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s1280m428s428m428s428m428s1280m428s1280m428s1280m428s428m428s428"
"m428s428m428s1280m428s1280m428s428m428s1280m428s1280m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428m428s428"
"m428s1280m428s1280m428s1280m428s1280m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s1280m428s1280m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s1280m428s1280"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s428m428s428m428s428m428s428m428s428m428s428m428s428"
"m428s428m428s1280m428s1280m428s428m428s428m428s1280m428s1280m428s1280"
"m428s29428",
irsend.outputStr());
}
// Tests for decodeDaikin().
// Test decoding a message captured from a real IR remote.
TEST(TestDecodeDaikin, RealExample) {
IRDaikinESP ac(0);
IRsendTest irsend(0);
IRrecv irrecv(0);
irsend.begin();
uint8_t expectedState[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0x00, 0x42, 0x3A, 0x05, 0x93, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x3F, 0x3A, 0x00, 0xA0, 0x00,
0x0A, 0x25, 0x17, 0x01, 0x00, 0xC0, 0x00, 0x00, 0x32};
uint16_t rawData[583] = {
416, 446, 416, 446, 416, 446, 418, 446, 416, 446, 416, 25434,
3436, 1768, 390, 1336, 390, 446, 416, 446, 416, 446, 416, 1336,
390, 446, 416, 446, 416, 446, 416, 446, 416, 1336, 390, 448,
416, 1336, 390, 1336, 390, 448, 416, 1336, 390, 1336, 390, 1338,
388, 1338, 390, 1336, 390, 446, 416, 446, 416, 1336, 390, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 446, 416, 448,
416, 446, 416, 446, 416, 446, 416, 1336, 390, 446, 416, 1336,
390, 448, 416, 446, 416, 446, 416, 1336, 390, 1336, 390, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 446, 416, 446,
416, 446, 416, 446, 416, 448, 416, 446, 416, 446, 416, 446,
416, 448, 414, 448, 416, 448, 416, 1336, 390, 1336, 390, 1336,
390, 446, 414, 1336, 390, 448, 414, 1336, 390, 1336, 390, 34878,
3436, 1768, 390, 1336, 390, 446, 416, 448, 416, 446, 416, 1336,
390, 446, 416, 448, 416, 446, 416, 446, 416, 1336, 390, 446,
416, 1336, 390, 1336, 390, 446, 416, 1336, 390, 1336, 390, 1336,
390, 1336, 390, 1336, 392, 446, 414, 448, 416, 1336, 390, 446,
416, 446, 416, 446, 416, 446, 414, 448, 416, 446, 416, 448,
414, 448, 416, 446, 416, 446, 416, 446, 414, 1336, 390, 448,
416, 446, 416, 446, 416, 448, 416, 1336, 390, 446, 416, 446,
416, 1336, 390, 446, 416, 1336, 390, 1336, 390, 1336, 390, 446,
416, 446, 414, 1338, 390, 446, 416, 1336, 390, 446, 416, 446,
416, 446, 416, 446, 416, 446, 416, 1336, 390, 1336, 390, 446,
416, 446, 416, 1336, 390, 446, 416, 446, 416, 1336, 390, 34876,
3436, 1768, 388, 1336, 390, 446, 416, 446, 416, 448, 416, 1336,
390, 446, 416, 446, 416, 446, 416, 448, 416, 1336, 390, 448,
414, 1336, 390, 1336, 390, 446, 416, 1336, 388, 1338, 388, 1336,
390, 1336, 390, 1336, 390, 446, 416, 446, 416, 1336, 390, 446,
420, 442, 416, 446, 416, 446, 416, 446, 416, 446, 416, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 446, 416, 448,
416, 446, 416, 448, 416, 446, 416, 448, 416, 446, 416, 1336,
390, 1336, 390, 1336, 388, 1338, 390, 1336, 390, 1336, 392, 446,
416, 446, 416, 448, 416, 1334, 390, 446, 416, 1338, 388, 1336,
390, 1336, 390, 446, 416, 446, 416, 448, 414, 446, 416, 446,
416, 446, 416, 448, 416, 446, 416, 446, 416, 446, 416, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 1336, 390, 446,
416, 1336, 390, 446, 414, 448, 416, 446, 416, 446, 416, 446,
416, 448, 416, 446, 416, 446, 416, 446, 416, 1336, 390, 446,
416, 1336, 390, 446, 416, 446, 416, 446, 416, 448, 416, 1338,
390, 444, 418, 1336, 390, 448, 416, 446, 416, 1336, 390, 446,
416, 446, 416, 1336, 390, 1336, 388, 1336, 390, 446, 416, 1336,
390, 448, 414, 448, 414, 448, 416, 1334, 390, 446, 416, 446,
416, 446, 416, 448, 416, 446, 416, 446, 416, 448, 416, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 446, 416, 446,
416, 446, 416, 446, 416, 446, 416, 446, 416, 446, 416, 446,
416, 448, 416, 1336, 390, 1336, 390, 446, 416, 446, 416, 446,
416, 446, 414, 446, 416, 448, 416, 446, 416, 448, 414, 446,
418, 446, 416, 446, 416, 448, 416, 446, 416, 448, 416, 446,
416, 448, 416, 446, 416, 1336, 390, 446, 416, 446, 416, 1338,
390, 1336, 390, 446, 416, 446, 416}; // Captured by @sillyfrog
irsend.reset();
irsend.sendRaw(rawData, 583, 38000);
irsend.makeDecodeResult();
EXPECT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN, irsend.capture.decode_type);
ASSERT_EQ(kDaikinBits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
ac.setRaw(irsend.capture.state);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 29C, Fan: 10 (Auto), Powerful: On, "
"Quiet: Off, Sensor: Off, Mould: Off, Comfort: Off, "
"Swing(H): Off, Swing(V): Off, "
"Clock: 22:18, Day: 0 (UNKNOWN), "
"On Timer: 21:30, Off Timer: 06:10, Weekly Timer: On", ac.toString());
}
// Decoding a message we entirely constructed based solely on a given state.
TEST(TestDecodeDaikin, ShortSyntheticExample) {
IRDaikinESP ac(0);
IRsendTest irsend(0);
IRrecv irrecv(0);
irsend.begin();
uint8_t shortState[kDaikinStateLengthShort] = {
0x11, 0xDA, 0x27, 0x00, 0x42, 0x3A, 0x05, 0x93, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x3F, 0x3A, 0x00, 0xA0, 0x00,
0x0A, 0x25, 0x17, 0x01, 0x00, 0xC0, 0x00, 0x00, 0x32};
uint8_t longState[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0x00, 0x42, 0x3A, 0x05, 0x93, 0x11,
0xDA, 0x27, 0x00, 0x00, 0x3F, 0x3A, 0x00, 0xA0, 0x00,
0x0A, 0x25, 0x17, 0x01, 0x00, 0xC0, 0x00, 0x00, 0x32};
irsend.reset();
irsend.sendDaikin(shortState, kDaikinStateLengthShort);
irsend.makeDecodeResult();
EXPECT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN, irsend.capture.decode_type);
ASSERT_EQ(kDaikinBits, irsend.capture.bits);
EXPECT_STATE_EQ(longState, irsend.capture.state, irsend.capture.bits);
ac.setRaw(irsend.capture.state);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 29C, Fan: 10 (Auto), Powerful: On, "
"Quiet: Off, Sensor: Off, Mould: Off, Comfort: Off, "
"Swing(H): Off, Swing(V): Off, "
"Clock: 22:18, Day: 0 (UNKNOWN), "
"On Timer: 21:30, Off Timer: 06:10, Weekly Timer: On", ac.toString());
}
// Decoding a message we entirely constructed based solely on a given state.
TEST(TestDecodeDaikin, LongSyntheticExample) {
IRDaikinESP ac(0);
IRsendTest irsend(0);
IRrecv irrecv(0);
irsend.begin();
uint8_t expectedState[kDaikinStateLength] = {
0x11, 0xDA, 0x27, 0x00, 0xC5, 0x00, 0x00, 0xD7,
0x11, 0xDA, 0x27, 0x00, 0x42, 0x3A, 0x05, 0x93,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x3F, 0x3A, 0x00, 0xA0, 0x00,
0x0A, 0x25, 0x17, 0x01, 0x00, 0xC0, 0x00, 0x00, 0x32};
irsend.reset();
irsend.sendDaikin(expectedState);
irsend.makeDecodeResult();
EXPECT_TRUE(irrecv.decodeDaikin(&irsend.capture));
ASSERT_EQ(DAIKIN, irsend.capture.decode_type);
ASSERT_EQ(kDaikinBits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
ac.setRaw(irsend.capture.state);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 29C, Fan: 10 (Auto), Powerful: On, "
"Quiet: Off, Sensor: Off, Mould: Off, Comfort: Off, "
"Swing(H): Off, Swing(V): Off, "
"Clock: 22:18, Day: 0 (UNKNOWN), "
"On Timer: 21:30, Off Timer: 06:10, Weekly Timer: On", ac.toString());
}
// Test decoding a message captured from a real IR remote.
TEST(TestDecodeDaikin2, RealExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
irsend.begin();
uint8_t expectedState[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x7A, 0xC3, 0x70, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xD5, 0xF5,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x08, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x80, 0x60, 0xE7};
// "Off" Data from https://github.com/crankyoldgit/IRremoteESP8266/issues/582
uint16_t rawData[633] = { // Data supplied by @sheppy99
10024, 25180, 3494, 1732, 436, 1300, 436, 436, 432, 438, 430, 438,
426, 1306, 430, 442, 430, 438, 428, 440, 430, 440, 430, 1304,
432, 442, 428, 1308, 424, 1312, 428, 442, 428, 1306, 424, 1314,
426, 1308, 434, 1306, 426, 1308, 428, 444, 426, 442, 428, 1310,
428, 442, 424, 444, 426, 442, 426, 444, 424, 444, 426, 444,
424, 446, 422, 446, 422, 446, 422, 446, 418, 1318, 418, 450,
420, 448, 420, 448, 422, 448, 420, 450, 420, 448, 420, 450,
420, 452, 418, 1318, 420, 450, 420, 1318, 420, 1314, 418, 1318,
424, 1314, 424, 448, 422, 1316, 424, 1312, 426, 446, 422, 448,
420, 448, 422, 448, 422, 1314, 418, 1320, 416, 452, 420, 448,
420, 448, 422, 448, 422, 1314, 416, 1320, 422, 1316, 422, 450,
418, 450, 420, 448, 420, 448, 416, 1320, 418, 452, 418, 1316,
422, 448, 420, 450, 420, 450, 420, 448, 422, 1314, 418, 1320,
418, 450, 420, 448, 420, 448, 420, 450, 420, 450, 418, 450,
418, 450, 420, 450, 418, 452, 416, 452, 420, 450, 418, 1318,
420, 452, 418, 452, 418, 1322, 416, 452, 416, 452, 418, 452,
418, 452, 416, 454, 418, 452, 416, 456, 414, 452, 418, 454,
416, 1320, 410, 1324, 418, 452, 418, 1320, 416, 452, 418, 1320,
418, 1318, 420, 448, 420, 1316, 420, 450, 420, 450, 418, 450,
420, 450, 418, 452, 418, 1320, 418, 450, 418, 450, 416, 1322,
412, 458, 420, 450, 416, 452, 418, 452, 416, 452, 418, 452,
416, 454, 416, 452, 418, 452, 416, 454, 414, 454, 416, 454,
416, 454, 414, 456, 414, 454, 414, 456, 412, 454, 416, 456,
414, 456, 412, 1326, 412, 1320, 412, 1322, 414, 1322, 418, 1320,
420, 452, 418, 1318, 420, 1316, 422, 450, 420, 1314, 424, 448,
422, 1314, 422, 448, 422, 1314, 418, 1318, 424, 1316, 422, 448,
422, 1312, 424, 446, 422, 1314, 420, 1318, 422, 1316, 426, 1310,
426, 35166, 3500, 1724, 446, 1296, 444, 432, 436, 432, 438, 432,
436, 1296, 440, 434, 434, 436, 432, 436, 434, 436, 434, 1298,
438, 438, 432, 1304, 428, 1304, 432, 442, 430, 1302, 430, 1308,
430, 1306, 434, 1302, 432, 1306, 430, 440, 430, 438, 430, 1308,
434, 438, 430, 440, 428, 440, 430, 440, 428, 442, 426, 444,
428, 442, 426, 444, 426, 442, 426, 444, 424, 446, 422, 446,
424, 446, 424, 446, 422, 446, 424, 448, 420, 448, 422, 446,
422, 448, 422, 450, 420, 450, 414, 1320, 420, 450, 418, 450,
418, 448, 420, 450, 418, 452, 418, 1320, 418, 1316, 422, 450,
418, 452, 418, 1320, 420, 448, 418, 450, 420, 450, 418, 452,
416, 452, 418, 450, 418, 452, 416, 452, 418, 452, 416, 454,
416, 452, 416, 454, 416, 454, 414, 456, 416, 454, 414, 1322,
416, 454, 416, 1320, 418, 452, 416, 454, 414, 454, 416, 454,
414, 454, 414, 454, 414, 456, 414, 456, 412, 456, 414, 456,
414, 456, 412, 456, 414, 458, 406, 464, 410, 458, 412, 458,
410, 460, 410, 1326, 412, 1324, 414, 456, 412, 458, 412, 456,
414, 456, 412, 458, 410, 458, 414, 458, 410, 458, 408, 460,
410, 470, 400, 1324, 408, 1328, 410, 458, 410, 460, 414, 456,
410, 456, 414, 458, 412, 460, 410, 458, 412, 458, 412, 460,
408, 460, 410, 460, 408, 472, 396, 462, 408, 470, 402, 470,
396, 472, 400, 470, 398, 1326, 412, 460, 408, 472, 396, 472,
400, 470, 400, 472, 396, 1328, 410, 1324, 414, 458, 410, 458,
410, 458, 412, 458, 412, 460, 408, 460, 410, 460, 410, 1324,
414, 458, 410, 460, 408, 460, 410, 458, 410, 460, 410, 1326,
412, 1322, 416, 456, 412, 1322, 412, 1326, 416, 1322, 418, 452,
416, 454, 412, 1324, 418, 1320, 420, 1316, 420};
irsend.reset();
irsend.sendRaw(rawData, 633, 38000);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN2, irsend.capture.decode_type);
ASSERT_EQ(kDaikin2Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
}
// Decoding a message we entirely constructed based solely on a given state.
TEST(TestDecodeDaikin2, SyntheticExample) {
IRDaikin2 ac(0);
IRsendTest irsend(0);
IRrecv irrecv(0);
irsend.begin();
uint8_t expectedState[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x7A, 0xC3, 0x70, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xD5, 0xF5,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x08, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x80, 0x60, 0xE7};
irsend.reset();
irsend.sendDaikin2(expectedState);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN2, irsend.capture.decode_type);
ASSERT_EQ(kDaikin2Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
ac.setRaw(irsend.capture.state);
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 19C, Fan: 10 (Auto), "
"Swing(V): 5 (Low), Swing(H): 190 (Auto), "
"Clock: 14:50, On Timer: Off, Off Timer: Off, Sleep Timer: Off, "
"Beep: 1 (Quiet), Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, "
"Eye: Off, Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: Off, "
"Econo: Off",
ac.toString());
}
TEST(TestDaikin2Class, CurrentTime) {
IRDaikin2 ac(0);
ac.begin();
ac.setCurrentTime(0); // 00:00
EXPECT_EQ(0, ac.getCurrentTime());
ac.setCurrentTime(754); // 12:34
EXPECT_EQ(754, ac.getCurrentTime());
ac.setCurrentTime(1439); // 23:59
EXPECT_EQ(1439, ac.getCurrentTime());
}
TEST(TestDaikin2Class, OnOffTimers) {
IRDaikin2 ac(0);
ac.begin();
// Both timers turned off.
ac.disableOnTimer();
ac.disableOffTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
// Turn on just the On Timer.
ac.enableOnTimer(123);
EXPECT_TRUE(ac.getOnTimerEnabled());
EXPECT_EQ(123, ac.getOnTime());
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
// Now turn on the Off Timer.
ac.enableOffTimer(754);
EXPECT_TRUE(ac.getOffTimerEnabled());
EXPECT_EQ(754, ac.getOffTime());
EXPECT_TRUE(ac.getOnTimerEnabled());
EXPECT_EQ(123, ac.getOnTime());
// Turn off the just the On Timer.
ac.disableOnTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_TRUE(ac.getOffTimerEnabled());
EXPECT_EQ(754, ac.getOffTime());
// Now turn off the Off Timer.
ac.disableOffTimer();
EXPECT_FALSE(ac.getOffTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOffTime());
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
}
TEST(TestDaikin2Class, LightAndBeep) {
IRDaikin2 ac(0);
ac.begin();
ac.setLight(kDaikinLightOff);
EXPECT_EQ(kDaikinLightOff, ac.getLight());
ac.setBeep(kDaikinBeepOff);
EXPECT_EQ(kDaikinBeepOff, ac.getBeep());
ac.setLight(kDaikinLightBright);
EXPECT_EQ(kDaikinLightBright, ac.getLight());
EXPECT_EQ(kDaikinBeepOff, ac.getBeep());
ac.setBeep(kDaikinBeepLoud);
EXPECT_EQ(kDaikinBeepLoud, ac.getBeep());
EXPECT_EQ(kDaikinLightBright, ac.getLight());
}
TEST(TestDaikin2Class, FanSpeed) {
IRDaikin2 ac(0);
ac.begin();
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
// Unexpected value should default to Auto.
ac.setFan(255);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax);
EXPECT_EQ(kDaikinFanMax, ac.getFan());
// Beyond Max should default to Auto.
ac.setFan(kDaikinFanMax + 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax - 1);
EXPECT_EQ(kDaikinFanMax - 1, ac.getFan());
ac.setFan(kDaikinFanMin);
EXPECT_EQ(kDaikinFanMin, ac.getFan());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(kDaikinFanMin + 1, ac.getFan());
// Beyond Min should default to Auto.
ac.setFan(kDaikinFanMin - 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(3);
EXPECT_EQ(3, ac.getFan());
ac.setFan(kDaikinFanAuto);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanQuiet);
EXPECT_EQ(kDaikinFanQuiet, ac.getFan());
}
// Test Mold mode.
TEST(TestDaikin2Class, MoldSetting) {
IRDaikin2 ac(0);
ac.begin();
ac.setMold(false);
ASSERT_FALSE(ac.getMold());
ac.setMold(true);
ASSERT_TRUE(ac.getMold());
ac.setMold(false);
ASSERT_FALSE(ac.getMold());
}
// Test Auto Clean setting.
TEST(TestDaikin2Class, CleanSetting) {
IRDaikin2 ac(0);
ac.begin();
ac.setClean(false);
ASSERT_FALSE(ac.getClean());
ac.setClean(true);
ASSERT_TRUE(ac.getClean());
ac.setClean(false);
ASSERT_FALSE(ac.getClean());
}
TEST(TestDaikin2Class, Temperature) {
IRDaikin2 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
// Now try it with Cool mode, which should set the temp to kDaikin2MinCoolTemp
ASSERT_TRUE(kDaikinMinTemp + 1 < kDaikin2MinCoolTemp);
ac.setMode(kDaikinCool);
EXPECT_EQ(kDaikin2MinCoolTemp, ac.getTemp());
ac.setTemp(kDaikin2MinCoolTemp - 1);
EXPECT_EQ(kDaikin2MinCoolTemp, ac.getTemp());
ac.setTemp(kDaikin2MinCoolTemp + 1);
EXPECT_EQ(kDaikin2MinCoolTemp + 1, ac.getTemp());
// Should be released from that requirement in other modes.
ac.setMode(kDaikinAuto);
ac.setTemp(kDaikin2MinCoolTemp - 1);
EXPECT_EQ(kDaikin2MinCoolTemp - 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
}
// Test Fresh Air settings.
TEST(TestDaikin2Class, FreshAirSettings) {
IRDaikin2 ac(0);
ac.begin();
ac.setFreshAir(false);
ac.setFreshAirHigh(false);
ASSERT_FALSE(ac.getFreshAir());
ASSERT_FALSE(ac.getFreshAirHigh());
ac.setFreshAir(true);
ASSERT_TRUE(ac.getFreshAir());
ASSERT_FALSE(ac.getFreshAirHigh());
ac.setFreshAirHigh(true);
ASSERT_TRUE(ac.getFreshAir());
ASSERT_TRUE(ac.getFreshAirHigh());
ac.setFreshAir(false);
ASSERT_FALSE(ac.getFreshAir());
ASSERT_TRUE(ac.getFreshAirHigh());
ac.setFreshAirHigh(false);
ASSERT_FALSE(ac.getFreshAir());
ASSERT_FALSE(ac.getFreshAirHigh());
}
// Test Eye mode.
TEST(TestDaikin2Class, EyeSetting) {
IRDaikin2 ac(0);
ac.begin();
ac.setEye(false);
ASSERT_FALSE(ac.getEye());
ac.setEye(true);
ASSERT_TRUE(ac.getEye());
ac.setEye(false);
ASSERT_FALSE(ac.getEye());
}
// Test Econo setting.
TEST(TestDaikin2Class, EconoSetting) {
IRDaikin2 ac(0);
ac.begin();
ac.setEcono(false);
ASSERT_FALSE(ac.getEcono());
ac.setEcono(true);
ASSERT_TRUE(ac.getEcono());
ac.setEcono(false);
ASSERT_FALSE(ac.getEcono());
}
TEST(TestDaikin2Class, SleepTimer) {
IRDaikin2 ac(0);
ac.begin();
// NOTE: On & Sleep timer share the same time location.
// Both timers turned off.
ac.disableOnTimer();
ac.disableSleepTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_FALSE(ac.getSleepTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getSleepTime());
// Turn on just the On Timer.
ac.enableOnTimer(123);
EXPECT_TRUE(ac.getOnTimerEnabled());
EXPECT_EQ(123, ac.getOnTime());
EXPECT_FALSE(ac.getSleepTimerEnabled());
EXPECT_EQ(123, ac.getSleepTime());
// Now turn on the Sleep Timer. This shoud disable the On Timer.
ac.enableSleepTimer(754);
EXPECT_TRUE(ac.getSleepTimerEnabled());
EXPECT_EQ(754, ac.getSleepTime());
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(754, ac.getOnTime());
// Turn off the just the On Timer.
ac.disableOnTimer();
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
EXPECT_FALSE(ac.getSleepTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getSleepTime());
// Now turn on the On Timer and turn off the Sleep Timer.
// Both should be off afterwards.
ac.enableOnTimer(123);
ac.disableSleepTimer();
EXPECT_FALSE(ac.getSleepTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getSleepTime());
EXPECT_FALSE(ac.getOnTimerEnabled());
EXPECT_EQ(kDaikinUnusedTime, ac.getOnTime());
}
// Test Vertical Swing.
TEST(TestDaikin2Class, Swing) {
IRDaikin2 ac(0);
ac.begin();
// Vertical
ac.setSwingVertical(1);
ASSERT_EQ(1, ac.getSwingVertical());
ac.setSwingVertical(3);
ASSERT_EQ(3, ac.getSwingVertical());
ac.setSwingVertical(6);
ASSERT_EQ(6, ac.getSwingVertical());
ac.setSwingVertical(kDaikin2SwingVBreeze);
ASSERT_EQ(kDaikin2SwingVBreeze, ac.getSwingVertical());
ac.setSwingVertical(kDaikin2SwingVCirculate);
ASSERT_EQ(kDaikin2SwingVCirculate, ac.getSwingVertical());
ac.setSwingVertical(kDaikin2SwingVSwing);
ASSERT_EQ(kDaikin2SwingVSwing, ac.getSwingVertical());
ac.setSwingVertical(kDaikin2SwingVAuto);
ASSERT_EQ(kDaikin2SwingVAuto, ac.getSwingVertical());
ac.setSwingVertical(0);
ASSERT_EQ(kDaikin2SwingVAuto, ac.getSwingVertical());
ac.setSwingVertical(20);
ASSERT_EQ(kDaikin2SwingVAuto, ac.getSwingVertical());
ac.setSwingVertical(255);
ASSERT_EQ(kDaikin2SwingVAuto, ac.getSwingVertical());
// Horizontal
ac.setSwingHorizontal(kDaikin2SwingHAuto);
ASSERT_EQ(kDaikin2SwingHAuto, ac.getSwingHorizontal());
ac.setSwingHorizontal(kDaikin2SwingHSwing);
ASSERT_EQ(kDaikin2SwingHSwing, ac.getSwingHorizontal());
ac.setSwingHorizontal(0);
ASSERT_EQ(0, ac.getSwingHorizontal());
ac.setSwingHorizontal(255);
ASSERT_EQ(255, ac.getSwingHorizontal());
}
TEST(TestDaikin2Class, QuietMode) {
IRDaikin2 ac(0);
ac.begin();
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
ac.setQuiet(false);
EXPECT_FALSE(ac.getQuiet());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
// But setting Powerful mode should exit out of quiet mode.
ac.setPowerful(true);
EXPECT_FALSE(ac.getQuiet());
}
TEST(TestDaikin2Class, PowerfulMode) {
IRDaikin2 ac(0);
ac.begin();
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setPowerful(false);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_FALSE(ac.getPowerful());
}
// Test Purify mode.
TEST(TestDaikin2Class, PurifySetting) {
IRDaikin2 ac(0);
ac.begin();
ac.setPurify(false);
ASSERT_FALSE(ac.getPurify());
ac.setPurify(true);
ASSERT_TRUE(ac.getPurify());
ac.setPurify(false);
ASSERT_FALSE(ac.getPurify());
}
TEST(TestDaikin2Class, HumanReadable) {
IRDaikin2 ac(0);
ac.begin();
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(21);
ac.setFan(kDaikinFanMax);
ac.setSwingVertical(kDaikin2SwingVAuto);
ac.setSwingHorizontal(kDaikin2SwingHSwing);
ac.setCurrentTime(12 * 60 + 34); // 12:34
ac.disableOnTimer();
ac.enableOffTimer(20 * 60); // 20:00
ac.enableSleepTimer(4 * 60); // 4:00
ac.setBeep(kDaikinBeepLoud);
ac.setLight(kDaikinLightDim);
ac.setMold(true);
ac.setClean(false);
ac.setFreshAir(true);
ac.setEye(true);
ac.setEyeAuto(true);
ac.setQuiet(false);
ac.setPowerful(true);
ac.setPurify(true);
ac.setEcono(false);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 21C, Fan: 5 (High), "
"Swing(V): 14 (Auto), Swing(H): 191 (Swing), Clock: 12:34, "
"On Timer: Off, Off Timer: 20:00, Sleep Timer: 04:00, Beep: 2 (Loud), "
"Light: 2 (Low), Mould: On, Clean: Off, Fresh: On, Eye: On, "
"Eye Auto: On, Quiet: Off, Powerful: On, Purify: On, Econo: Off",
ac.toString());
ac.setQuiet(true);
ac.setMode(kDaikinHeat);
ac.setBeep(kDaikinBeepQuiet);
ac.setLight(kDaikinLightBright);
ac.setTemp(32);
ac.setFan(kDaikinFanMin);
ac.setCurrentTime(23 * 60 + 45); // 23:45
ac.enableOnTimer(9 * 60 + 11); // 9:11
EXPECT_EQ(
"Power: On, Mode: 4 (Heat), Temp: 32C, Fan: 1 (Low), "
"Swing(V): 14 (Auto), Swing(H): 191 (Swing), Clock: 23:45, "
"On Timer: 09:11, Off Timer: 20:00, Sleep Timer: Off, Beep: 1 (Quiet), "
"Light: 1 (High), Mould: On, Clean: Off, Fresh: On, Eye: On, "
"Eye Auto: On, Quiet: On, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
}
// See if we can construct a known state.
TEST(TestDaikin2Class, KnownConstruction) {
IRDaikin2 ac(0);
uint8_t expectedState[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x7A, 0xC3, 0x70, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xD5, 0xF5,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x08, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x80, 0x60, 0xE7};
ac.begin();
ac.setPower(false);
ac.setMode(kDaikinAuto);
ac.setTemp(19);
ac.setFan(kDaikinFanAuto);
ac.setSwingVertical(5);
ac.setSwingHorizontal(kDaikin2SwingHAuto);
ac.setCurrentTime(14 * 60 + 50); // 14:50
ac.disableOnTimer();
ac.disableOffTimer();
ac.disableSleepTimer();
ac.setBeep(kDaikinBeepQuiet);
ac.setLight(kDaikinLightOff);
ac.setMold(true);
ac.setClean(true);
ac.setFreshAir(false);
ac.setEye(false);
ac.setEyeAuto(false);
ac.setQuiet(false);
ac.setPowerful(false);
ac.setPurify(false);
ac.setEcono(false);
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 19C, Fan: 10 (Auto), "
"Swing(V): 5 (Low), Swing(H): 190 (Auto), "
"Clock: 14:50, On Timer: Off, Off Timer: Off, Sleep Timer: Off, "
"Beep: 1 (Quiet), Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, "
"Eye: Off, Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: Off, "
"Econo: Off",
ac.toString());
EXPECT_STATE_EQ(expectedState, ac.getRaw(), kDaikin2Bits);
}
TEST(TestUtils, Housekeeping) {
ASSERT_EQ("DAIKIN", typeToString(decode_type_t::DAIKIN));
ASSERT_EQ(decode_type_t::DAIKIN, strToDecodeType("DAIKIN"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN));
ASSERT_EQ("DAIKIN128", typeToString(decode_type_t::DAIKIN128));
ASSERT_EQ(decode_type_t::DAIKIN128, strToDecodeType("DAIKIN128"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN128));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN128));
ASSERT_EQ("DAIKIN152", typeToString(decode_type_t::DAIKIN152));
ASSERT_EQ(decode_type_t::DAIKIN152, strToDecodeType("DAIKIN152"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN152));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN152));
ASSERT_EQ("DAIKIN160", typeToString(decode_type_t::DAIKIN160));
ASSERT_EQ(decode_type_t::DAIKIN160, strToDecodeType("DAIKIN160"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN160));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN160));
ASSERT_EQ("DAIKIN176", typeToString(decode_type_t::DAIKIN176));
ASSERT_EQ(decode_type_t::DAIKIN176, strToDecodeType("DAIKIN176"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN176));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN176));
ASSERT_EQ("DAIKIN2", typeToString(decode_type_t::DAIKIN2));
ASSERT_EQ(decode_type_t::DAIKIN2, strToDecodeType("DAIKIN2"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN2));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN2));
ASSERT_EQ("DAIKIN216", typeToString(decode_type_t::DAIKIN216));
ASSERT_EQ(decode_type_t::DAIKIN216, strToDecodeType("DAIKIN216"));
ASSERT_TRUE(hasACState(decode_type_t::DAIKIN216));
ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::DAIKIN216));
}
// https://github.com/crankyoldgit/IRremoteESP8266/issues/582#issuecomment-453863879
TEST(TestDecodeDaikin2, Issue582DeepDecodeExample) {
IRDaikin2 ac(0);
const uint8_t state[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x30, 0x42, 0xF0, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xCE, 0xA3,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x09, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x92, 0x60, 0xFA};
ac.setRaw(state);
ASSERT_TRUE(ac.getMold());
ASSERT_TRUE(ac.getEye());
ASSERT_TRUE(ac.getPurify());
EXPECT_EQ(
"Power: On, Mode: 0 (Auto), Temp: 19C, Fan: 10 (Auto), "
"Swing(V): 14 (Auto), Swing(H): 190 (Auto), Clock: 09:20, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 3 (Off), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: On, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
}
// https://docs.google.com/spreadsheets/d/1f8EGfIbBUo2B-CzUFdrgKQprWakoYNKM80IKZN4KXQE/edit?ts=5c317775#gid=1023395743
TEST(TestDecodeDaikin2, Issue582PowerfulEconoFix) {
IRDaikin2 ac(0);
const uint8_t PowerfulOn[39] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x3A, 0x43, 0xF0, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xCE, 0xAE,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x39, 0x28, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x01, 0x00, 0xC1, 0x90, 0x60, 0x2B};
const uint8_t PowerfulOff[39] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x3A, 0x43, 0xF0, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xCE, 0xAE,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x39, 0x28, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x90, 0x60, 0x2A};
ac.setRaw(PowerfulOn);
ASSERT_TRUE(ac.getPowerful());
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 10 (Auto), "
"Swing(V): 14 (Auto), Swing(H): 190 (Auto), Clock: 13:46, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 3 (Off), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: On, Purify: On, Econo: Off",
ac.toString());
ac.setRaw(PowerfulOff);
ASSERT_FALSE(ac.getPowerful());
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 10 (Auto), "
"Swing(V): 14 (Auto), Swing(H): 190 (Auto), Clock: 13:46, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 3 (Off), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
const uint8_t EconoOn[39] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x3B, 0x43, 0xF0, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xCE, 0xAF,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x39, 0x28, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x94, 0x60, 0x2E};
const uint8_t EconoOff[39] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x3B, 0x43, 0xF0, 0x28, 0x0C,
0x80, 0x04, 0xB0, 0x16, 0x24, 0x00, 0x00, 0xBE, 0xCE, 0xAF,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x39, 0x28, 0x00, 0xA0, 0x00,
0x00, 0x06, 0x60, 0x00, 0x00, 0xC1, 0x90, 0x60, 0x2A};
ac.setRaw(EconoOn);
ASSERT_TRUE(ac.getEcono());
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 10 (Auto), "
"Swing(V): 14 (Auto), Swing(H): 190 (Auto), Clock: 13:47, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 3 (Off), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: On",
ac.toString());
ac.setRaw(EconoOff);
ASSERT_FALSE(ac.getEcono());
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 10 (Auto), "
"Swing(V): 14 (Auto), Swing(H): 190 (Auto), Clock: 13:47, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 3 (Off), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
}
// Tests for IRDaikin216 class.
TEST(TestDaikin216Class, Power) {
IRDaikin216 ac(0);
ac.begin();
ac.on();
EXPECT_TRUE(ac.getPower());
ac.off();
EXPECT_FALSE(ac.getPower());
ac.setPower(true);
EXPECT_TRUE(ac.getPower());
ac.setPower(false);
EXPECT_FALSE(ac.getPower());
}
TEST(TestDaikin216Class, Temperature) {
IRDaikin216 ac(0);
ac.begin();
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
}
TEST(TestDaikin216Class, OperatingMode) {
IRDaikin216 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinCool);
EXPECT_EQ(kDaikinCool, ac.getMode());
ac.setMode(kDaikinHeat);
EXPECT_EQ(kDaikinHeat, ac.getMode());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikinFan, ac.getMode());
ac.setMode(kDaikinFan + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinAuto + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikinAuto, ac.getMode());
}
TEST(TestDaikin216Class, VaneSwing) {
IRDaikin216 ac(0);
ac.begin();
ac.setSwingHorizontal(true);
ac.setSwingVertical(false);
ac.setSwingHorizontal(true);
EXPECT_TRUE(ac.getSwingHorizontal());
EXPECT_FALSE(ac.getSwingVertical());
ac.setSwingVertical(true);
EXPECT_TRUE(ac.getSwingHorizontal());
EXPECT_TRUE(ac.getSwingVertical());
ac.setSwingHorizontal(false);
EXPECT_FALSE(ac.getSwingHorizontal());
EXPECT_TRUE(ac.getSwingVertical());
ac.setSwingVertical(false);
EXPECT_FALSE(ac.getSwingHorizontal());
EXPECT_FALSE(ac.getSwingVertical());
}
TEST(TestDaikin216Class, FanSpeed) {
IRDaikin216 ac(0);
ac.begin();
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
// Unexpected value should default to Auto.
ac.setFan(255);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax);
EXPECT_EQ(kDaikinFanMax, ac.getFan());
// Beyond Max should default to Auto.
ac.setFan(kDaikinFanMax + 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax - 1);
EXPECT_EQ(kDaikinFanMax - 1, ac.getFan());
ac.setFan(kDaikinFanMin);
EXPECT_EQ(kDaikinFanMin, ac.getFan());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(kDaikinFanMin + 1, ac.getFan());
// Beyond Min should default to Auto.
ac.setFan(kDaikinFanMin - 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(3);
EXPECT_EQ(3, ac.getFan());
ac.setFan(kDaikinFanAuto);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanQuiet);
EXPECT_EQ(kDaikinFanQuiet, ac.getFan());
}
TEST(TestDaikin216Class, QuietAndPowerful) {
IRDaikin216 ac(0);
ac.begin();
ac.setQuiet(false);
ac.setPowerful(false);
EXPECT_FALSE(ac.getQuiet());
EXPECT_FALSE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_FALSE(ac.getQuiet());
EXPECT_TRUE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
EXPECT_FALSE(ac.getPowerful());
ac.setQuiet(false);
EXPECT_FALSE(ac.getQuiet());
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_FALSE(ac.getQuiet());
EXPECT_TRUE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
}
TEST(TestDaikin216Class, ExampleStates) {
IRDaikin216 ac(0);
ac.begin();
// https://github.com/crankyoldgit/IRremoteESP8266/pull/690#issuecomment-487770194
uint8_t state[kDaikin216StateLength] = {
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x02,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x21, 0xC0, 0x00, 0xA0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x53};
ac.setRaw(state);
EXPECT_EQ(
"Power: On, Mode: 2 (Dry), Temp: 32C, Fan: 10 (Auto), "
"Swing(H): Off, Swing(V): Off, "
"Quiet: Off, Powerful: Off",
ac.toString());
}
TEST(TestDaikin216Class, ReconstructKnownState) {
IRDaikin216 ac(0);
ac.begin();
// https://github.com/crankyoldgit/IRremoteESP8266/issues/689#issue-438086949
uint8_t expectedState[kDaikin216StateLength] = {
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x02,
0x11, 0xDA, 0x27, 0x00, 0x00, 0x00, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x98};
ac.setPower(false);
ac.setMode(kDaikinAuto);
ac.setTemp(19);
ac.setFan(kDaikinFanAuto);
ac.setSwingHorizontal(false);
ac.setSwingVertical(false);
ac.setQuiet(false);
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 19C, Fan: 10 (Auto), "
"Swing(H): Off, Swing(V): Off, "
"Quiet: Off, Powerful: Off",
ac.toString());
EXPECT_STATE_EQ(expectedState, ac.getRaw(), kDaikin216Bits);
}
// https://github.com/crankyoldgit/IRremoteESP8266/issues/689
TEST(TestDecodeDaikin216, RealExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
// https://github.com/crankyoldgit/IRremoteESP8266/issues/689#issue-438086949
uint16_t rawData[439] = {
3402, 1770, 382, 1340, 382, 480, 382, 478, 382, 480, 380, 1342, 382, 478,
356, 504, 382, 480, 380, 478, 384, 1342, 380, 480, 380, 1342, 382, 1342,
382, 478, 382, 1340, 382, 1340, 384, 1340, 382, 1342, 382, 1340, 380, 480,
382, 480, 382, 1296, 426, 480, 380, 480, 382, 480, 380, 480, 382, 480,
382, 478, 382, 1342, 382, 1342, 382, 1340, 356, 1368, 382, 478, 382, 480,
382, 478, 380, 480, 382, 480, 382, 480, 382, 478, 382, 480, 382, 478, 358,
504, 382, 480, 380, 480, 382, 480, 382, 480, 380, 480, 382, 478, 382, 480,
382, 478, 382, 480, 354, 506, 354, 506, 380, 480, 382, 480, 382, 480, 382,
480, 380, 1342, 382, 480, 382, 480, 382, 478, 382, 478, 382, 478, 384,
478, 382, 29652, 3426, 1772, 382, 1340, 382, 480, 380, 478, 382, 480, 382,
1342, 382, 480, 382, 480, 382, 478, 356, 506, 382, 1342, 380, 480, 382,
1340, 382, 1340, 382, 478, 356, 1366, 382, 1340, 384, 1340, 382, 1340,
382, 1342, 382, 478, 382, 478, 382, 1340, 382, 478, 382, 478, 382, 478,
382, 480, 382, 480, 384, 478, 358, 504, 382, 478, 382, 480, 382, 478, 382,
480, 382, 480, 382, 478, 382, 480, 382, 478, 382, 478, 382, 478, 382, 478,
384, 478, 382, 478, 360, 500, 358, 504, 382, 478, 382, 480, 382, 480, 382,
478, 382, 478, 382, 1340, 382, 1342, 382, 480, 380, 480, 382, 1342, 382,
478, 382, 480, 356, 506, 382, 478, 382, 480, 382, 480, 356, 506, 382, 478,
382, 480, 382, 478, 382, 480, 382, 478, 382, 480, 380, 480, 380, 480, 382,
1342, 382, 478, 382, 1342, 382, 480, 382, 480, 382, 478, 382, 478, 382,
480, 382, 478, 382, 480, 356, 504, 384, 478, 382, 480, 382, 480, 380, 480,
382, 478, 382, 480, 382, 480, 382, 478, 356, 504, 384, 478, 380, 480, 382,
480, 382, 480, 382, 478, 356, 506, 382, 478, 382, 480, 380, 480, 382, 478,
382, 480, 382, 478, 382, 480, 358, 504, 382, 478, 382, 478, 356, 504, 382,
478, 382, 480, 382, 478, 382, 478, 382, 478, 382, 480, 380, 480, 382, 480,
380, 480, 356, 506, 356, 504, 382, 480, 382, 478, 382, 478, 382, 478, 382,
478, 382, 480, 382, 478, 382, 480, 382, 480, 382, 1340, 382, 1342, 382,
478, 384, 478, 382, 478, 382, 480, 380, 480, 382, 478, 382, 480, 356, 506,
382, 478, 382, 480, 382, 478, 356, 506, 380, 480, 382, 478, 382, 478, 382,
478, 382, 480, 382, 480, 380, 480, 382, 1342, 382, 1340, 382, 480, 356,
504, 382, 1342, 382}; // UNKNOWN E0E32232
uint8_t expectedState[kDaikin216StateLength] = {
// 8 bytes
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x02,
// 19 bytes
0x11, 0xDA, 0x27, 0x00, 0x00, 0x00, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x98};
irsend.begin();
irsend.reset();
irsend.sendRaw(rawData, 439, 38000);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN216, irsend.capture.decode_type);
ASSERT_EQ(kDaikin216Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
IRDaikin216 ac(0);
ac.setRaw(irsend.capture.state);
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 19C, Fan: 10 (Auto), "
"Swing(H): Off, Swing(V): Off, "
"Quiet: Off, Powerful: Off",
ac.toString());
}
// https://github.com/crankyoldgit/IRremoteESP8266/issues/689
TEST(TestDecodeDaikin216, SyntheticExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
// https://github.com/crankyoldgit/IRremoteESP8266/issues/689#issue-438086949
uint8_t expectedState[kDaikin216StateLength] = {
// 8 bytes
0x11, 0xDA, 0x27, 0xF0, 0x00, 0x00, 0x00, 0x02,
// 19 bytes
0x11, 0xDA, 0x27, 0x00, 0x00, 0x00, 0x26, 0x00, 0xA0, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x98};
irsend.begin();
irsend.reset();
irsend.sendDaikin216(expectedState);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN216, irsend.capture.decode_type);
ASSERT_EQ(kDaikin216Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
}
TEST(TestDaikinClass, toCommon) {
IRDaikinESP ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMax);
ac.setSwingVertical(true);
ac.setSwingHorizontal(true);
ac.setQuiet(false);
ac.setPowerful(true);
ac.setEcono(false);
ac.setMold(true);
// Now test it.
ASSERT_EQ(decode_type_t::DAIKIN, ac.toCommon().protocol);
ASSERT_EQ(-1, ac.toCommon().model);
ASSERT_TRUE(ac.toCommon().power);
ASSERT_TRUE(ac.toCommon().celsius);
ASSERT_EQ(20, ac.toCommon().degrees);
ASSERT_TRUE(ac.toCommon().turbo);
ASSERT_TRUE(ac.toCommon().clean);
ASSERT_FALSE(ac.toCommon().quiet);
ASSERT_FALSE(ac.toCommon().econo);
ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode);
ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed);
ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv);
ASSERT_EQ(stdAc::swingh_t::kAuto, ac.toCommon().swingh);
// Unsupported.
ASSERT_FALSE(ac.toCommon().filter);
ASSERT_FALSE(ac.toCommon().light);
ASSERT_FALSE(ac.toCommon().beep);
ASSERT_EQ(-1, ac.toCommon().sleep);
ASSERT_EQ(-1, ac.toCommon().clock);
}
TEST(TestDaikin2Class, toCommon) {
IRDaikin2 ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMax);
ac.setSwingVertical(kDaikin2SwingVHigh + 3);
ac.setSwingHorizontal(kDaikin2SwingHAuto);
ac.setQuiet(false);
ac.setPowerful(true);
ac.setEcono(false);
ac.setMold(true);
ac.setLight(true);
ac.setPurify(true);
ac.setBeep(true);
ac.enableSleepTimer(6 * 60);
// Now test it.
ASSERT_EQ(decode_type_t::DAIKIN2, ac.toCommon().protocol);
ASSERT_EQ(-1, ac.toCommon().model);
ASSERT_TRUE(ac.toCommon().power);
ASSERT_TRUE(ac.toCommon().celsius);
ASSERT_EQ(20, ac.toCommon().degrees);
ASSERT_TRUE(ac.toCommon().turbo);
ASSERT_TRUE(ac.toCommon().clean);
ASSERT_FALSE(ac.toCommon().quiet);
ASSERT_FALSE(ac.toCommon().econo);
ASSERT_TRUE(ac.toCommon().light);
ASSERT_TRUE(ac.toCommon().filter);
ASSERT_TRUE(ac.toCommon().beep);
ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode);
ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed);
ASSERT_EQ(stdAc::swingv_t::kMiddle, ac.toCommon().swingv);
ASSERT_EQ(stdAc::swingh_t::kOff, ac.toCommon().swingh);
ASSERT_EQ(6 * 60, ac.toCommon().sleep);
// Unsupported.
ASSERT_EQ(-1, ac.toCommon().clock);
}
TEST(TestDaikin216Class, toCommon) {
IRDaikin216 ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMax);
ac.setSwingVertical(true);
ac.setSwingHorizontal(true);
ac.setQuiet(false);
ac.setPowerful(true);
// Now test it.
ASSERT_EQ(decode_type_t::DAIKIN216, ac.toCommon().protocol);
ASSERT_EQ(-1, ac.toCommon().model);
ASSERT_TRUE(ac.toCommon().power);
ASSERT_TRUE(ac.toCommon().celsius);
ASSERT_EQ(20, ac.toCommon().degrees);
ASSERT_TRUE(ac.toCommon().turbo);
ASSERT_FALSE(ac.toCommon().quiet);
ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode);
ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed);
ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv);
ASSERT_EQ(stdAc::swingh_t::kAuto, ac.toCommon().swingh);
// Unsupported.
ASSERT_FALSE(ac.toCommon().clean);
ASSERT_FALSE(ac.toCommon().econo);
ASSERT_FALSE(ac.toCommon().light);
ASSERT_FALSE(ac.toCommon().filter);
ASSERT_FALSE(ac.toCommon().beep);
ASSERT_EQ(-1, ac.toCommon().sleep);
ASSERT_EQ(-1, ac.toCommon().clock);
}
// https://github.com/crankyoldgit/IRremoteESP8266/issues/731
TEST(TestDecodeDaikin160, RealExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint16_t rawData[327] = {
5024, 2144, 342, 1786, 344, 706, 342, 706, 344, 706, 342, 1786, 342, 706,
342, 708, 342, 708, 342, 708, 342, 1786, 342, 708, 342, 1786, 342, 1788,
342, 708, 342, 1786, 344, 1786, 342, 1786, 342, 1786, 342, 1786, 342, 708,
342, 708, 340, 1786, 344, 706, 342, 708, 342, 706, 342, 708, 342, 708,
342, 706, 342, 1786, 342, 1788, 342, 1786, 342, 1786, 342, 1788, 342, 706,
342, 1788, 342, 1786, 342, 706, 342, 706, 342, 708, 342, 708, 342, 708,
342, 708, 342, 706, 342, 708, 342, 708, 342, 706, 342, 706, 342, 708, 342,
1786, 342, 1786, 342, 1786, 342, 1788, 342, 706, 342, 706, 342, 706, 342,
708, 342, 29442, 5022, 2146, 342, 1786, 342, 706, 342, 708, 342, 708, 342,
1788, 342, 706, 342, 706, 342, 706, 342, 706, 342, 1788, 342, 708, 342,
1786, 342, 1786, 342, 708, 342, 1786, 342, 1788, 342, 1786, 342, 1786,
342, 1786, 342, 706, 342, 706, 342, 1786, 344, 706, 342, 706, 344, 706,
342, 706, 342, 706, 342, 708, 342, 706, 342, 706, 342, 706, 342, 706, 342,
1786, 342, 1786, 342, 706, 342, 706, 342, 1788, 342, 708, 342, 1786, 342,
1786, 342, 706, 342, 706, 342, 706, 342, 708, 342, 1786, 342, 1786, 342,
708, 342, 708, 342, 1786, 342, 706, 342, 706, 344, 706, 342, 1786, 342,
708, 342, 706, 342, 706, 342, 708, 342, 706, 342, 708, 342, 706, 342, 708,
342, 706, 342, 704, 344, 706, 342, 706, 344, 706, 342, 706, 342, 708, 342,
706, 342, 706, 344, 706, 342, 706, 342, 706, 344, 1786, 342, 1786, 342,
1786, 342, 1786, 342, 706, 342, 706, 344, 706, 342, 706, 342, 1786, 344,
706, 342, 1786, 342, 706, 342, 708, 342, 706, 342, 706, 344, 706, 342,
706, 342, 706, 342, 1786, 342, 706, 344, 706, 342, 706, 342, 708, 342,
706, 342, 1788, 342, 1786, 342, 706, 344, 1786, 344, 706, 344, 1786, 342,
708, 342}; // UNKNOWN 99CC993
uint8_t expectedState[kDaikin160StateLength] = {
// 7 bytes
0x11, 0xDA, 0x27, 0xF0, 0x0D, 0x00, 0x0F,
// 13 bytes
0x11, 0xDA, 0x27, 0x00, 0xD3, 0x30, 0x11,
0x00, 0x00, 0x1E, 0x0A, 0x08, 0x56};
irsend.begin();
irsend.reset();
irsend.sendRaw(rawData, 327, 38000);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN160, irsend.capture.decode_type);
ASSERT_EQ(kDaikin160Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
IRDaikin160 ac(0);
ac.setRaw(irsend.capture.state);
EXPECT_EQ("Power: Off, Mode: 3 (Cool), Temp: 25C, Fan: 10 (Auto), "
"Swing(V): 1 (Lowest)", ac.toString());
}
TEST(TestDecodeDaikin160, SyntheticExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint8_t expectedState[kDaikin160StateLength] = {
// 7 bytes
0x11, 0xDA, 0x27, 0xF0, 0x0D, 0x00, 0x0F,
// 13 bytes
0x11, 0xDA, 0x27, 0x00, 0xD3, 0x30, 0x11,
0x00, 0x00, 0x1E, 0x0A, 0x08, 0x56};
irsend.begin();
irsend.reset();
irsend.sendDaikin160(expectedState);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN160, irsend.capture.decode_type);
ASSERT_EQ(kDaikin160Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
}
TEST(TestDaikin160Class, toCommon) {
IRDaikin160 ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMax);
ac.setSwingVertical(kDaikin160SwingVAuto);
// Now test it.
ASSERT_EQ(decode_type_t::DAIKIN160, ac.toCommon().protocol);
ASSERT_EQ(-1, ac.toCommon().model);
ASSERT_TRUE(ac.toCommon().power);
ASSERT_TRUE(ac.toCommon().celsius);
ASSERT_EQ(20, ac.toCommon().degrees);
ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode);
ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed);
ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv);
// Unsupported.
ASSERT_EQ(stdAc::swingh_t::kOff, ac.toCommon().swingh);
ASSERT_FALSE(ac.toCommon().turbo);
ASSERT_FALSE(ac.toCommon().quiet);
ASSERT_FALSE(ac.toCommon().clean);
ASSERT_FALSE(ac.toCommon().econo);
ASSERT_FALSE(ac.toCommon().light);
ASSERT_FALSE(ac.toCommon().filter);
ASSERT_FALSE(ac.toCommon().beep);
ASSERT_EQ(-1, ac.toCommon().sleep);
ASSERT_EQ(-1, ac.toCommon().clock);
}
TEST(TestDaikin160Class, FanSpeed) {
IRDaikin160 ac(0);
ac.begin();
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
// Unexpected value should default to Auto.
ac.setFan(255);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax);
EXPECT_EQ(kDaikinFanMax, ac.getFan());
// Beyond Max should default to Auto.
ac.setFan(kDaikinFanMax + 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax - 1);
EXPECT_EQ(kDaikinFanMax - 1, ac.getFan());
ac.setFan(kDaikinFanMin);
EXPECT_EQ(kDaikinFanMin, ac.getFan());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(kDaikinFanMin + 1, ac.getFan());
// Beyond Min should default to Auto.
ac.setFan(kDaikinFanMin - 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(3);
EXPECT_EQ(3, ac.getFan());
ac.setFan(kDaikinFanAuto);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanQuiet);
EXPECT_EQ(kDaikinFanQuiet, ac.getFan());
}
TEST(TestDaikin160Class, VaneSwing) {
IRDaikin160 ac(0);
ac.begin();
ac.setSwingVertical(kDaikin160SwingVAuto);
EXPECT_EQ(kDaikin160SwingVAuto, ac.getSwingVertical());
ac.setSwingVertical(kDaikin160SwingVHigh);
EXPECT_EQ(kDaikin160SwingVHigh, ac.getSwingVertical());
ac.setSwingVertical(255);
EXPECT_EQ(kDaikin160SwingVAuto, ac.getSwingVertical());
EXPECT_EQ(kDaikin160SwingVHighest,
IRDaikin160::convertSwingV(stdAc::swingv_t::kHighest));
EXPECT_EQ(kDaikin160SwingVLowest,
IRDaikin160::convertSwingV(stdAc::swingv_t::kLowest));
EXPECT_EQ(kDaikin160SwingVMiddle,
IRDaikin160::convertSwingV(stdAc::swingv_t::kMiddle));
}
TEST(TestDaikin160Class, Power) {
IRDaikin160 ac(0);
ac.begin();
ac.on();
EXPECT_TRUE(ac.getPower());
ac.off();
EXPECT_FALSE(ac.getPower());
ac.setPower(true);
EXPECT_TRUE(ac.getPower());
ac.setPower(false);
EXPECT_FALSE(ac.getPower());
}
TEST(TestDaikin160Class, Temperature) {
IRDaikin160 ac(0);
ac.begin();
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
}
TEST(TestDaikin160Class, OperatingMode) {
IRDaikin160 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinCool);
EXPECT_EQ(kDaikinCool, ac.getMode());
ac.setMode(kDaikinHeat);
EXPECT_EQ(kDaikinHeat, ac.getMode());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikinFan, ac.getMode());
ac.setMode(kDaikinFan + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinAuto + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikinAuto, ac.getMode());
}
TEST(TestDaikin160Class, HumanReadable) {
IRDaikin160 ac(0);
EXPECT_EQ(
"Power: Off, Mode: 3 (Cool), Temp: 25C, Fan: 10 (Auto), "
"Swing(V): 1 (Lowest)",
ac.toString());
ac.setMode(kDaikinAuto);
ac.setTemp(19);
ac.setFan(kDaikinFanMin);
ac.setSwingVertical(kDaikin160SwingVAuto);
ac.setPower(true);
EXPECT_EQ(
"Power: On, Mode: 0 (Auto), Temp: 19C, Fan: 1 (Low), "
"Swing(V): 15 (Auto)",
ac.toString());
}
TEST(TestDaikin176Class, FanControl) {
IRDaikin176 ac(0);
EXPECT_EQ(
"Power: Off, Mode: 7 (Cool), Temp: 9C, Fan: 1 (Low), Swing(H): 6 (Off)",
ac.toString());
ac.setFan(kDaikinFanMin);
ac.setPower(true);
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 9C, Fan: 1 (Low), Swing(H): 6 (Off)",
ac.toString());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 9C, Fan: 3 (High), Swing(H): 6 (Off)",
ac.toString());
ac.setFan(kDaikin176FanMax);
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 9C, Fan: 3 (High), Swing(H): 6 (Off)",
ac.toString());
// Real state from remote
// https://github.com/crankyoldgit/IRremoteESP8266/pull/826#issuecomment-513168270
uint8_t state[kDaikin176StateLength] = {
0x11, 0xDA, 0x17, 0x18, 0x04, 0x00, 0x1E,
0x11, 0xDA, 0x17, 0x18, 0x00, 0x73, 0x00, 0x21, 0x00, 0x00, 0x22, 0x35,
0x00, 0x20, 0x25};
ac.setRaw(state);
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 26C, Fan: 3 (High), "
"Swing(H): 5 (Auto)",
ac.toString());
}
TEST(TestDaikin176Class, convertFan) {
EXPECT_EQ(kDaikinFanMin, IRDaikin176::convertFan(stdAc::fanspeed_t::kMin));
EXPECT_EQ(kDaikinFanMin, IRDaikin176::convertFan(stdAc::fanspeed_t::kLow));
EXPECT_EQ(kDaikin176FanMax,
IRDaikin176::convertFan(stdAc::fanspeed_t::kMedium));
EXPECT_EQ(kDaikin176FanMax,
IRDaikin176::convertFan(stdAc::fanspeed_t::kHigh));
EXPECT_EQ(kDaikin176FanMax, IRDaikin176::convertFan(stdAc::fanspeed_t::kMax));
EXPECT_EQ(kDaikin176FanMax,
IRDaikin176::convertFan(stdAc::fanspeed_t::kAuto));
}
TEST(TestDaikin176Class, SimulateIRacDaikin176) {
IRDaikin176 ac(0);
ac.setPower(true);
ac.setMode(ac.convertMode(stdAc::opmode_t::kCool));
ac.setTemp(26);
ac.setFan(ac.convertFan(stdAc::fanspeed_t::kMax));
ac.setSwingHorizontal(kDaikin176SwingHOff);
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 26C, Fan: 3 (High), Swing(H): 6 (Off)",
ac.toString());
ac.setSwingHorizontal(ac.convertSwingH(stdAc::swingh_t::kAuto));
EXPECT_EQ(
"Power: On, Mode: 7 (Cool), Temp: 26C, Fan: 3 (High), "
"Swing(H): 5 (Auto)",
ac.toString());
}
TEST(TestDaikin176Class, OperatingMode) {
IRDaikin176 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
ac.setMode(kDaikin176Cool);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
ac.setMode(kDaikinHeat);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikinFan, ac.getMode());
ac.setMode(kDaikin176Cool + 1);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
ac.setMode(kDaikinAuto + 1);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikin176Cool, ac.getMode());
}
TEST(TestDaikin176Class, Temperature) {
IRDaikin176 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
// Temp should be locked to kDaikin176DryFanTemp when in Dry or Fan Mode.
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikin176DryFanTemp, ac.getTemp());
ac.setMode(kDaikin176Cool);
EXPECT_EQ(29, ac.getTemp());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
EXPECT_EQ(kDaikin176DryFanTemp, ac.getTemp());
ac.setMode(kDaikin176Cool);
EXPECT_EQ(29, ac.getTemp());
ac.setMode(kDaikinFan);
ac.setTemp(25);
EXPECT_EQ(kDaikin176DryFanTemp, ac.getTemp());
ac.setMode(kDaikinHeat);
EXPECT_EQ(25, ac.getTemp());
}
TEST(TestDaikin176Class, Power) {
IRDaikin176 ac(0);
ac.begin();
ac.on();
EXPECT_TRUE(ac.getPower());
ac.off();
EXPECT_FALSE(ac.getPower());
ac.setPower(true);
EXPECT_TRUE(ac.getPower());
ac.setPower(false);
EXPECT_FALSE(ac.getPower());
}
TEST(TestDaikin176Class, VaneSwing) {
IRDaikin176 ac(0);
ac.begin();
ac.setSwingHorizontal(kDaikin176SwingHAuto);
EXPECT_EQ(kDaikin176SwingHAuto, ac.getSwingHorizontal());
ac.setSwingHorizontal(0);
EXPECT_EQ(kDaikin176SwingHAuto, ac.getSwingHorizontal());
ac.setSwingHorizontal(kDaikin176SwingHOff);
EXPECT_EQ(kDaikin176SwingHOff, ac.getSwingHorizontal());
ac.setSwingHorizontal(255);
EXPECT_EQ(kDaikin176SwingHAuto, ac.getSwingHorizontal());
EXPECT_EQ(kDaikin176SwingHAuto,
IRDaikin176::convertSwingH(stdAc::swingh_t::kAuto));
EXPECT_EQ(kDaikin176SwingHOff,
IRDaikin176::convertSwingH(stdAc::swingh_t::kOff));
EXPECT_EQ(kDaikin176SwingHAuto,
IRDaikin176::convertSwingH(stdAc::swingh_t::kLeft));
}
TEST(TestDaikin176Class, ReconstructKnownStates) {
IRDaikin176 ac(0);
ac.begin();
// Data from:
// https://github.com/crankyoldgit/IRremoteESP8266/pull/826#issuecomment-513531138
// Power: On, Mode: 7 (Cool), Temp: 25C, Fan: 3 (Max), Swing(H): 5 (Auto)
// 11DA171804001E11DA17180073002100002035002023
uint8_t on_cool_25_max_auto[22] = {
0x11, 0xDA, 0x17, 0x18, 0x04, 0x00, 0x1E,
0x11, 0xDA, 0x17, 0x18, 0x00, 0x73, 0x00, 0x21, 0x00, 0x00, 0x20, 0x35,
0x00, 0x20, 0x23};
// Power: On, Mode: 6 (Fan), Temp: 17C, Fan: 3 (Max), Swing(H): 5 (Auto)
// 11DA171804001E11DA171800630401000010350020E7
uint8_t on_fan_17_max_auto[22] = {
0x11, 0xDA, 0x17, 0x18, 0x04, 0x00, 0x1E,
0x11, 0xDA, 0x17, 0x18, 0x00, 0x63, 0x04, 0x01, 0x00, 0x00, 0x10, 0x35,
0x00, 0x20, 0xE7};
// Power: On, Mode: 2 (Dry), Temp: 17C, Fan: 3 (Max), Swing(H): 5 (Auto)
// 11DA171804001E11DA17180023047100001035002017
uint8_t on_dry_17_max_auto[22] = {
0x11, 0xDA, 0x17, 0x18, 0x04, 0x00, 0x1E,
0x11, 0xDA, 0x17, 0x18, 0x00, 0x23, 0x04, 0x71, 0x00, 0x00, 0x10, 0x35,
0x00, 0x20, 0x17};
// Power: On, Mode: 7 (Cool), Temp: 25C, Fan: 3 (Max), Swing(H): 5 (Auto)
// 11DA171804001E11DA17180073042100002035002027
uint8_t on_cool_25_max_auto_v2[22] = {
0x11, 0xDA, 0x17, 0x18, 0x04, 0x00, 0x1E,
0x11, 0xDA, 0x17, 0x18, 0x00, 0x73, 0x04, 0x21, 0x00, 0x00, 0x20, 0x35,
0x00, 0x20, 0x27};
ac.setMode(kDaikin176Cool);
ac.setPower(true);
ac.setTemp(25);
ac.setFan(kDaikin176FanMax);
ac.setSwingHorizontal(true);
EXPECT_STATE_EQ(on_cool_25_max_auto, ac.getRaw(), kDaikin176Bits);
ac.setMode(kDaikinFan);
EXPECT_STATE_EQ(on_fan_17_max_auto, ac.getRaw(), kDaikin176Bits);
ac.setMode(kDaikinDry);
EXPECT_STATE_EQ(on_dry_17_max_auto, ac.getRaw(), kDaikin176Bits);
ac.setMode(kDaikin176Cool);
EXPECT_STATE_EQ(on_cool_25_max_auto_v2, ac.getRaw(), kDaikin176Bits);
}
// Ref: https://github.com/crankyoldgit/IRremoteESP8266/issues/827
// Data from:
// https://docs.google.com/spreadsheets/d/1-YJnHyzy6bId5QmjTEZuw8_wSufESoIl-L_VEF-o8lM/edit?usp=sharing
TEST(TestDecodeDaikin128, RealExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint16_t rawData[265] = {
9846, 9794, 9848, 9796, 4638, 2512, 348, 382, 352, 954, 352, 956, 352,
382, 352, 956, 352, 384, 352, 382, 352, 386, 352, 382, 352, 954, 352, 384,
352, 382, 352, 954, 352, 384, 352, 382, 352, 386, 352, 382, 352, 382, 354,
382, 354, 382, 352, 382, 352, 954, 352, 382, 352, 384, 352, 954, 352, 382,
352, 382, 352, 954, 352, 954, 354, 382, 352, 382, 352, 386, 352, 954, 354,
954, 352, 954, 352, 384, 352, 382, 352, 382, 352, 954, 352, 384, 354, 382,
352, 954, 352, 382, 352, 382, 352, 382, 352, 956, 352, 382, 354, 384, 354,
382, 354, 954, 352, 954, 352, 382, 352, 382, 352, 954, 352, 382, 352, 384,
354, 954, 352, 382, 352, 954, 352, 954, 352, 382, 352, 954, 352, 382, 352,
956, 352, 20306, 376, 954, 352, 384, 352, 382, 352, 382, 354, 382, 352,
954, 352, 382, 352, 958, 352, 384, 352, 382, 352, 382, 352, 382, 352, 382,
354, 382, 352, 382, 352, 386, 352, 382, 352, 382, 354, 382, 352, 384, 352,
382, 352, 382, 352, 382, 354, 384, 354, 382, 354, 382, 354, 382, 352, 382,
352, 382, 352, 382, 352, 382, 352, 386, 354, 382, 352, 382, 352, 382, 352,
382, 352, 382, 352, 382, 354, 382, 352, 384, 352, 382, 354, 382, 354, 382,
354, 382, 352, 382, 354, 382, 354, 382, 354, 384, 354, 382, 354, 382, 352,
382, 352, 382, 354, 382, 352, 382, 352, 382, 352, 386, 354, 952, 354, 954,
352, 382, 352, 954, 354, 382, 352, 382, 354, 382, 354, 382, 4618
}; // UNKNOWN DBA1F5E3
uint8_t expectedState[kDaikin128StateLength] = {
// 8 bytes
0x16, 0x12, 0x20, 0x19, 0x47, 0x22, 0x26, 0xAD,
// 8 bytes
0xA1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0B};
irsend.begin();
irsend.reset();
irsend.sendRaw(rawData, 265, 38000);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN128, irsend.capture.decode_type);
ASSERT_EQ(kDaikin128Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
EXPECT_EQ(
"Power Toggle: On, Mode: 2 (Cool), Temp: 26C, Fan: 1 (Auto), "
"Powerful: Off, Quiet: Off, Swing(V): On, Sleep: Off, "
"Econo: Off, Clock: 19:20, "
"On Timer: Off, On Timer: 07:30, Off Timer: Off, Off Timer: 22:00, "
"Light Toggle: 0 (Off)",
IRAcUtils::resultAcToString(&irsend.capture));
}
// Ref: https://github.com/crankyoldgit/IRremoteESP8266/issues/827
// Data from:
// https://docs.google.com/spreadsheets/d/1-YJnHyzy6bId5QmjTEZuw8_wSufESoIl-L_VEF-o8lM/edit?usp=sharing
TEST(TestDecodeDaikin128, SyntheticSelfDecode) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint8_t expectedState[kDaikin128StateLength] = {
// 8 bytes
0x16, 0x12, 0x20, 0x19, 0x47, 0x22, 0x26, 0xAD,
// 8 bytes
0xA1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0B};
irsend.begin();
irsend.reset();
irsend.sendDaikin128(expectedState);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN128, irsend.capture.decode_type);
ASSERT_EQ(kDaikin128Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
}
TEST(TestDaikin128Class, Checksums) {
IRDaikin128 ac(0);
uint8_t knownGood[kDaikin128StateLength] = {
0x16, 0x12, 0x20, 0x19, 0x47, 0x22, 0x26, 0xAD,
0xA1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0B};
uint8_t knownBad[kDaikin128StateLength] = {
0x16, 0x12, 0x20, 0x19, 0x47, 0x22, 0x26, 0x0D,
0xA1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
EXPECT_EQ(0xA, ac.calcFirstChecksum(knownGood));
EXPECT_EQ(0x0B, ac.calcSecondChecksum(knownGood));
EXPECT_TRUE(ac.validChecksum(knownGood));
ac.setRaw(knownBad);
EXPECT_STATE_EQ(knownGood, ac.getRaw(), kDaikin128Bits);
}
TEST(TestDaikin128Class, PowerToggle) {
IRDaikin128 ac(0);
ac.begin();
ac.setPowerToggle(true);
EXPECT_TRUE(ac.getPowerToggle());
ac.setPowerToggle(false);
EXPECT_FALSE(ac.getPowerToggle());
ac.setPowerToggle(true);
EXPECT_TRUE(ac.getPowerToggle());
}
TEST(TestDaikin128Class, SwingVertical) {
IRDaikin128 ac(0);
ac.begin();
ac.setSwingVertical(true);
EXPECT_TRUE(ac.getSwingVertical());
ac.setSwingVertical(false);
EXPECT_FALSE(ac.getSwingVertical());
ac.setSwingVertical(true);
EXPECT_TRUE(ac.getSwingVertical());
}
TEST(TestDaikin128Class, Sleep) {
IRDaikin128 ac(0);
ac.begin();
ac.setSleep(true);
EXPECT_TRUE(ac.getSleep());
ac.setSleep(false);
EXPECT_FALSE(ac.getSleep());
ac.setSleep(true);
EXPECT_TRUE(ac.getSleep());
}
TEST(TestDaikin128Class, Econo) {
IRDaikin128 ac(0);
ac.begin();
// Econo works in some modes
ac.setMode(kDaikin128Heat);
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
ac.setEcono(false);
EXPECT_FALSE(ac.getEcono());
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
// But not some some modes
ac.setMode(kDaikin128Auto);
EXPECT_FALSE(ac.getEcono());
ac.setEcono(true);
EXPECT_FALSE(ac.getEcono());
}
TEST(TestDaikin128Class, FanSpeed) {
IRDaikin128 ac(0);
ac.begin();
ac.setMode(kDaikin128Cool);
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikin128FanAuto, ac.getFan());
ac.setFan(255);
EXPECT_EQ(kDaikin128FanAuto, ac.getFan());
ac.setFan(5);
EXPECT_EQ(kDaikin128FanAuto, ac.getFan());
ac.setFan(kDaikin128FanHigh);
EXPECT_EQ(kDaikin128FanHigh, ac.getFan());
// Beyond Quiet should default to Auto.
ac.setFan(kDaikin128FanQuiet + 1);
EXPECT_EQ(kDaikin128FanAuto, ac.getFan());
ac.setFan(kDaikin128FanMed);
EXPECT_EQ(kDaikin128FanMed, ac.getFan());
ac.setFan(kDaikin128FanLow);
EXPECT_EQ(kDaikin128FanLow, ac.getFan());
ac.setFan(kDaikin128FanPowerful);
EXPECT_EQ(kDaikin128FanPowerful, ac.getFan());
ac.setFan(kDaikin128FanAuto);
EXPECT_EQ(kDaikin128FanAuto, ac.getFan());
ac.setFan(kDaikin128FanQuiet);
EXPECT_EQ(kDaikin128FanQuiet, ac.getFan());
}
TEST(TestDaikin128Class, OperatingMode) {
IRDaikin128 ac(0);
ac.begin();
ac.setMode(0);
EXPECT_EQ(kDaikin128Auto, ac.getMode());
ac.setMode(kDaikin128Cool);
EXPECT_EQ(kDaikin128Cool, ac.getMode());
ac.setMode(kDaikin128Auto);
EXPECT_EQ(kDaikin128Auto, ac.getMode());
ac.setMode(kDaikin128Heat);
EXPECT_EQ(kDaikin128Heat, ac.getMode());
ac.setMode(kDaikin128Dry);
EXPECT_EQ(kDaikin128Dry, ac.getMode());
ac.setMode(kDaikin128Fan);
EXPECT_EQ(kDaikin128Fan, ac.getMode());
ac.setMode(3);
EXPECT_EQ(kDaikin128Auto, ac.getMode());
ac.setMode(kDaikin128Auto + 1);
EXPECT_EQ(kDaikin128Auto, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikin128Auto, ac.getMode());
}
TEST(TestDaikin128Class, Quiet) {
IRDaikin128 ac(0);
ac.begin();
// Quiet works in some modes
ac.setMode(kDaikin128Cool);
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
ac.setQuiet(false);
EXPECT_FALSE(ac.getQuiet());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
// But not some some modes
ac.setMode(kDaikin128Auto);
EXPECT_FALSE(ac.getQuiet());
ac.setQuiet(true);
EXPECT_FALSE(ac.getQuiet());
}
TEST(TestDaikin128Class, Powerful) {
IRDaikin128 ac(0);
ac.begin();
// Powerful works in some modes
ac.setMode(kDaikin128Cool);
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setPowerful(false);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
// But not some some modes
ac.setMode(kDaikin128Auto);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_FALSE(ac.getPowerful());
}
TEST(TestDaikin128Class, Temperature) {
IRDaikin128 ac(0);
ac.begin();
ac.setTemp(0);
EXPECT_EQ(kDaikin128MinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikin128MaxTemp, ac.getTemp());
ac.setTemp(kDaikin128MinTemp);
EXPECT_EQ(kDaikin128MinTemp, ac.getTemp());
ac.setTemp(kDaikin128MaxTemp);
EXPECT_EQ(kDaikin128MaxTemp, ac.getTemp());
ac.setTemp(kDaikin128MinTemp - 1);
EXPECT_EQ(kDaikin128MinTemp, ac.getTemp());
ac.setTemp(kDaikin128MaxTemp + 1);
EXPECT_EQ(kDaikin128MaxTemp, ac.getTemp());
ac.setTemp(kDaikin128MinTemp + 1);
EXPECT_EQ(kDaikin128MinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
}
// Test human readable output.
TEST(TestDaikin128Class, HumanReadable) {
IRDaikin128 ac(0);
ac.setPowerToggle(false);
ac.setMode(kDaikin128Auto);
ac.setTemp(25);
ac.setFan(kDaikin128FanAuto);
ac.setQuiet(false);
ac.setPowerful(false);
ac.setSleep(false);
ac.setEcono(false);
ac.setSwingVertical(true);
EXPECT_EQ(
"Power Toggle: Off, Mode: 10 (Auto), Temp: 25C, Fan: 1 (Auto), "
"Powerful: Off, Quiet: Off, Swing(V): On, "
"Sleep: Off, Econo: Off, Clock: 00:00, "
"On Timer: Off, On Timer: 00:00, Off Timer: Off, Off Timer: 00:00, "
"Light Toggle: 0 (Off)",
ac.toString());
ac.setMode(kDaikin128Cool);
ac.setTemp(16);
ac.setQuiet(true);
ac.setSwingVertical(false);
ac.setPowerToggle(true);
ac.setSleep(true);
ac.setEcono(true);
ac.setClock(18 * 60 + 33); // 18:33
ac.setOnTimer(10 * 60); // 10am
ac.setOnTimerEnabled(true);
ac.setOffTimer(21 * 60 + 30); // 9:30pm
ac.setOffTimerEnabled(true);
ac.setLightToggle(kDaikin128BitWall);
EXPECT_EQ(
"Power Toggle: On, Mode: 2 (Cool), Temp: 16C, Fan: 9 (Quiet), "
"Powerful: Off, Quiet: On, Swing(V): Off, "
"Sleep: On, Econo: On, Clock: 18:33, "
"On Timer: On, On Timer: 10:00, Off Timer: On, Off Timer: 21:30, "
"Light Toggle: 8 (Wall)",
ac.toString());
}
TEST(TestDaikin128Class, Clock) {
IRDaikin128 ac(0);
ac.begin();
ac.setClock(0);
EXPECT_EQ(0, ac.getClock());
ac.setClock(23 * 60 + 59);
EXPECT_EQ(23 * 60 + 59, ac.getClock());
ac.setClock(23 * 60 + 59 + 1);
EXPECT_EQ(0, ac.getClock());
ac.setClock(24 * 60 + 99);
EXPECT_EQ(0, ac.getClock());
}
TEST(TestDaikin128Class, Timers) {
IRDaikin128 ac(0);
ac.begin();
ac.setOnTimerEnabled(false);
EXPECT_FALSE(ac.getOnTimerEnabled());
ac.setOnTimerEnabled(true);
EXPECT_TRUE(ac.getOnTimerEnabled());
ac.setOnTimer(13 * 60 + 30);
EXPECT_EQ("13:30", irutils::minsToString(ac.getOnTimer()));
ac.setOnTimer(13 * 60 + 31);
EXPECT_EQ("13:30", irutils::minsToString(ac.getOnTimer()));
ac.setOnTimer(13 * 60 + 29);
EXPECT_EQ("13:00", irutils::minsToString(ac.getOnTimer()));
EXPECT_TRUE(ac.getOnTimerEnabled());
ac.setOnTimerEnabled(false);
EXPECT_FALSE(ac.getOnTimerEnabled());
ac.setOffTimerEnabled(false);
EXPECT_FALSE(ac.getOffTimerEnabled());
ac.setOffTimerEnabled(true);
EXPECT_TRUE(ac.getOffTimerEnabled());
ac.setOffTimer(1 * 60 + 30);
EXPECT_EQ("01:30", irutils::minsToString(ac.getOffTimer()));
ac.setOffTimer(23 * 60 + 31);
EXPECT_EQ("23:30", irutils::minsToString(ac.getOffTimer()));
ac.setOffTimer(24 * 60 + 29);
EXPECT_EQ("00:00", irutils::minsToString(ac.getOffTimer()));
EXPECT_TRUE(ac.getOffTimerEnabled());
ac.setOffTimerEnabled(false);
EXPECT_FALSE(ac.getOffTimerEnabled());
}
TEST(TestDaikin128Class, ReconstructKnownState) {
IRDaikin128 ac(0);
uint8_t expectedState[kDaikin128StateLength] = {
0x16, 0x12, 0x20, 0x19, 0x47, 0x22, 0x26, 0xAD,
0xA1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0B};
ac.begin();
ac.setPowerToggle(true);
ac.setMode(kDaikin128Cool);
ac.setTemp(26);
ac.setFan(kDaikin128FanAuto);
ac.setPowerful(false);
ac.setQuiet(false);
ac.setSwingVertical(true);
ac.setSleep(false);
ac.setEcono(false);
ac.setClock(19 * 60 + 20);
ac.setOnTimerEnabled(false);
ac.setOnTimer(7 * 60 + 30);
ac.setOffTimerEnabled(false);
ac.setOffTimer(22 * 60 + 0);
ac.setLightToggle(0);
EXPECT_STATE_EQ(expectedState, ac.getRaw(), kDaikin128Bits);
}
// Ref: https://github.com/crankyoldgit/IRremoteESP8266/issues/873
// Data from:
// https://github.com/crankyoldgit/IRremoteESP8266/issues/873#issue-485088080
TEST(TestDecodeDaikin152, RealExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint16_t rawData[319] = {
450, 420, 448, 446, 422, 444, 422, 446, 422, 446, 422, 25182, 3492, 1718,
450, 1288, 448, 422, 446, 448, 420, 446, 422, 1290, 448, 422, 446, 446,
422, 446, 424, 420, 448, 1290, 448, 446, 422, 1288, 448, 1288, 450, 420,
448, 1288, 448, 1288, 450, 1288, 448, 1288, 448, 1290, 448, 446, 422, 446,
422, 1288, 450, 446, 422, 420, 446, 446, 422, 422, 446, 446, 422, 420,
448, 422, 446, 446, 422, 446, 422, 446, 422, 420, 446, 446, 422, 446, 422,
422, 446, 446, 422, 422, 446, 446, 422, 446, 422, 446, 422, 446, 422, 446,
424, 444, 424, 446, 420, 446, 422, 446, 422, 424, 444, 444, 422, 424, 444,
1288, 450, 444, 422, 1288, 450, 1288, 450, 444, 422, 422, 446, 446, 422,
446, 422, 446, 422, 446, 422, 422, 446, 420, 448, 444, 422, 446, 422, 446,
422, 420, 448, 446, 422, 446, 422, 446, 422, 422, 446, 1286, 450, 422,
448, 446, 422, 446, 422, 422, 446, 420, 446, 422, 446, 446, 422, 422, 446,
446, 422, 422, 446, 446, 424, 444, 422, 420, 448, 446, 422, 420, 446, 446,
422, 446, 422, 420, 448, 444, 422, 422, 448, 444, 424, 420, 446, 446, 422,
446, 422, 422, 446, 444, 422, 446, 422, 444, 422, 446, 422, 420, 448, 446,
422, 420, 448, 446, 422, 446, 422, 446, 422, 446, 422, 446, 422, 444, 422,
1288, 450, 420, 448, 446, 420, 446, 422, 446, 422, 446, 424, 420, 448,
444, 422, 422, 446, 446, 424, 420, 448, 1312, 424, 420, 448, 1288, 448,
446, 422, 446, 424, 420, 446, 1288, 450, 1288, 450, 444, 422, 446, 422,
422, 448, 444, 422, 420, 448, 446, 422, 1288, 448, 446, 422, 446, 422,
444, 424, 444, 422, 446, 422, 446, 422, 420, 448, 446, 422, 420, 446,
1290, 448, 1288, 448, 420, 446, 1288, 448, 420, 446, 1288, 450, 444, 424,
1286, 450}; // UNKNOWN 2B9504D3
uint8_t expectedState[kDaikin152StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x00, 0x00, 0x34, 0x00, 0x40, 0x00,
0x00, 0x00, 0x00, 0x20, 0x00, 0xC5, 0x40, 0x00, 0xAB};
irsend.begin();
irsend.reset();
irsend.sendRaw(rawData, 319, 38000);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN152, irsend.capture.decode_type);
ASSERT_EQ(kDaikin152Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
EXPECT_EQ(
"Power: Off, Mode: 0 (Auto), Temp: 26C, Fan: 2 (UNKNOWN), Swing(V): Off, "
"Powerful: Off, Quiet: On, Econo: Off, Sensor: Off, Comfort: Off",
IRAcUtils::resultAcToString(&irsend.capture));
}
// https://github.com/crankyoldgit/IRremoteESP8266/issues/873
TEST(TestDecodeDaikin152, SyntheticExample) {
IRsendTest irsend(0);
IRrecv irrecv(0);
uint8_t expectedState[kDaikin152StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x00, 0x00, 0x34, 0x00, 0x40, 0x00,
0x00, 0x00, 0x00, 0x20, 0x00, 0xC5, 0x40, 0x00, 0xAB};
irsend.begin();
irsend.reset();
irsend.sendDaikin152(expectedState);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN152, irsend.capture.decode_type);
ASSERT_EQ(kDaikin152Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits);
irsend.reset();
// Data from:
// https://github.com/crankyoldgit/IRremoteESP8266/issues/873#issuecomment-525166905
uint8_t expectedState2[kDaikin152StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x00, 0x31, 0x28, 0x00, 0x3F, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC5, 0x00, 0x00, 0x6F};
irsend.sendDaikin152(expectedState2);
irsend.makeDecodeResult();
ASSERT_TRUE(irrecv.decode(&irsend.capture));
ASSERT_EQ(DAIKIN152, irsend.capture.decode_type);
ASSERT_EQ(kDaikin152Bits, irsend.capture.bits);
EXPECT_STATE_EQ(expectedState2, irsend.capture.state, irsend.capture.bits);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 1 (Low), Swing(V): On, "
"Powerful: Off, Quiet: Off, Econo: Off, Sensor: Off, Comfort: Off",
IRAcUtils::resultAcToString(&irsend.capture));
}
TEST(TestDaikin2ClassNew, Issue908) {
IRDaikin2 ac(0);
// https://docs.google.com/spreadsheets/d/1f8EGfIbBUo2B-CzUFdrgKQprWakoYNKM80IKZN4KXQE/edit#gid=236366525&range=I8
uint8_t fanMedium[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x4A, 0x42, 0xB0, 0x28, 0x0C, 0x80, 0x04,
0xB0, 0x16, 0x24, 0x00, 0x00, 0xAA, 0xC3, 0x5E, 0x11, 0xDA, 0x27, 0x00,
0x00, 0x09, 0x3C, 0x00, 0x50, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0xC1,
0x90, 0x60, 0xBE};
ac.setRaw(fanMedium);
EXPECT_EQ(
"Power: On, Mode: 0 (Auto), Temp: 30C, Fan: 3 (Medium), "
"Swing(V): 3 (UpperMiddle), Swing(H): 170 (UNKNOWN), Clock: 09:46, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 2 (Loud), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
ASSERT_EQ(kDaikinFanMed, ac.getFan());
ASSERT_EQ(stdAc::fanspeed_t::kMedium, ac.toCommon().fanspeed);
ASSERT_EQ(kDaikinFanMed, ac.convertFan(stdAc::fanspeed_t::kMedium));
// https://docs.google.com/spreadsheets/d/1f8EGfIbBUo2B-CzUFdrgKQprWakoYNKM80IKZN4KXQE/edit#gid=236366525&range=I17
uint8_t swingvMiddle[kDaikin2StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x01, 0x55, 0x42, 0xB0, 0x28, 0x0C, 0x80, 0x04,
0xB0, 0x16, 0x24, 0x00, 0x00, 0xAA, 0xC3, 0x69, 0x11, 0xDA, 0x27, 0x00,
0x00, 0x09, 0x3C, 0x00, 0xB0, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0xC1,
0x90, 0x60, 0x1E};
ac.setRaw(swingvMiddle);
EXPECT_EQ(
"Power: On, Mode: 0 (Auto), Temp: 30C, Fan: 11 (Quiet), "
"Swing(V): 3 (UpperMiddle), Swing(H): 170 (UNKNOWN), Clock: 09:57, "
"On Timer: Off, Off Timer: Off, Sleep Timer: Off, Beep: 2 (Loud), "
"Light: 3 (Off), Mould: On, Clean: On, Fresh: Off, Eye: Off, "
"Eye Auto: Off, Quiet: Off, Powerful: Off, Purify: On, Econo: Off",
ac.toString());
ASSERT_EQ(3, ac.getSwingVertical());
ASSERT_EQ(stdAc::swingv_t::kMiddle, ac.toCommon().swingv);
ac.setSwingVertical(4);
ASSERT_EQ(4, ac.getSwingVertical());
ASSERT_EQ(stdAc::swingv_t::kMiddle, ac.toCommon().swingv);
// Either 3 or 4 is fine as they both map to stdAc::swingv_t::kMiddle.
ASSERT_EQ(4, ac.convertSwingV(stdAc::swingv_t::kMiddle));
// Native "swing" should convert to common's "auto".
ac.setSwingVertical(kDaikin2SwingVSwing);
ASSERT_EQ(kDaikin2SwingVSwing, ac.getSwingVertical());
ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv);
ASSERT_EQ(kDaikin2SwingVSwing, ac.convertSwingV(stdAc::swingv_t::kAuto));
// Native "auto" should convert to common's "off".
ac.setSwingVertical(kDaikin2SwingVAuto);
ASSERT_EQ(kDaikin2SwingVAuto, ac.getSwingVertical());
ASSERT_EQ(stdAc::swingv_t::kOff, ac.toCommon().swingv);
ASSERT_EQ(kDaikin2SwingVAuto, ac.convertSwingV(stdAc::swingv_t::kOff));
}
// Tests for IRDaikin152 class.
TEST(TestDaikin152Class, Power) {
IRDaikin152 ac(0);
ac.begin();
ac.on();
EXPECT_TRUE(ac.getPower());
ac.off();
EXPECT_FALSE(ac.getPower());
ac.setPower(true);
EXPECT_TRUE(ac.getPower());
ac.setPower(false);
EXPECT_FALSE(ac.getPower());
}
TEST(TestDaikin152Class, Temperature) {
IRDaikin152 ac(0);
ac.begin();
ac.setMode(kDaikinHeat); // Heat has the widest temp range.
ac.setTemp(0);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(255);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp - 1);
EXPECT_EQ(kDaikinMinTemp, ac.getTemp());
ac.setTemp(kDaikinMaxTemp + 1);
EXPECT_EQ(kDaikinMaxTemp, ac.getTemp());
ac.setTemp(kDaikinMinTemp + 1);
EXPECT_EQ(kDaikinMinTemp + 1, ac.getTemp());
ac.setTemp(21);
EXPECT_EQ(21, ac.getTemp());
ac.setTemp(25);
EXPECT_EQ(25, ac.getTemp());
ac.setTemp(29);
EXPECT_EQ(29, ac.getTemp());
// Special temps.
ac.setTemp(kDaikin152FanTemp);
EXPECT_EQ(kDaikin152FanTemp, ac.getTemp());
}
TEST(TestDaikin152Class, OperatingMode) {
IRDaikin152 ac(0);
ac.begin();
ac.setMode(kDaikinAuto);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setTemp(25);
ac.setMode(kDaikinCool);
EXPECT_EQ(kDaikinCool, ac.getMode());
ac.setMode(kDaikinHeat);
EXPECT_EQ(kDaikinHeat, ac.getMode());
ac.setMode(kDaikinFan);
EXPECT_EQ(kDaikinFan, ac.getMode());
EXPECT_EQ(kDaikin152FanTemp, ac.getTemp());
ac.setMode(kDaikinDry);
EXPECT_EQ(kDaikinDry, ac.getMode());
EXPECT_EQ(kDaikin152DryTemp, ac.getTemp());
ac.setMode(kDaikinFan + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(kDaikinAuto + 1);
EXPECT_EQ(kDaikinAuto, ac.getMode());
ac.setMode(255);
EXPECT_EQ(kDaikinAuto, ac.getMode());
}
TEST(TestDaikin152Class, Swing) {
IRDaikin152 ac(0);
ac.begin();
ac.setSwingV(false);
EXPECT_FALSE(ac.getSwingV());
ac.setSwingV(true);
EXPECT_TRUE(ac.getSwingV());
ac.setSwingV(false);
EXPECT_FALSE(ac.getSwingV());
}
TEST(TestDaikin152Class, QuietMode) {
IRDaikin152 ac(0);
ac.begin();
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
ac.setQuiet(false);
EXPECT_FALSE(ac.getQuiet());
ac.setQuiet(true);
EXPECT_TRUE(ac.getQuiet());
// Setting Econo mode should NOT change out of quiet mode.
ac.setEcono(true);
EXPECT_TRUE(ac.getQuiet());
ac.setEcono(false);
EXPECT_TRUE(ac.getQuiet());
// But setting Powerful mode should exit out of quiet mode.
ac.setPowerful(true);
EXPECT_FALSE(ac.getQuiet());
}
TEST(TestDaikin152Class, PowerfulMode) {
IRDaikin152 ac(0);
ac.begin();
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setPowerful(false);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
EXPECT_TRUE(ac.getPowerful());
ac.setQuiet(true);
EXPECT_FALSE(ac.getPowerful());
ac.setPowerful(true);
ac.setEcono(true);
EXPECT_FALSE(ac.getPowerful());
}
TEST(TestDaikin152Class, EconoMode) {
IRDaikin152 ac(0);
ac.begin();
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
ac.setEcono(false);
EXPECT_FALSE(ac.getEcono());
ac.setEcono(true);
EXPECT_TRUE(ac.getEcono());
// Setting Quiet mode should NOT change out of Econo mode.
ac.setQuiet(true);
EXPECT_TRUE(ac.getEcono());
ac.setQuiet(false);
EXPECT_TRUE(ac.getEcono());
// But setting Powerful mode should exit out of Econo mode.
ac.setPowerful(true);
EXPECT_FALSE(ac.getEcono());
}
TEST(TestDaikin152Class, FanSpeed) {
IRDaikin152 ac(0);
ac.begin();
// Unexpected value should default to Auto.
ac.setFan(0);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
// Unexpected value should default to Auto.
ac.setFan(255);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax);
EXPECT_EQ(kDaikinFanMax, ac.getFan());
// Beyond Max should default to Auto.
ac.setFan(kDaikinFanMax + 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanMax - 1);
EXPECT_EQ(kDaikinFanMax - 1, ac.getFan());
ac.setFan(kDaikinFanMin);
EXPECT_EQ(kDaikinFanMin, ac.getFan());
ac.setFan(kDaikinFanMin + 1);
EXPECT_EQ(kDaikinFanMin + 1, ac.getFan());
// Beyond Min should default to Auto.
ac.setFan(kDaikinFanMin - 1);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(3);
EXPECT_EQ(3, ac.getFan());
ac.setFan(kDaikinFanAuto);
EXPECT_EQ(kDaikinFanAuto, ac.getFan());
ac.setFan(kDaikinFanQuiet);
EXPECT_EQ(kDaikinFanQuiet, ac.getFan());
}
TEST(TestDaikin152Class, Comfort) {
IRDaikin152 ac(0);
ac.begin();
// Comfort mode should change these settings.
ac.setSwingV(true);
ac.setFan(kDaikinFanMax);
ac.setPowerful(true);
ac.setComfort(false);
ASSERT_FALSE(ac.getComfort());
ac.setComfort(true);
ASSERT_TRUE(ac.getComfort());
ASSERT_FALSE(ac.getSwingV());
ASSERT_FALSE(ac.getPowerful());
ASSERT_EQ(kDaikinFanAuto, ac.getFan());
ac.setComfort(false);
ASSERT_FALSE(ac.getComfort());
}
TEST(TestDaikin152Class, toCommon) {
IRDaikin152 ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMax);
ac.setSwingV(true);
ac.setQuiet(false);
ac.setPowerful(true);
ac.setEcono(false);
// Now test it.
ASSERT_EQ(decode_type_t::DAIKIN152, ac.toCommon().protocol);
ASSERT_EQ(-1, ac.toCommon().model);
ASSERT_TRUE(ac.toCommon().power);
ASSERT_TRUE(ac.toCommon().celsius);
ASSERT_EQ(20, ac.toCommon().degrees);
ASSERT_TRUE(ac.toCommon().turbo);
ASSERT_FALSE(ac.toCommon().quiet);
ASSERT_FALSE(ac.toCommon().econo);
ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode);
ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed);
ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv);
// Unsupported.
ASSERT_EQ(stdAc::swingh_t::kOff, ac.toCommon().swingh);
ASSERT_FALSE(ac.toCommon().filter);
ASSERT_FALSE(ac.toCommon().clean);
ASSERT_FALSE(ac.toCommon().light);
ASSERT_FALSE(ac.toCommon().beep);
ASSERT_EQ(-1, ac.toCommon().sleep);
ASSERT_EQ(-1, ac.toCommon().clock);
}
TEST(TestDaikin152Class, convertFan) {
EXPECT_EQ(kDaikinFanQuiet, IRDaikin152::convertFan(stdAc::fanspeed_t::kMin));
EXPECT_EQ(kDaikinFanMin, IRDaikin152::convertFan(stdAc::fanspeed_t::kLow));
EXPECT_EQ(kDaikinFanMed,
IRDaikin152::convertFan(stdAc::fanspeed_t::kMedium));
EXPECT_EQ(kDaikinFanMax - 1,
IRDaikin152::convertFan(stdAc::fanspeed_t::kHigh));
EXPECT_EQ(kDaikinFanMax, IRDaikin152::convertFan(stdAc::fanspeed_t::kMax));
EXPECT_EQ(kDaikinFanAuto,
IRDaikin152::convertFan(stdAc::fanspeed_t::kAuto));
}
TEST(TestDaikin152Class, BuildKnownState) {
IRDaikin152 ac(0);
ac.setPower(true);
ac.setMode(kDaikinCool);
ac.setTemp(20);
ac.setFan(kDaikinFanMin);
ac.setSwingV(true);
ac.setQuiet(false);
ac.setPowerful(false);
ac.setEcono(false);
ac.setSensor(false);
ac.setComfort(false);
EXPECT_EQ(
"Power: On, Mode: 3 (Cool), Temp: 20C, Fan: 1 (Low), Swing(V): On, "
"Powerful: Off, Quiet: Off, Econo: Off, Sensor: Off, Comfort: Off",
ac.toString());
uint8_t expectedState[kDaikin152StateLength] = {
0x11, 0xDA, 0x27, 0x00, 0x00, 0x31, 0x28, 0x00, 0x3F, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xC5, 0x00, 0x00, 0x6F};
EXPECT_STATE_EQ(expectedState, ac.getRaw(), kDaikin152Bits);
}